Sewage Treatment

Preface. Before sewage treatment, cities were hell-holes of foul smells from rotting human waste, industrial effluent, and garbage.  Few people lived beyond 50 because of the many waterborne diseases.  In fact, sewage and water treatment systems are the main reason lifespans nearly doubled (Garrett 2001).  Here are just a few of the diseases possible from drinking untreated water: Adenovirus infection, Amebiasis, Campylobacteriosis, Cryptosporidiosis, Cholera, E. Coli 0157:H7, Giardiasis, Hepatitis A, Legioellosis, Salmonellosis, Vibrio infection, Viral gastroenteritis, free living amoebae (ADHS).  For the full list of waterborne diseases, see post Water-borne diseases will increase as energy declines.

Nearly all sewage infrastructure is past its life-time, a good way to spend the remaining cheap oil before it becomes scarce.

Sewage is also a way to return nutrients back to the soil, especially finite phosphorus, which is eaten and excreted, treated, and lost to oceans and other waterways.

Today moving sludge from city sewage treatment farms works because of cheap energy. In the future energy crisis, that won’t be possible.

There are two articles below, one about sewage sludge for crops, and the other about sewage corrosion.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Perkins, T. 2020. Questions remain about using treated sewage on farms. Use of biosolids in agriculture is increasingly coming under fire as a potential health and environmental threat. Salon.

Human waste is a nutrient-rich substance that farmers around the world have spread on cropland for centuries.  Every day, about 20 million gallons of sewage flows into the city of Tacoma’s wastewater treatment plants. The water is separated, treated, and discharged into the Puget Sound, which leaves behind sludge — a mix of human excrement, industrial waste, and everything else that ends up in sewers. The plants further treat the product to reduce pathogens, bacteria, heavy metals, and odors, and convert it into a fertilizer called biosolids, which is high in phosphorus, nitrogen, and other nutrients that help plants grow.

Over 50 percent of the approximately 130 million wet tons of sludge produced nationally each year is treated and applied to less than 1% of cropland. As a fertilizer, it’s popular because most wastewater treatment plants give it away for free or at prices less than the cost of synthetic fertilizers.

The Sierra club notes that it can contain up to 90,000 man-made chemicals and we don’t know what new chemicals are made synergistically by combining them. It’s not certain that biosolids are safe.

One of the most controversial piece of the sewage puzzle is the fact that factories, slaughterhouses, and other industrial facilities are allowed to discharge their waste into the taxpayer-funded sewer system.

Increased testing is consistently finding levels of per- and polyfluoroalkyl substances (PFAS) that are alarming health officials and the public.

Before the 1972 Clean Water Act, the waste industry largely burned it, but that often violates the Clean Air Act, Lewis said. Municipalities also tried dumping it in the ocean, but that created large dead zones. Then, in 1993, the EPA approved a proposal to spread it on land after it was treated. Sludge that isn’t turned into biosolids is landfilled or incinerated — both of which are expensive compared to spreading it on farmland.

The EPA only requires nine pollutants — all heavy metals — to be removed from biosolids, as well as living pathogens such as E. coli and Salmonella. Sludge may be treated by air drying, pasteurization, or composting. Lime is often used to raise the pH level to eliminate odors, and about 95 percent of pathogens, viruses, and other organisms are killed in the process, according to waste management industry officials.

Pikaar, I. et al. 2014. Reducing sewer corrosion through integrated urban water management. Science 345: 812-814  

Sewer systems are among the most critical infrastructure assets for modern urban societies and provide essential human health protection. Sulfide-induced concrete sewer corrosion costs billions of dollars annually and has been identified as a main cause of global sewer deterioration. Aluminum sulfate addition during drinking water production contributes substantially to the sulfate load in sewage and indirectly serves as the primary source of sulfide. This unintended consequence of urban water management structures could be avoided by switching to sulfate-free coagulants, with no or only marginal additional expenses compared with the large potential savings in sewer corrosion costs.

Sewer systems are corroding at an alarming rate, costing governments billions of dollars to replace. Differences among water treatment systems make it difficult to track down the source of corrosive sulfide responsible for this damage.

Urban sewer networks collect and transport domestic and industrial waste waters through underground pipelines to wastewater treatment plants for pollutant removal before environmental discharge. They protect our urban society against sewage-borne diseases, unhygienic conditions, and noxious odors and so allow us to live in ever larger and more densely populated cities. Today’s underground sewer infrastructure is the result of an enormous investment over the last 100+ years with, for example, an estimated asset value of one trillion dollars in the USA (Brongers). This equates to ~7% of its current gross domestic product. However, these assets are under serious threat with an estimated annual asset loss of around $14 billion in the United States alone. Sulfide-induced concrete corrosion is recognized as a main cause of sewer deterioration in most cases.

Many water utilities will need to upgrade both their water supply and wastewater service infrastructure over the next 10 to 15 years, which will require enormous capital investments.


ADHS. Waterborne diseases. Arizona Department of Health Services.

Brongers, M. P. H., et al. 2002. “Drinking water and sewer systems in corrosion costs and preventative strategies in the United States”.  Federal Highway Administration Publication FHWA-RD-01-156, U.S. Department of Transportation, Washington, DC.

Garrett, L. 2001. Betrayal of Trust: The Collapse of Global Public Health. Hatchette Books.

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Climate change impacts on agriculture

Preface. There are three articles below on this topic.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


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Berdugo, M., et al. 2020. Global ecosystem thresholds driven by aridity. Science.

Earth’s dryland ecosystem covers 45% of the world’s surface and is home to around a third of its population who depend on these areas for their food and water.

This study found that as aridity increases, dryland ecosystems undergo a series of abrupt changes. This results first in drastic reductions in the capacity of plants to fix carbon from the atmosphere, then substantial declines of soil fertility, drought-tolerant plants replace food crops, and finally vegetation disappears under the most arid and extreme conditions and turns into a desert. 

As aridification grows worse, the land becomes more vulnerable to erosion, soil biota maintaining the ecosystem decline, pathogens increase,  crops fail.

More than 20% of land may cross these thresholds by 2100 due to climate change.

Hatfield, J., et. al. 2014: Ch. 6: Agriculture. Climate Change Impacts in the United States. The Third National Climate Assessment. 150-174.

  1. Climate disruptions to agricultural production have increased in the past 40 years and are projected to increase over the next 25 years. By 2050 and beyond, these impacts will be increasingly negative on most crops and livestock.
  2. Many agricultural regions will experience declines in crop and livestock production from increased stress due to weeds, diseases, insect pests, and other climate change induced stresses.
  3. Current loss and degradation of critical agricultural soil and water assets due to increasing extremes in precipitation will continue to challenge both rain-fed and irrigated agriculture 
  4. The rising incidence of weather extremes will have increasingly negative impacts on crop and livestock productivity because critical thresholds are already being exceeded.
  5. Agriculture has been able to adapt to recent changes in climate; however, increased innovation will be needed to ensure the rate of adaptation of agriculture and the associated socioeconomic system can keep pace with climate change over the next 25 years.
  6. Climate change effects on agriculture will have consequences for food security, both in the U.S. and globally, through changes in crop yields and food prices and effects on food processing, storage, transportation, and retailing. Adaptation measures can help delay and reduce some of these impacts.

The United States produces nearly $330 billion per year in agricultural commodities, with livestock accounting for half of that value. Production of all commodities will be vulnerable to direct impacts (from changes in crop and livestock development and yield due to changing climate conditions and extreme weather events) and indirect impacts (through increasing pressures from pests and pathogens that will benefit from a changing climate). Crop production projections often fail to consider the indirect impacts from weeds, insects, and diseases that accompany changes in both average trends and extreme events, which can increase losses significantly.

Rising average temperatures will increase crop water demand, increasing the rate of water use by the crop. Higher temperatures are projected to increase both evaporative losses from land and water surfaces and transpiration losses (through plant leaves) from non-crop land cover, potentially reducing annual runoff and streamflow for a given amount of precipitation.

By mid-century, when temperature increases are projected to be between 1.8°F and 5.4°F and precipitation extremes are further intensified, yields of major U.S. crops and farm profits are expected to decline.  There have already been detectable impacts on production due to increasing temperatures.

One critical period in which temperatures are a major factor is the pollination stage; pollen release is related to development of fruit, grain, or fiber. Exposure to high temperatures during this period can greatly reduce crop yields and increase the risk of total crop failure. Plants exposed to high nighttime temperatures during the grain, fiber, or fruit production period experience lower productivity and reduced quality. These effects have already begun to occur; high nighttime temperatures affected corn yields in 2010 and 2012 across the Corn Belt. With the number of nights with hot temperatures projected to increase as much as 30%, yield reductions will become more prevalent.

Plants have specific temperature tolerances, and can only be grown in areas where their temperature thresholds are not exceeded. As temperatures increase over this century, crop production areas may shift to follow the temperature range for optimal growth and yield of grain or fruit. Temperature effects on crop production are only one component; production over years in a given location is more affected by available soil water during the growing season than by temperature, and increased variation in seasonal precipitation, coupled with shifting patterns of precipitation within the season, will create more variation in soil water availability.

Increasing temperatures cause cultivated plants to grow and mature more quickly. Crops, such as cereals, would grow more quickly, meaning less time for the grain itself to mature, reducing productivity. But because the soil may not be able to supply nutrients at required rates for faster growing plants, plants may be smaller, reducing grain, forage, fruit, or fiber production.

In vegetables, exposure to temperatures in the range of 1.8°F to 7.2°F above optimal moderately reduces yield, and exposure to temperatures more than 9°F to 12.6°F above optimal often leads to severe if not total production losses.

Temperature and precipitation changes will include an increase in both the number of consecutive dry days (days with less than 0.01 inches of precipitation) and the number of hot nights. The western and southern parts of the nation show the greatest projected increases in consecutive dry days, while the number of hot nights is projected to increase throughout the U.S. These increases in consecutive dry days and hot nights will have negative impacts on crop and animal production. High nighttime temperatures during the grain-filling period (the period between the fertilization of the ovule and the production of a mature seed in a plant) increase the rate of grain-filling and decrease the length of the grain-filling period, resulting in reduced grain yields. Exposure to multiple hot nights increases the degree of stress imposed on animals resulting in reduced rates of meat, milk, and egg production.

Climate change poses a major challenge to U.S. agriculture because of the critical dependence of the agricultural system on climate and because of the complex role agriculture plays in rural and national social and economic systems (Figure 6.2). Climate change has the potential to both positively and negatively affect the location, timing, and productivity of crop, livestock, and fishery systems at local, national, and global scales. It will also alter the stability of food supplies and create new food security challenges for the United States

Over time, climate change is expected to increase the annual variation in crop and livestock production because of its effects on weather patterns and because of increases in some types of extreme weather events.

Each crop species has a temperature range for growth, along with an optimum temperature.9 Plants have specific temperature tolerances, and can only be grown in areas where their temperature thresholds are not exceeded. As temperatures increase over this century, crop production areas may shift to follow the temperature range for optimal growth and yield of grain or fruit. Temperature effects on crop production are only one component; production over years in a given location is more affected by available soil water during the growing season than by temperature, and increased variation in seasonal precipitation, coupled with shifting patterns of precipitation within the season, will create more variation in soil water availability. The use of a model to evaluate the effect of changing temperatures

Key Message: Extreme Precipitation and Soil Erosion

Current loss and degradation of critical agricultural soil and water assets due to increasing extremes in precipitation will continue to challenge both rainfed and irrigated agriculture unless innovative conservation methods are implemented. Wind erosion could also increase in areas with persistent drought because of the reduction in vegetative cover.

Several processes act to degrade soils, including erosion, compaction, acidification, salinization, toxification, and net loss of organic matter. Several of these processes, particularly erosion, will be directly affected by climate change. Rainfall’s erosive power is expected to increase as a result of increases in rainfall amount in northern portions of the United States, accompanied by further increases in precipitation intensity.  Projected increases in rainfall intensity that include more extreme events will increase soil erosion in the absence of conservation practices. Precipitation and temperature affect the potential amount of water available, but the actual amount of available water also depends on soil type, soil water holding capacity, and the rate at which water filters through the soil.

Iowa is the nation’s top corn and soybean producing state. These crops are planted in the spring. Heavy rain can delay planting and create problems in obtaining a good stand of plants, both of which can reduce crop productivity. In Iowa soils with even modest slopes, rainfall of more than 1.25 inches in a single day leads to runoff that causes soil erosion and loss of nutrients and, under some circumstances, can lead to flooding. Figure 6.9 shows the number of days per year during which more than 1.25 inches of rain fell is increasing.

A few of the ecosystem services provided by soils include:

  • the provision of food
  • wood
  • fiber (i.e. cotton)
  • raw materials
  • flood mitigation
  • recycling of wastes
  • biological control of pest
  • regulation of carbon and other heat-trapping gases
  • physical support for roads and buildings
  • cultural and aesthetic values

Productive soils are characterized by levels of nutrients necessary for the production of healthy plants, moderately high levels of organic matter, a soil structure with good binding of the primary soil particles, moderate pH levels, thickness sufficient to store adequate water for plants, a healthy microbial community, and the absence of elements or compounds in concentrations that are toxic for plant, animal, and microbial life.

Erosion is managed through maintenance of cover on the soil surface to reduce the effect of rainfall intensity. Studies have shown that a reduction in projected crop biomass (and hence the amount of crop residue that remains on the surface over the winter) will increase soil loss.

Key Message: Weeds, Diseases, and Pests

Many agricultural regions will experience declines in crop and livestock production from increased stress due to weeds, diseases, insect pests, and other climate change induced stresses.

The growth of atmospheric CO2 concentrations has a disproportionately positive impact on several weed species. This effect will contribute to increased risk of crop loss due to weed pressure.

Weeds, insects, and diseases already have large negative impacts on agricultural production, and climate change has the potential to increase these impacts. Current estimates of losses in global crop production show that weeds cause the largest losses (34%), followed by insects (18%), and diseases (16%). Further increases in temperature and changes in precipitation patterns will induce new conditions that will affect insect populations, incidence of pathogens, and the geographic distribution of insects and diseases. Increasing CO2 boosts weed growth, adding to the potential for increased competition between crops and weeds. Several weed species benefit more than crops from higher temperatures and CO2 levels.

One concern involves the northward spread of invasive weeds like privet and kudzu, which are already present in the southern states. Changing climate and changing trade patterns are likely to increase both the risks posed by, and the sources of, invasive species. Controlling weeds costs the U.S. more than $11 billion a year, with most of that spent on herbicides. Both herbicide use and costs are expected to increase as temperatures and CO2 levels rise. Also, the most widely used herbicide in the United States, glyphosate, loses its efficacy on weeds grown at CO2 levels projected to occur in the coming decades. Higher concentrations of the chemical and more frequent sprayings thus will be needed, increasing economic and environmental costs associated with chemical use.

Insects are directly affected by temperature and synchronize their development and reproduction with warm periods and are dormant during cold periods. Higher winter temperatures increase insect populations due to overwinter survival and, coupled with higher summer temperatures, increase reproductive rates and allow for multiple generations each year. An example of this has been observed in the European corn borer (Ostrinia nubialis) which produces one generation in the northern Corn Belt and two or more generations in the southern Corn Belt. Changes in the number of reproductive generations coupled with the shift in ranges of insects will alter insect pressure in a given region.

Key Message: Heat and Drought Damage

The rising incidence of weather extremes will have increasingly negative impacts on crop and livestock productivity because critical thresholds are already being exceeded.

Climate change projections suggest an increase in extreme heat, severe drought, and heavy precipitation. Extreme climate conditions, such as dry spells, sustained droughts, and heat waves all have large effects on crops and livestock. The timing of extreme events will be critical because they may occur at sensitive stages in the life cycles of agricultural crops or reproductive stages for animals, diseases, and insects. Extreme events at vulnerable times could result in major impacts on growth or productivity, such as hot-temperature extreme weather events on corn during pollination. By the end of this century, the occurrence of very hot nights and the duration of periods lacking agriculturally significant rainfall are projected to increase. Recent studies suggest that increased average temperatures and drier conditions will amplify future drought severity and temperature extremes. Crops and livestock will be at increased risk of exposure to extreme heat events. Projected increases in the occurrence of extreme heat events will expose production systems to conditions exceeding maximum thresholds for given species more frequently.

California’s Wine, Fruit, & Nut production will begin declining as soon as 2050

In fact, it’s already happening. In 2000, the number of chilling hours in some regions was 30% lower than in 1950. A warmer climate will affect growing conditions, and the lack of cold temperatures may threaten perennial crop production (Figure 6.6), which have a winter chilling requirement (expressed as hours when temperatures are between 32°F and 50°F) ranging from 200 to 2,000 cumulative hours. Yields decline if the chilling requirement is not completely satisfied, because flower emergence and viability is low.  Projections show that chilling requirements for fruit and nut trees in California will not be met by the middle to the end of this century.

Impacts on Animal Production  

Animal agriculture is a major component of the U.S. agriculture system. Changing climatic conditions affect animal agriculture in four primary ways: 1) feed-grain production, availability, and price; 2) pastures and forage crop production and quality; 3) animal health, growth, and reproduction; and 4) disease and pest distributions. The optimal environmental conditions for livestock production include temperatures and other conditions for which animals do not need to significantly alter behavior or physiological functions to maintain relatively constant core body temperature.

Optimum animal core body temperature is often maintained within a 4°F to 5°F range, while deviations from this range can cause animals to become stressed. This can disrupt performance, production, and fertility, limiting the animals’ ability to produce meat, milk, or eggs. In many species, deviations in core body temperature in excess of 4°F to 5°F cause significant reductions in productive performance, while deviations of 9°F to 12.6°F often result in death. For cattle that breed during spring and summer, exposure to high temperatures reduces conception rates. Livestock and dairy production are more affected by the number of days of extreme heat than by increases in average temperature. Elevated humidity exacerbates the impact of high temperatures on animal health and performance.

Animals respond to extreme temperature events (hot or cold) by altering their metabolic rates and behavior. Increases in extreme temperature events may become more likely for animals, placing them under conditions where their efficiency in meat, milk, or egg production is affected. Projected increases in extreme heat events will further increase the stress on animals, leading to the potential for greater impacts on production. Meat animals are managed for a high rate of weight gain (high metabolic rate), which increases their potential risk when exposed to high temperature conditions. Exposure to heat stress disrupts metabolic functions in animals and alters their internal temperature when exposure occurs. Exposure to high temperature events can be costly to producers, as was the case in 2011, when heat-related production losses exceeded $1 billion.

Livestock production faces additional climate change related impacts that can affect disease prevalence and range. Regional warming and changes in rainfall distribution have the potential to change the distributions of diseases that are sensitive to temperature and moisture, such as anthrax, blackleg, and hemorrhagic septicemia, and lead to increased incidence of ketosis, mastitis, and lameness in dairy cows.

Goats, sheep, beef cattle, and dairy cattle are the livestock species most widely managed in extensive outdoor facilities. Within physiological limits, animals can adapt to and cope with gradual thermal changes, though shifts in thermoregulation may result in a loss of productivity.  Lack of prior conditioning to rapidly changing or adverse weather events, however, often results in catastrophic deaths in domestic livestock and losses of productivity in surviving animals.

Key Message: Rate of Adaptation

Agriculture has been able to adapt to recent changes in climate; however, increased innovation will be needed to ensure the rate of adaptation of agriculture and the associated socioeconomic system can keep pace with climate change over the next 25 years.

In the longer term existing adaptive technologies will likely not be sufficient to buffer the impacts of climate change without significant impacts to domestic producers, consumers, or both. Limits to public investment and constraints on private investment could slow the speed of adaptation. Adaptation may also be limited by the availability of inputs (such as land or water), changing prices of other inputs with climate change (such as energy and fertilizer), and by the environmental implications of intensifying or expanding agricultural production.

In addition to regional constraints on the availability of critical basic resources such as land and water, there are potential constraints related to farm financing and credit availability in the U.S. and elsewhere. Research suggests that such constraints may be significant, especially for small family farms with little available capital.

Farm resilience to climate change is also a function of financial capacity to withstand increasing variability in production and returns, including catastrophic loss. As climate change intensifies, “climate risk” from more frequent and intense weather events will add to the existing risks commonly managed by producers, such as those related to production, marketing, finances, regulation, and personal health and safety factors. The role of innovative management techniques and government policies as well as research and insurance programs will have a substantial impact on the degree to which the agricultural sector increases climate resilience in the longer term.

Key Message: Food Security

Climate change effects on agriculture will have consequences for food security, both in the U.S. and globally, through changes in crop yields and food prices and effects on food processing, storage, transportation, and retailing. 

Food security includes four components: availability, stability, access, and utilization of food. Following this definition, in 2011, 14.9% of U.S. households did not have secure food supplies at some point during the year, with 5.7% of U.S. households experiencing very low food security.

In addition to altering agricultural yields, projected rising temperatures, changing weather patterns, and increases in frequency of extreme weather events will affect distribution of food- and water-borne diseases as well as food trade and distribution. This means that U.S. food security depends not only on how climate change affects crop yields at the local and national level, but also on how climate change and changes in extreme events affect food processing, storage, transportation, and retailing, through the disruption of transportation as well as the ability of consumers to purchase food. And because about one-fifth of all food consumed in the U.S. is imported, our food supply and security can be significantly affected by climate variations and changes in other parts of the world. The import share has increased over the last two decades, and the U.S. now imports 13% of grains, 20% of vegetables (much higher in winter months), almost 40% of fruit, 85% of fish and shellfish, and almost all tropical products such as coffee, tea, and bananas. Climate extremes in regions that supply these products to the U.S. can cause sharp reductions in production and increases in prices.

In an increasingly globalized food system with volatile food prices, climate events abroad may affect food security in the U.S. while climate events in the U.S. may affect food security globally. The globalized food system can buffer the local impacts of weather events on food security, but can also increase the global vulnerability of food security by transmitting price shocks globally.


Senate 113-245. February 14, 2013. Drought, fire and freeze: the economics of disasters for America’s agricultural producers. U.S. Senate hearing. 

Excerpts from this 195-page document follow.

DEBBIE STABENOW, MICHIGAN. Nobody feels the effect of weather disasters more than our nation’s farmers and ranchers, as we all know, whose livelihoods depend on getting the right amount of rain, the right amount of sunshine, getting it all together the right way at the right time. All too frequently, an entire season’s crop can be lost, as we know. Or an entire herd must be sent to slaughter due to the lack of feed.

The year 2012 was a year of unprecedented destruction, from drought, freezes, wildfires, hurricanes, and tornadoes, including the tornadoes that hit Mississippi and other parts of the South last weekend, and my heart goes out to all the survivors of those devastating storms. Our country experienced two of the most destructive hurricanes on record last year, Isaac and Sandy. We experienced the warmest year on record ever in the contiguous United States, which, coupled with the historic drought, produced conditions that rivaled the Dust Bowl. Wildfires raged in the West. In the Upper Midwest and Northeast, warm weather in February and March caused trees to bloom early, resulting in total fruit destruction when temperatures dropped down to the 20s again in April, and we certainly were hit hard with that in Michigan. California and Arizona experienced a freeze just last month, threatening citrus, strawberries, lettuce, and avocados. We learned last week that our cattle herd inventories are the lowest in over six decades, which has had broad-ranging impacts, including job losses in rural communities as processing facilities and feedlots idle.

The drought has left many of our waterways with dangerously low water levels. Lake Michigan, Lake Huron have hit their all- time lowest water levels. Barge traffic on the Mississippi, our most vital waterway has nearly ground to a halt. We have seen major disruptions and increased transportation costs for commodities and fertilizers. Today, we will hear from officials at the National Oceanic and Atmospheric Administration, NOAA, and the Department of Agriculture about the disasters we faced last year. We also will hear directly from those affected by these disasters. Thanks to our successful Crop Insurance Program, many farmers will be able to recover their losses. For those farmers who did not have access to crop insurance or the other risk management tools we worked so hard to include in our Senate-passed farm bill, the future is less certain. Unfortunately, instead of a farm bill that gave those farmers certainty, we ended up with a partial extension that creates the haves and haven’ts. Low crop producers that participate in crop insurance not only get assistance from crop insurance, which is essential, but some will continue to receive direct payments, as well, regardless if they have a loss. Meanwhile, many livestock producers and specialty crop growers who suffered substantial losses will not receive any assistance.

We all know that farming is the riskiest business in the world and altogether employs 16 million Americans.


Drought is a pallet of the American experience, from the Southwest in the 13th century to the events of the 1930s and the 1950s to the present. From 2000 to 2010, the annual average land area affected by drought in the United States was 25 percent. Prior to the 2000s, this number stood at 15 percent. 2012 ended as one of the driest years on record, having had five months in which over 60 percent of the country was in moderate to extreme drought. It was also the warmest year on record. Only 1934 had more months with over 60 percent of the U.S. in moderate to severe drought. 1934 was also a warm year.

Drought conditions continue across much of the nation. According to one estimate, the cost of the 2012 drought is in excess of $35 billion, based on agriculture alone.

However, it is important to note the drought-related impacts cross a broad spectrum, from energy, tourism, and recreation in the State of Colorado where I live, to wildfire impacts. According to the National Interagency Fire Center in Boise, over nine million acres were burned last year, which had only happened twice before in the record, 2006 and 2007, since 1960. Low river levels also threaten commerce on the vital Mississippi shipping lanes, affecting transportation of agricultural products. As many of you know, half of the transport on the Mississippi is agriculturally based.

An important feature of conditions in 2012 was the persistence of the area of dryness and warm temperatures, the magnitude of the extremes, and the large area they encompassed.

Twenty-twelve began with about 32 percent of the U.S. in moderate to exceptional drought. The drought reintensified in May, and you can see a jump in the figure there. And by the end of August, the drought had expanded to cover 60 percent of the country, from the Central Rockies to the Ohio Valley and the Mexican to the Canadian borders. Several States had record dry seasons, including Arkansas, Kansas, Nebraska and South Dakota.

The drought years of 1955 and 1956 have the closest geographical pattern to what we have seen to date, and the year 1998, now the second-warmest year on record, and 2006, the third-warmest year on record, have the closest temperature pattern to what we see.

So as of this morning, we have released the U.S. Drought Monitor that gives you present conditions, which people have in front of them. And what we are pointing out in this case is the drought continues across many parts of the Midwest and the West. The physical drivers of drought are linked to sea surface temperatures in the Tropical Pacific and Atlantic Oceans.

As you can see from the last figure on the U.S. Drought Monitor, a dry pattern is expected over the upcoming three months across the South and the Midwest. Prospects are limited for improvement in drought conditions in California, Nevada, and Western Arizona. Drought development and persistence is forecasted for Texas by the end of April. The drought and warm temperatures in the Midwest are firmly entrenched into February, placing a greater need for above-normal spring rains if the region is to recover. This area is now becoming the epicenter of the 2013 drought. Despite some relief, much of the Appalachicola-Chattahoochee-Flint River Basin remain under extreme drought conditions, including low ground water levels, and Georgia is now in its driest two-year period on record.


Row crop producers have generally fared well, despite the adverse weather, in large part due to higher prices and protection from the Federal Crop Insurance Program, which has helped offset many of the yield losses. For uninsured producers, or producers of crops for which insurance is unavailable, however, crop losses have had a more adverse effect. Livestock producers experienced high feed costs and poor pasture conditions this year with limited programs to fall back on, particularly since key livestock disaster programs authorized under the 2008 farm bill are currently unfunded.

What had started out as a promising year for U.S. crop production, with favorable planting conditions supporting high planted acreage and expectations of record or near- record production turned into one of the most unfavorable growing seasons in decades. Crop production estimates for several major crops declined throughout the summer. By January 2013, final production estimates for corn were down almost 28 percent from our May projections. Sorghum was down 26 percent, while soybeans fell about six percent over the same period.

As a result, prices for grains and oil seeds soared to record highs in the summer. Higher prices and crop insurance indemnity payments helped offset crop losses for many rural crop producers. Roughly 85 percent of corn, wheat, and soybean area, almost 80 percent of rice area, and over 90 percent of cotton area is typically enrolled in the Crop Insurance Program, and for those of you who were around back in 1988, this contrasts sharply with what the experience was in 1988 when we had this massive drought in the Midwest. At that time, only about 25 percent of the area, insurable area, was enrolled in the program. So, again, very, very strong participation has helped offset those losses.

As of February 11, just this Monday, about $14.2 billion in indemnity payments have been made to producers of 2012 crops suffering crop or revenue losses. We think that these indemnity payments will likely go higher. They could be as high as 16 or 17 billion dollars before we are done.

On the other hand, looking at the livestock, dairy, and poultry producers, they are facing very high feed costs for most—they faced very high feed costs for most of 2012, and the high prices are likely to persist through much of 2013 until new crops become available in the fall. And in addition to these high feed costs, cattle producers have been particularly hard hit by poor pasture conditions and a poor hay crop. Almost two- thirds of the nation’s pasture and hay crops were in drought conditions, with almost 60 percent of pasture conditions rated poor or very poor for most of July, August, and September 2012. December 1 stocks for hay were at their lowest level since 1957.

The U.S. cattle and calf herd, as was mentioned in your statement, is at its lowest level since 1952. Dryness in the Southern Plains has persisted for over two years and resulted in large liquidation in cattle numbers. The January 1 NASS Cattle Report indicated that total cattle and calf numbers in Kansas, Oklahoma, and Texas alone declined by 3.4 million head between 2011 and 2013. The reduction is a 13.6 percent decline and almost equals the net decline in the U.S. herd over the same period. Likewise, dairy producers have faced high feed costs and poor pasture conditions, and higher temperatures during the summer also adversely affected milk production.

Net cash income is forecast lower in 2013 for all livestock, dairy, and poultry sector. Feed costs make up 51 percent of expenses for dairy, about 20 percent for beef cattle, 42 percent for hogs, and 35 percent for poultry farm businesses.

Major concerns related to persistent drought conditions remain. Fifty-nine percent of wheat area, the winter wheat area, 69 percent of cattle production, and 59 percent of hay acreage remains under drought conditions. Forty-three percent of the winter wheat production is located in areas under extreme or exceptional drought conditions, down only slightly from the 51 percent in August.

Chairwoman STABENOW. How long before we are going to have crop insurance available for specialty crop growers?

Mr. GLAUBER. I think we have made some improvements there. As you know, I sit on the Federal Crop Insurance Board. We have seen several products, new products that have come in that have extended crop insurance to some specialty crops. We have made some changes, for example, in the cherry policy with a revenue product. I think the overall liability for specialty crops right now is around 10 to 13 billion dollars. Certainly, we would like to see that improved. The difficulty is that with a lot of these crops, they are very small with not a lot of producers, and sometimes some of the producers are not interested in crop insurance. Now, what we have seen over the last five years, ten years, which is very different than, I would say, 15 years ago, is the fact that a lot of producers now are interested in developing these products.

Our major issue, as you know, in the Midwest and the Southwest, in particular, the Colorado Basin, is that we are having back- to-back dry years, and a third year of that puts our systems completely under stress. The forecast for this season is that, in fact, we are projecting drier conditions.

Senator KLOBUCHAR. Mississippi River transportation is my next question. In 2012, as you know, the barge traffic on the Mississippi was greatly impacted by the drought. It was more difficult to transport grain abroad and more farm inputs up-river to our farmers in Minnesota. We were very scared at the end of the year they were actually going to have to stop barge traffic. Could you talk about that a little and how this could impact our ability to stay competitive, as so many agriculture products go down the Mississippi?

Mr. GLAUBER. Yes. We, too, were very concerned with it because it looked like, particularly late December, early January, that there would be a halt in traffic. Now, understand, the upper part of the Mississippi, as you well know, you stop shipping because of the winter weather. But I think there were a couple of good things. One, the best thing, is that we got rain. The Corps was able to go in and clear out some of the disruptions in the river and then we got adequate rain and barge traffic is moving very well. I will say this. Because of the lower corn harvest and lower soybean harvest and the fact that so much more grain is going to China, it was probably less stress than it might have been under, say, 15 years ago. But, still, the best news is that we have adequate water.

Senator KLOBUCHAR. It is good, but it was a close call and I think it is something that we have to prepare better for next time and have a plan in place. Drought-resistant seeds—what efforts is the USDA taking to speed the adoption of such drought-hardy varieties developed using biotech or conventional breeding?

Mr. GLAUBER. Most of the breeding for seed breeding is in private hands these days. They do it better. There are a lot of profits to be made in that industry and they are working very hard. My understanding is, is that we should be seeing some disaster-resistant, purely disaster-resistant strains come on the market just in the next few years. We know upstream, as well, about 20 percent of what comes into the basin is coal and 20 percent is about fertilizers, as well.

Senator ROBERTS. We have got two years of sustained drought and another one coming, according to our renowned forecaster here. But Kansas producers, once again, put seeds in the ground. Many will once again fire up their tractor and their planter in another six weeks.  They manage their risk and protect their operations from Mother Nature’s destruction through the purchase of crop insurance.

Unfortunately, livestock producers do not have a similar safety net. However, with the support of Secretary Vilsack last year, the Department authorized the emergency haying and grazing of Conservation Reserve Program acres in all Kansas counties, including the emergency grazing on CP-25 for the first time. You do not do that unless you have a very, very serious problem.

According to USDA reports last year, over 9,000 emergency haying and grazing contracts allowed haying and grazing on over 470,000 acres in Kansas, that’s a lot of acres.   But as we continue to experience what we have experienced in the 1950s and back in the 1930s, what considerations has the Department given to allowing emergency haying and grazing of CRP acres for 2013??

Mr. GLAUBER. A lot of these producers have been hanging on with very, very tight or negative margins. And again, I cited these numbers. Over three million, three-and-a-half million head down from just two years ago in your region of the country. And so it is very critical. I think any help that we can get to the producers to help them make it through to better prices, we will be working with your office on that.

Senator ROBERTS.  As you know, many ranchers simply culled their herds and lost their genetics and many are out of business. Northwest Kansas producers irrigating from the Ogallala Aquifer, they must work to conserve their water, but current RMA practices do not have a middle ground between fully irrigated and dry land practices and we need a mechanism to allow limited irrigation to be fairly rated.

Senator BENNET. —we have now had two years in a row, and it sounds like we are going to have a third year of drought in our region. And I wonder if you could talk about the specific challenges that NOAA projects for producers in the water-scarce Western region of our country.

Mr. PULWARTY.  I hope I am wrong, as well. The State of Colorado, as you know, in the Front Range, where I live and others do, we get 30 to 40 percent of our water from the Colorado Basin itself. The Colorado Basin came in at 44 percent in the previous water year. So far, the fall snow pack has not been as significant as we would like it. In some places, it is 40, some places 60%, and we hope that picks up in March and April.

However, right now, based on what is happening in the Pacific Ocean and the Atlantic Oceans, we are not projecting an improved set of conditions in those basins, the Upper Basin, including the San Juan and places like that.

The area in terms of the basin is experiencing some lower precipitation and snow pack, and it is also experiencing a combination of high temperatures, however driven. Something else that is happening in that basin has to do with some of our rural communities, where there is rain-fed agriculture.

the combination of temperature and drought is actually creating the die-off of key vegetation that holds our soils together. And the result, then, is dust storms, dust on snow, which lets the runoff and melt occur even earlier than we are accustomed to managing it.

From that standpoint, and looking into the future, while we are seeing some improvement in the lower Colorado Basin—Arizona, Southern California, Nevada—we are expecting that to be short- lived into April. From the standpoint of the Upper Basin, and again, I hope I am, in fact, wrong, we are not projecting significant new inputs of snow unless we get heavy rainfall events later in the spring.

One of the reasons why that is the case is when it has been dry for a year before, even when you get significant snow pack, a lot of that disappears because the soil just picks it up. In 2005, we had 100 percent of snow pack, but the runoff was 70 percent of what we expected because the springtime had been warm.

The Colorado is now in its second longest ten-year period of low flows on record. If we average over the last ten years, the flow has been at average or less, and this is in an already over-allocated system, as you know better than I do.

The issue concerning the basin, where 30 million people live and where we have seven States reliant on the water, is very much at the edge. The demand exceeded supply about ten years ago, so it does not take a major drought to put us into areas of contention.

And to be perfectly honest, given the uncertainty, certainly, there are issues in introducing drought-resistant crops. There are issues in introducing risk pooling and insurance. But where the Conservation Reserve Programs come in is the admission that we are uncertain about the future, that it leaves us the flexibility to manage for the pieces that we are uncertain about. And I think that is the richest contribution from the standpoint of an understand what the weather incline is doing, naturally or otherwise, and then what the buffers in our system supply.

Senator COWAN. We also need to be thinking about new threats that our farmers and fishermen are facing. The climate change and more frequent and intense extreme weather events threaten our agricultural economy, and I am pleased that the committee is discussing this important issue today.

According to the Climate Vulnerability Initiative, the U.S. is among the top ten countries that will be most adversely affected by desertification and sea level risk, and this does not bode well for either our farmers or fishermen.

Senator BAUCUS. It is a real honor for me to introduce Leon LaSalle. Leon is a Native American rancher. The real deal, several generations. His grandfather, Frank Billy, is one of the first to found the ranch on the Chippewa Cree Reservation of Montana. It actually is part of the Rocky Boys Reservation. We have got seven reservations in Montana. Leon and his family are real stalwarts, and one of the reservations is Rocky Boys and the Chippewa Cree are the Tribal members in that reservation. They raise Black Angus around the Bears Paw Mountains between Rocky Boys, up around Havre, Montana. It is sort of a real standout, that is, as a landmark in our State. We are very proud of it. Leon was featured in a book. The book was called Big Sky Boots. It is the working seasons of a Montana cowboy. He has a great quote in that book. He said he thinks there is a growing disconnect between the general public and agriculture producers. Well, Leon, I have got to tell you, the same thing is true in Washington, D.C. There is a disconnect between the people here and the people who represent the rest of the country, and maybe you can kind of help connect those dots a little bit here when it comes time for you to testify. We are really very honored to have you here because you are a great credit to the Tribe and to the State of Montana and your industry. Leon is also on the Board of Directors of the Montana Stockgrowers and one of the guiding lights there,


We have installed numerous conservation practices specifically designed to preserve and protect our natural resources. Even though we have implemented these conservation measures, there are times when my family’s ranch has been struck so hard by weather- related disasters that we have sought economic assistance. The Federal Livestock Disaster Programs have been that assistance.

The Native American Livestock Feed Program is a great example of a program that helped when feed was short. In drought years, when there is little or no hay to feed our livestock, ranchers like me must purchase hay at a premium. Sometimes by the time the hay reaches the ranch, the freight is more than the cost of the hay itself.

These programs provide the only financial relief available when a rancher was faced with loss of livestock or forage to feed them. There is no insurance for catastrophic livestock losses, such as those experienced by Southeastern Montana ranchers during the horrific wildfires of 2012.

I have helped neighbors prepare applications for LIP, and on one sad occasion, I participated as a third-party witness when several cattle fell through the ice and drowned while trying to shelter themselves from a stinging Montana blizzard.

Mother Nature throws a variety of natural events in the path of a Montana rancher. Our weather is uncertain, sometimes severe. We find our markets are even vulnerable to the effects of drought, as well. Drought has reduced the number of cattle available, and processing facilities have closed as a result, thus affecting our price. If weather and markets are not the issue, then many of my fellow ranchers are challenged by the ever- increasing predator losses.


we now farm 1,500 acres of corn and soybeans as well as a small cow-calf operation in the State. We find our association with various farm organizations, such as the Indiana Soybean Alliance, invaluable to the success of our operation. The Indiana Soybean Alliance is an arm of the American Soybean Association, a trade organization that represents our nation’s 600,000 soybean farmers on national and international policy issues.

It has always been our dream to farm. My husband and I both knew that the only way to make our dreams a reality were to save our pennies and work off-farm incomes in hope that, one day, my father would give us the opportunity to participate in the farming operation. Mike worked in the seed, tile ditching, and bulk milk transport business while I worked in fertilizer, chemical, and crop insurance businesses.

We started farming 600 acres and have increased the operation to 1,500 acres. Roughly one-half of our acres are on a share arrangement with our landlords. We continue to work off- farm, as it is still not self-supporting. Mike sold the milk truck to buy a school bus and I continue to work in the crop insurance and do the farm recordkeeping.

To manage our thin, light soil types, we started our farming operation employing conservation tillage techniques, using such programs as CRP and NRCS cost share funding. To this day, we are still advocates of no-till farming as a way to preserve our soil and maintain soil moisture. As a result of our conservation efforts, our average yields are 150 bushels of corn and 50 bushels of soybeans.

Our best corn was on the farm with the pivot. Under the pivot, it was 200 bushels to the acre. And outside of the pivot, ten. Needless to say, there was not anything to put in the grain bins. Due to the drought and heat, the grain quality was very poor and we even shipped our grain that was going to be fed for livestock.

The number one barrier to increasing our yields is the lack of water. Dry weather in the months of July and August always limit our yield potential. We find crop insurance an effective tool in managing risk when we experience these weather events. We began using crop insurance in 1991 as a way to maintain our cash flow and prevent us from having to borrow money. I actually have lost money over buying crop insurance over the last 20- year time span. It was not until the last two drought years that it actually paid for us to have crop insurance.


I grew up working my grandfather’s 40 acres. Now, my wife and I, Anita, farm 800 acres of sweet and tart cherries. Putting some of the land into the Federal Farm and Ranch Land Protection Program is one of the tools we use to expand our operation. Our youngest daughter and her husband work with us and they someday hope to take over the farm. I also have managed a receiving station for 37 years. I have a working relationship with 35 growers who bring me cherries to be weighed, inspected, shipped to ten different processors in Michigan, Wisconsin, and the State of New York that I work with. I currently am serving as Vice Chair of the Cherry Marketing Institute Board. CMI is a national organization for tart cherry farmers. I am also a Vice Chair of the National Cherry Growers and Industries Foundation, which is a sweet cherry organization. Year in and year out, Michigan produces 75 percent of the United States tart cherries. However, that was not the case in 2012. Last year was the most disastrous year I and the cherry industry have ever experienced. Our winter was much warmer than normal, with little snow and ice on the Great Lakes. In mid-March, there were seven days of 80-degrees temperatures, which is unheard of in Northern Michigan. Cherry trees began to come out of dormancy and began to grow. This left them completely vulnerable to the next 13 freezes in April. This extreme weather in Michigan was one of the worst disasters we had ever seen. Sweet cherries endured freezes slightly better than tart cherries. But to top things off, we were hit with a worst case bacterial canker I had ever seen. There is no treatment for this disease, which affects the fruit buds.

In Michigan, we have the capacity to grow 275 million pounds of tart cherries. In 2012, our total was 11.6 million pounds.

There is no tart cherry insurance available at all for our industry, so my fellow growers and I had no risk management tool to get through this very difficult year. NAP insurance is available, but the policy starts at 50% loss and then pays out only 50% of that number. Farmers are left with only about 25% of coverage, and there is a $100,000 cap. This does not come close to covering our expenses. My costs on my farm alone are between three-quarters and a million dollars.

Tree fruits must be maintained whether there is a crop or not on them. You carry on with the same practices in order to keep them healthy. So expenses remain the same. Imagine working for a year-and-a-half with no paycheck and still having the same expenses.

I worry about our young farmers, who haven’t built up any equity. No income with all the same expenses is formula for disaster. There needs to be something to help farmers stay in business when natural disaster hits. A few days that we have no control over can put us out of business.


My family, our employees, and I produce milk, corn, soybeans, wheat, and hay on our farm at Humboldt in Southeast Nebraska. We milk 135 cows on 1,900 acres of non-irrigated dryland farm, and I have family members at home right now caring for and feeding animals so that I can be here today.

My family, our employees, and I produce milk, corn, soybeans, wheat, and hay on our farm at Humboldt in Southeast Nebraska. We milk 135 cows on 1,900 acres of non-irrigated dryland farm, and I have family members at home right now caring for and feeding animals so that I can be here today. This nation has benefited from a food supply that is plentiful, inexpensive, and of the highest quality, and securing that food supply for the future is clearly a responsible public policy. Facing a growing world population, it is a moral imperative. The impact of fire and drought has hit our farming operation and those of our neighbors. The price of high-quality dairy hay has gone up by 50 percent, and the price of lower- quality hay suitable for beef animals has more than doubled. While we appreciated last year’s release of Conservation Reserve Program acres for emergency haying and grazing, we would like to see efforts made for an earlier release date for those acres. This would dramatically improve the quality and the quantity of those forages.

My neighbors in Western Nebraska have been dealt a particularly hard blow by wildfires, and nearly 400,00 acres, approximately half the State—equivalent to half the State of Rhode Island—were burned in 2012. On those ranches, feed supplies were wiped out, fences were destroyed, and cattle have been liquidated. I would urge you to consider some tax relief to help those ranchers regain their footing. Ladies and gentlemen, our nation’s cattle herd is at a 61-year low and consumers will feel this damage for years.

Livestock contributed $10 billion to Nebraska’s economy in 2011 and crop production contributed $11.7 billion.

Another risk management tool that we employ is diversification. We include both livestock and crops in our business. In order to manage price risk, we constantly watch the changing world markets and the prices for the products we sell, and we accept the challenge of using futures and options contracts. But we, along with thousands of other producers and processors, were victimized by the genius of mismanagement at MF Global when our accounts were frozen in the subsequent bankruptcy. We continue to wait for the return of a slowly rising percentage of our funds.

To further protect our soil and water, we began using cover crops years ago. But participation in the Conservation Security Program gave us a push to go beyond the program requirements, and last year, we planted nearly 60 percent of our acres to cover crops. This practice holds great promise for conserving our soil, saving water, building quality, and sequestering carbon, but we need more research in this area. I urge Congress and this committee to prioritize funding for both basic and applied agricultural research and our Land Grant system of universities created by the Morrill Act of 1862.

Mr. STEFFEN. As I mentioned in my testimony, I would point our again to the no-till techniques we have been using for 40 years on our operation, to save soil, conserve water, and improve our crops. I would also point out that we are making extensive use of cover crops, and those crops planted in conjunction with our traditional crops offer us a way to catch more moisture and snowfall, to improve the way water and rainfall percolates into the soil and it is absorbed so that we are able to capture and store more water in that soil by using those cover crops. It is a way to increase the organic matter levels in the soil, and that makes the soil more productive and increases its ability to hold water.

Senator BAUCUS. Following on Senator Donnelly’s point, it has always struck me how farmers and ranchers have a better perspective on life. They are more philosophical. Why? Because they know they can’t control their fate as much as some people in cities think they can, erroneously. You can’t control the weather. You can’t control price. Cost, you can’t control. You take what you get, but you have got to manage it as well as you possibly can. It is very, very difficult and it is kind of humbling. It gives you a sense of life and the importance of hard work and doing one’s best. Whereas on the other hand, I think a lot of people in the city get a little arrogant and they think they can control everything, and obviously, they can’t.


Posted in Agriculture, BioInvasion, Drought, Extreme Weather, Heat, Soil, Soil, Water, Where to Be or Not to Be | Tagged , , , , , , , | Comments Off on Climate change impacts on agriculture

Nuclear powered airplanes, cars, and tanks

Preface. After all the research I’ve done on rebuildable, not renewable wind and solar, hydrogen, batteries, and other Green dreams of an endless future of growth based on them, I’ve come to see them as just as likely as nuclear airplanes and cars. Not going to happen.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Nuclear Airplanes

Fuels made from biomass are a lot like the nuclear powered airplanes the Air Force tried to build from 1946 to 1961, for billions of dollars. They never got off the ground.  The idea was interesting – atomic jets could fly for months without refueling.  But the lead shielding to protect the crew and several months of food and water was too heavy for the plane to take off.  The weight problem, the ease of shooting this behemoth down, and the consequences of a crash landing were so obvious, it’s amazing the project was ever funded, let alone kept going for 15 years (Wiki 2020).

Although shielding a plane enough to keep the radiation from killing the crew was impossible, some engineers proposed hiring elderly Air Force crews to pilot nuclear planes, because they would die before radiation exposure gave them fatal cancers. Also, the reactor would have to be small enough to fit onto an aircraft, which would release far more heat than a standard one. The heat could risk melting the reactor—and the plane along with it, sending a radioactive hunk of liquid metal careening toward Earth (Ruhl 2019).

Nuclear powered Cars

In 1958, Ford came up with a nuclear-powered concept, the Nucleon car that would be powered by a nuclear reactor in the trunk.

In the 1950s and 1960s, there was huge hype around nuclear energy. Many believed it would replace oil and deliver clean power.

Had Ford gone ahead and made an actual working version of the Nucleon, the company says drivers would have fueled it with Uranium pellets. Ford never actually made a working version, though.

The Nucleon car would use an atomic reactor like a nuclear submarine, fissioning Uranium pellets to heat water into steam that could turn turbines to produce electric power and turn it into mechanical power.

Running low on uranium? Just head to a Uranium station to get a new nuclear capsule, good for another 5,000 miles and no emissions.

Not surprisingly, the Nucleon project was scrapped since small-scale nuclear reactors and lightweight shielding materials couldn’t be developed. Just as well not to have 100+ mph nuclear bombs on our roads (Beedham 2020).

Nuclear Tanks (Peck 2020)

Chrysler’s design was essentially a giant pod-shaped turret mounted on a lightweight tank chassis, like a big head stuck on top a small body. The crew, weapons and power plant would have been housed in the turret, according to tank historian R.P. Hunnicut’s authoritative “A History of the Main American Battle Tank Vol. 2″.

The four-man vehicle would have weighed 25 tons, with a closed circuit TV to protect the crew from the flash of nuclear weapons and to increase the field of vision, running on a vapor-cycle power plant using nuclear fuel.

The Army also considered a nuclear tank to replace M-48 Patton. The 50-ton tank would have been propelled by a nuclear power plant that created heat to drive a turbine engine. The range of the vehicle would have more than 4,000 miles.

Obviously, such a tank would have been extremely expensive and the radiation hazard would have required crew changes at periodic intervals, as well as more ammunition. On top of the usual dangers such as fire or explosion, crews in combat would have worried being irradiated if their tank was hit. Pity the poor mechanics as well who would have had to fix or tow a damaged tank leaking radioactive fuel and spitting out radioactive particles.

Most important of all, nuclear-powered tactical vehicles would destroy the whole concept of nuclear non-proliferation. A fleet of atomic tanks would have meant hundreds or thousands of nuclear reactors spread out all over the place.


Beedham, M. 2020. Remembering the Nucleon, Ford’s 1958 nuclear-powered concept car that never was.

Peck, M. 2020. Why America’s nuclear-powered tank was a dumb idea.

Ruhl, C. 2019. Why There Are No Nuclear Airplanes. Strategists considered sacrificing older pilots to patrol the skies in flying reactors. An Object Lesson. The Atlantic.

Wiki. 2020. Nuclear-powered aircraft.

Posted in Airplanes, Automobiles, Far Out, Nuclear Power | Tagged , , | 5 Comments

Distribution – why it is so hard to add E15 or E85 at a gas station

Preface. One of the huge hurdles to shifting from oil to “something else” is the chicken-or-egg problem of no one buying a new-fuel vehicle with few places to get it, so few are made, so service stations don’t add the new fuel since there are few customers.

This is just one piece of the distribution system, it’s also a problem that ethanol can’t flow in oil or gas pipelines because it corrodes them, and has to be transported by truck or rail using diesel fuel (since trucks can’t burn ethanol or diesohol).

This is why it is hard for service stations to add E15, E85, hydrogen, or any fuel for that matter, though of course each has its own unique costs and difficulties.  Go here to see where alternative fuels can be found by state.

And heaven forbid you put in the wrong fuel. Gasoline cars can not burn diesel fuel, it could lead to needing an engine rebuild.  At best the car chugs and lurches and is towed, then billed up to $1500 to flush the tank, fuel lines, injectors, and fuel pump.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report

Mr. Shane Karr, Vice President of Federal Government Affairs, the Alliance of Automobile Manufacturers

only about 2% of gas stations have an E85 pump, and most are concentrated in the Midwest, where most com ethanol is produced. This makes sense, because keeping production close to point-of-sale is the most affordable approach. But even in states where E85 pumps are concentrated, actual sale of E85 has been low and stagnant. For example, in 2009 Minnesota had 351 stations with an E85 pump (the most of any state) but the average Flexible fuel vehicle (FFV) in the state used just 10.3 gallons of E85 for the whole year.

Achieving vehicle production mandates in H.R. 1687 by producing E85 FFVs would cost consumers well more than $1 billion per year by the most conservative estimates. And these conservative estimates are severely understated for the vehicle mandates of the bill for two reasons: (I) H.R. 1687 requires a new kind of tri-fuel FFV that can run on gasoline, ethanol, methanol, and any combination of the 3 fuels, and which does not exist today; and (2) it will be more expensive to produce tri-fuel FFVs that can comply with H.R. 1687, especially with the forthcoming California Low Emission Vehicles (LEV III) and federal Tier 3 emissions standards along with very aggressive fuel economy/GHG emission requirements through 2025.

Serial No. 112–159. July 10, 2012. The American energy initiative part 23: A focus on Alternative Fuels and vehicles. House of Representatives. 210 pages.

Jeffrey Miller, President of Miller Oil Company, Norfolk, VA.

On behalf of the National Association of Convenience Stores (NACS) Before the House Energy and Commerce Committee, Subcommittee on Energy and Power May 5, 2011 Hearing on “The American Energy Initiative”

My name is Jeff Miller, President of Miller Oil Company headquartered in Norfolk, VA. As of December 31, 2010, the U.S. convenience and fuel retailing industry operated 146,341 stores of which 117,297 (80.2%) sold motor fuels. In 2009, our industry generated $511 billion in sales (one of every 28 dollars spent in the United States), employed more than 1.5 million workers and sold approximately 80% of the nation’s motor fuel.

To fully understand how fuels enter the market and are sold to consumers, it is important to know who is making the decision at the retail level of trade. Our industry is dominated by small businesses. In fact, of the 117,297 convenience stores that sell fuel, 57.5% of them are single-store companies – true mom and pop operations. Overall, nearly 75% of all stores are owned and operated by companies my size or smaller – and we all started with just a couple of stores.

Many of these companies – mine included – sell fuel under the brand name of their fuel supplier. This has created a common misperception in the minds of many policymakers and consumers that the large integrated oil companies own these stations. The reality is that the majors are leaving the retail market place and today own and operate fewer than 2% of the retail locations.

Taking a chance by offering a new candy bar is very different from switching my fueling infrastructure to accommodate a new fuel. So when a new fuel product becomes available, our decision to offer it to our customers takes more time. We need to know that our customers want to buy it, that we can generate enough return to justify the investment, and that we can sell the fuel legally. These are the fundamental issues that face the introduction of new renewable and alternative fuels.

Today, most of the fuel sold in the United States is blended with 10% ethanol. The transition to this fuel mix was not complicated, but it was not without challenges. When ethanol became more prevalent in my market, we realized what a powerful solvent it is. Ethanol forced us to clean our storage tanks and change our filters frequently to avoid introducing contaminants into the fuel tanks of our customers’ vehicles. Despite our best efforts, however, there were times when the fuel a customer purchased caused problems with their vehicles. In those situations, it was our responsibility to correct the damage. And while the transition to E10 required no significant changes to equipment or systems, it taught us some lessons that influence our decisions concerning new fuels.

Retailers are now hearing reports from Washington that the use of fuel containing 15% ethanol is authorized.

Currently, there is essentially only one organization that certifies our equipment – Underwriters Laboratories (UL). UL establishes specifications for safety and compatibility and runs tests on equipment submitted by manufacturers for UL listing. Once satisfied, UL lists the equipment as meeting a certain standard for a certain fuel.

Prior to last spring, however, UL had not listed a single motor fuel dispenser (a.k.a, pump) as compatible with any fuel containing more than 10% ethanol. This means that any dispenser in the market prior to last spring – which would represent the vast majority of my dispensers – is not legally permitted to sell E15, E85 or anything above 10% ethanol – even if it is technically able to do so safely.

If I use non-listed equipment, I am in violation of OSHA regulations and may be violating my tank insurance policies, state tank fund program requirements, bank loan covenants, and potentially other local regulations. Furthermore, if my store has a petroleum release from that equipment, I could be sued on the grounds of negligence for using non-listed equipment, which would cost me significantly more than the expense of cleaning up the spill.

So, if none of my dispensers are UL-listed for E15, what are my options?

Unfortunately, UL will not re-certify any equipment. Only those units manufactured after UL certification is issued are so certified – all previously manufactured devices, even if they are the same model, are subject only to the UL listing available at the time of manufacture. This means that no retail dispensers, except those produced after UL issued a listing last spring, are legally approved for E10+ fuels.

In other words, the only legal option for me to sell E15 is to replace my dispensers with the specific models listed by UL. On average, a retail motor fuel dispenser costs approximately $20,000.

It is less clear how many of my underground storage tanks and associated pipes and lines would require replacement. Many of these units are manufactured to be compatible with high concentrations of ethanol, but they may not be listed as such. In addition, the gaskets and seals may need to be replaced to ensure the system does not pose a threat to the environment. If I have to crack open concrete to replace seals, gaskets or tanks, my costs can escalate rapidly and can easily exceed $100,000 per location.


The second major issue I must consider is the effect of the fuel on customer engines and vehicles. Having dealt with engine problems associated with fuel contamination following the introduction of E10, I am very concerned about the potential effect a fuel like E15 would have on vehicles. The EPA decision concerning E15 is very challenging. Under EPA’s partial waiver, only vehicles manufactured in model year 2001 or more recently are authorized to fuel with E15. Older vehicles, motorcycles, boats, and small engines are not authorized to use E15.

How am I supposed to prevent the consumer from buying the wrong fuel? I can deal with the responsibility for fuel quality and contamination control, but self-service customer misfueling is a much more difficult challenge to control.

In the past, when we have introduced new fuels – like unleaded gasoline or ultra-low sulfur diesel – they were backwards compatible; i.e. older vehicles could use the new fuel. In addition, newer vehicles were required to use the new fuel, creating a guaranteed market demand.

Such is not the case with E15 – legacy vehicles are not permitted to use the new fuel. Doing so will violate Clean Air Act standards and could cause engine performance or safety issues. Yet, there are no viable options to retroactively install physical countermeasures to prevent misfueling. Consequently, my risk of liability if a customer uses E15 in the wrong engine – whether accidentally or intentionally – is significant.

First of all, I could be fined under the Clean Air Act for misuse of the fuel – this has happened before. When lead was phased out of gasoline, unleaded fuel was more expensive than leaded fuel. To save a few cents per gallon, some consumers physically altered their vehicle fill pipes to accommodate the larger leaded nozzles either by using can openers or by using a funnel while fueling. Retailers had no ability to prevent such behavior, but the EPA often levied fines against retailers for not physically preventing the consumer from bypassing the misfueling countermeasures.

My understanding is EPA has told NACS that the agency would not be targeting retailers for consumer misfueling. But that provides me with little comfort – EPA policy can change in the absence of specific legal safeguards. Further, the Clean Air Act includes a private right of action and any citizen can file a lawsuit against a retailer who does not prevent misfueling. Whether the retailer is found guilty does not change the fact that defending against such claims can be very expensive.

Finally, I am very concerned about the effect of E15 in the wrong engine. Using the wrong fuel could void an engine’s warranty, cause engine performance problems or even compromise the safety of some equipment. A consumer may seek to hold me liable for these situations even if my company was not responsible for the misfueling. Defending my company against such claims is financially expensive, but also expensive from a customer-relations perspective.


Retailers are also concerned about long-term liability exposure. Our industry has experience with being sued for selling fuels that were approved at the time but later ruled defective. What assurances are there that such a situation will not repeat itself with new fuels being approved for commerce?

For example, E15 is approved only for certain engines and its use in other engines is prohibited by the EPA due to associated emissions and performance issues. What if E15 does indeed cause problems in non-approved engines or even in approved engines? What if in the future the product is determined defective, the rules are changed and E15 is no longer approved for use in commerce? There is significant concern that such a change in the law would be retroactively applied to any who manufactured, distributed, blended or sold the product in question.

Retailers are hesitant to enter new fuel markets without some assurance that our compliance with the law today will protect us from retroactive liability should the law change in the future. It seems reasonable that law abiding citizens should not be held accountable if the law changes in the future. Congress could help overcome significant resistance to new fuels by providing assurances that market participants will only be held to account for the laws as they exist at the time and not subject to liability for violating a future law or regulation.


The final challenge we face is the rate at which consumers will adopt the new fuels. Assume all the other issues are resolved, I have to ask myself: Will my customers purchase the fuel? It is important to note that this is the first fuel transition in which no person is required to purchase the fuel, unlike prior transitions to unleaded gasoline and ultra-low sulfur diesel fuel.

In the situation facing E15, only a subset of the population (about 65% of vehicles) is authorized to buy it. Yet the auto industry is not fully supportive of its use in anything except flexible fuel vehicles (about 3% of vehicles). This situation could dramatically reduce consumer acceptance. The risk of misfueling and potentially alienating customers if E15 causes performance issues also is a serious concern.

With these unknowns, how can I calculate an accurate return on my investment to install E15 compatible equipment? Again, this is not like offering a new candy bar – to sell E15 I will likely have to spend significant resources.

As new fuels enter the market, their compatibility with vehicles and their performance characteristics compared to traditional gasoline will be critically important to determining consumer acceptance. In addition, the cost of entry for retailers will influence the return on investment calculations required to determine whether to invest in the new fuel.


NACS believes there are options available to Congress to help the market overcome these challenges. I have referenced E15 in this testimony because it is a fuel with which we are all familiar due to its current considerations at EPA. However, E15 alone will not satisfy the renewable fuel objectives of the country. Other products must be brought to market and how they interact with the refueling infrastructure and the consumer’s vehicles should be critical considerations to Congress when deciding whether to support their development and introduction.

Regardless which fuels are introduced in the future, the following recommendations can help lower the cost of entry and provide retailers with greater regulatory and legal certainty necessary for them to offer these new fuels to consumers:
First, because UL will not retroactively certify any equipment, Congress should authorize an alternative method for certifying legacy equipment. Such a method would preserve the protections for environmental health and safety, but eliminate the need to replace all equipment simply because the certification policy of the primary testing laboratory will not re-evaluate legacy equipment. NACS was supportive of legislation introduced in the House last Congress Reps. Mike Ross (D-AR) and John Shimkus (R-IL) as H.R. 5778. This bill directed the EPA to develop guidelines for determining the compatibility of equipment with new fuels and stipulates equipment that satisfied such guidelines would thereby satisfy all laws and regulations concerning compatibility.

Second, Congress can require EPA to issue labeling regulations for fuels that are authorized for only a subset of vehicles and ensure that retailers who comply with such requirements satisfy their requirements under the Clean Air Act and protect them from violations or engine warranty claims in the event a self-service customer ignores the notifications and misfuels a non-authorized engine. H.R. 5778 also included provisions to achieve these objectives.

Third, Congress can provide market participants with regulatory and legal certainty that compliance with current applicable laws and regulations concerning the manufacture, distribution, storage and sale of new fuels will protect them from retroactive liability should the laws and regulations change at some time in the future.

Finally, Congress should evaluate the prospects for the marketing of infrastructure-compatible fuels and support the development of such fuels. These could aid compliance with the renewable fuels standard and save retailers, engine makers and consumers billions of dollars. Policymakers might consider establishing characteristics that new fuels must possess so that equipment and engines can be manufactured or retrofitted to accommodate whichever new fuel provides the greatest benefit to consumers and the economy.

If Congress takes action to lower the cost of entry and to remove the threat of unreasonable liability, more retailers may be willing to take a chance and offer a new renewable fuel. By lowering the barriers to entry, Congress will give the market an opportunity to express its will and allow retailers to offer consumers more choice. If consumers reject the new fuel, the retailer can reverse the decision without sacrificing a significant investment, but new fuels will be given a better opportunity to successfully penetrate the market.

Serial No. 112–159. July 10, 2012. The American energy initiative part 23: A focus on Alternative Fuels and vehicles. House of Representatives. 210 pages.

Jack Gerard, President and CEO of the American Petroleum Institute. Over the past 7 years, the two RFS laws passed in 2005 and in 2007 have substantially expanded the role of renewables in America. Biofuels are now in almost all gasoline. While API supports the continued appropriate use of ethanol and other renewable fuels, the RFS law has become increasingly unrealistic, unworkable, and a threat to consumers. It needs an overhaul. Most of the problems relate to the law’s volume requirements. These mandates call for blending increasing amounts of renewable fuels into gasoline and diesel. Although we are already close to blending an amount that would result in a 10 percent concentration level of ethanol in every gallon of gasoline sold in America, that which is the maximum known safe level, the volumes required will more than double over the next 10 years. The E10, or 10 percent ethanol blend that we consume today could, by virtue of RFS volume requirements, become at least an E20 blend in the future. This would present an unacceptable risk to billions of dollars in consumer investment in vehicles, a vast majority of which were designed, built, and warranted to operate on a maximum blend of E10.

It also would put at risk billions of dollars of gasoline station equipment in thousands of retail outlets across America, most owned by small independent businesses. I believe well over 60 percent of retail establishments in this area are Ma and Pa operations.

Vehicle research conducted by the Auto Oil Coordinated Research Council shows that E15 could also damage the engines of millions of cars and light trucks, estimates exceeding five million vehicles on the road today. E20 blends may have similar, if not worse, compatibility issues with engines and service station attendants.

The RFS law also requires increasing use of cellulosic ethanol, an advanced form of ethanol that can be made from a broader range of feed stocks. The problem is, you can’t buy the fuel yet because no one is making it commercially. While EPA could waive that provision, it has decided to require refiners to purchase credits for this nonexistent fuel, which will drive up costs and potentially hurt consumers. Mandating the use of fuels that do not exist is absurd on its face and is inexcusably bad public policy.

To date, E85 has faced low consumer acceptance as FFV owners use E85 less than 1% of the time. The fuel economy of an FFV operated on E85 is approximately 25-30% lower than when fueled with gasoline due to ethanol’s lower energy content. Also, less than 2% of retail gasoline stations offer E85, which has high installation costs. In 2010 and 2011, EPA approved the use of E15 for a portion of the motor vehicle fleet in order to accommodate the RFS law’s volume increases. We believe these actions were premature and unlawful, and present an unacceptable risk to billions of dollars in consumer investments in vehicles. They also put at risk billions of dollars of gasoline station pump equipment in scores of thousands of retail outlets across America, most owned by small independent businesses. E15 is a different transportation fuel, well outside the range for which the vast majority of U.S. vehicles and engines have been designed and warranted. E15 is also outside the range for which service station pumping equipment has been listed and proven to be safe and compatible and conflicts with existing worker and public safety laws outlined in OSHA and Fire Codes. EPA should not have proceeded with E15, especially before a thorough evaluation was conducted to assess the full range of short- and long-term impacts of increasing the amount of ethanol in gasoline on the environment, on engine and vehicle performance, and on consumer safety. Research on higher blends was already underway when EPA approved El5 in 2010 and 2011. In response to the passage of EISA in 2007, the oil and natural gas industry, the auto industry, and other stakeholders, including EPA and DOE, recognized in early 2008 that substantial research was needed in order to assess the impact of higher ethanol blends including the compatibility of ethanol blends above 10% (E10+) with the existing fleet of vehicles and small engines. Through the Coordinating Research Council (CRC), the oil and auto industries developed and funded a comprehensive multi-year testing program prior to the biofuels industry’s E15 waiver application. API worked closely with the auto and off-road engine industries and with EPA and DOE to share and coordinate research plans. Yet, EPA approved the E15 waiver request before this research effort was finished and the results thoroughly evaluated. The potential for harm from that decision is substantial, as suggested by the results of various research studies, including testing performed by DOE’s National Renewal Energy Laboratory and by the CRC, have been completed to date. The DOE research shows an estimated half of existing service station pumping equipment may not be compatible with a 15% ethanol blend. The CRC research shows that E15 could also damage the engines of millions of cars and light trucks.

E20 may have similar, if not worse, compatibility issues with engines and service station equipment.


We are the Nation’s eighth largest convenience retailer of petroleum products and convenience items in over 13 States. Our wholesale oil division, Gulf Oil, carries and merchandises over 350,000 barrels of petroleum products and biofuels over 29 States, $13 billion revenue places us in the top 50 private companies in the country. We employ 8,000 employees,

We do not drill, we do not refine petroleum products. What we care to sell are products that our customers want to buy that are most economic for them to achieve their desired transport, heating, and other energy uses in a lawful manner.

We blend—in addition to selling petroleum products, which is our primary product that we sell, we blend over 1 million gallons a day of biofuels across our system, and just recently, we have purchased 24 Class A trucks to begin to fuel on natural gas to deliver our fuel products to our stations and stores.

We believe that a sound energy policy rests on four bedrocks. One is that we have diverse fuel sources, and there are two reasons for that. The future is unknowable. The new shale technology that has taken over the industry in natural gas was unheard of more than 2 decades ago. Technology and events are beyond our abilities to understand where we are going, and so to bet any of our future on one single source of fuel would be a mistake. We believe diversity in all systems ensures health and stability. And so we look for diversity in fuel, not only by fuel type, but to make sure that we are not concentrated in taking it from one region, particularly the Middle East and unstable regions.

I do want to point out to all the members that we have billions, hundreds of billions of dollars invested in terminals, gas stations, barges, transportation, and we have to live with the realities of the marketplace and the particulars.

America’s love affair with the automobile is not going away. Neither is the need for transportation fuels that underpin the economy and create jobs. In a country as vast as ours with a density of 79 people per square mile (as opposed to the Netherlands with 1300 people per square mile), the cost of transport is central to economic health.

When total national energy costs exceed 16% of GDP a recession or worse is almost always the result. The United States’ current accounts trade balance for all energy products recently exceeded $1 trillion dollars, and while it has currently been reduced to one half that amount on an annualized basis we look forward to the day when the United States is a net energy exporter. Not only will that be positive to GDP and job growth, but it will position us to revitalize our industrial production, especially in energy-intensive industries with an eye toward value added product exports. And no policy would be more beneficial for the spread of world democracy

Our industry is dominated by small businesses. In fact, of the 120,950 convenience stores that sell fuel, almost sixty percent of them are single-store companies – true mom and pop operations. Many of these companies sell fuel under the brand name of their fuel supplier. This has created a common misperception in the minds of many policymakers and consumers that the large integrated oil companies own these stations. The reality is that the majors are leaving the retail marketplace and today own and operate fewer than 2% of the retail locations. Although a store may sell a particular brand of fuel associated with a refiner, the vast majority are independently owned and operated like mine. When people pull into an Exxon or a BP station, the odds are good that they are in fact refueling at a small mom-and-pop operation.

THE BLEND WALL AND THE NEED FOR A CONGRESSIONAL FIX. Since the enactment of the Energy Independence and Security Act (EISA) of2007, we have heard much about the impending arrival of the so-called “blend wall” – the point at which the market cannot absorb any additional renewable fuels. Most of the fuel sold in the United States today is blended with 10% ethanol. If 10% ethanol were blended into every gallon of gasoline sold in the nation in 2011 (33.9 billion gallons), the market would reach a maximum of 13.39 billion gallons. However, the 2012 statutory mandate for the RFS is 15.2 billion gallons. Meanwhile, the market for higher blends of ethanol (E85) for flexible fuel vehicles (FFVs) has not developed as rapidly as some had hoped. Clearly, we have reached the blend wall.

EPA recently authorized the use ofE15 in certain vehicles. However, this has so far done very little to expand the use of renewable fuels, due largely to retailers’ liability and compatibility concerns, as well as state and local restrictions on selling E15. Congress can do something immediately to mitigate other obstacles preventing new fuels from entering the market. H.R. 4345, the Domestic Fuels Protection Act of 2012-currentiy before the subcommittee on Environment and the Economy-addresses three of these obstacles: infrastructure compatibility, liability for consumer misuse of fuels, and retroactive liability of the rules governing a fuel change in the future.

The reason the retail market is unable to easily accommodate additional volumes of renewable fuels begins with the equipment found at retail stations. By law, all equipment used to store and dispense flammable and combustible liquids must be certified by a nationally recognized testing laboratory. These requirements are found in regulations of the Occupational Safety and Health Administration. Currently, there is essentially only one organization that certifies such equipment, Underwriters Laboratories (UL). UL establishes specifications for safety and compatibility and runs tests on equipment submitted by manufacturers for UL listing. Once satisfied, UL lists the equipment as meeting a certain standard for a certain fuel. Prior to 20I0, UL had not listed a single motor fuel dispenser (aka a gas pump) as compatible with any fuel containing more than 10% ethanol. This means that any dispenser in the market prior to early 20lOis not legally permitted to sell E15, E85 or anything above 10% ethanol – even if it is able to do so safely.

If a retailer fails to use listed equipment, that retailer is violating OSHA regulations and -may be violating tank insurance policies, state tank fund program requirements, bank loan covenants, and potentially other local regulations. In addition, the retailer could be found negligent per se based solely on the fact that his fuel dispensing system is not listed by UL. This brings us to the primary challenge: if no dispenser prior to early 20I0 was listed as compatible with fuels containing greater than ten percent ethanol, what options are available to retailers to sell these fuels? In order to comply with the law, retailers wishing to sell E I 0+ fuels can only use equipment specifically listed by UL as compatible with such fuels. Because UL did list any equipment as compatible with E10+ fuels until 2010, only those units produced after that date can legally sell E I 0+ fuels. All previously manufactured devices, even if they are the exact same model using the exact same materials, are subject only to the UL listing available at the time of manufacture. (UL policy prevents retroactive certification of equipment.)

Practically speaking, this means that a vast majority of retailers wishing to sell EIO+ fuels must replace their dispensers. This costs an average of $20,000 per dispenser. It is less clear how many underground storage tanks and associated pipes and lines would require replacement. Many of these units are manufactured to be compatible with high concentrations of ethanol, but they may not be listed as such. Further, if there are concerns with gaskets and seals in dispensers, care must be given to ensure the underground gaskets and seals do not pose a threat to the environment. Once a retailer begins to replace underground equipment, the cost can escalate rapidly and can easily exceed $100,000 per location.

The second major issue facing retailers is the potential liability associated with improperly fueling an engine with a non-approved fuel. The EPA decision concerning EI5 puts this issue into sharp focus for retailers. Under EPA’s partial waiver, only vehicles manufactured in model year 2001 or more recently are authorized to fuel with E15. Older vehicles, motorcycles, boats, and small engines are not authorized to use E15. For the retailer, bifurcating the market in this way presents serious challenges. For instance, how does the retailer prevent the consumer from buying the wrong fuel? Typically, when new fuels are authorized they are backwards compatible so this is not a problem. In other words, older vehicles can use the new fuel. When EPA phased lead out of gasoline in the late I 970s and early 1980s, for example, older vehicles were capable of running on unleaded fuel newer vehicles, however, were required to run only on unleaded. These newer vehicle gasoline tanks were equipped with smaller fill pipes into which a leaded nozzle could not fit – likewise, unleaded dispensers were equipped with smaller nozzles. E 15 is very different: legacy engines are not permitted to use the new fuel. Doing so will violate Clean Air Act standards and could cause engine performance or safety issues. Yet there are no viable options to retroactively install physical counter measures to prevent misfueling.

Retailers could be subject to penalties under the Clean Air Act for not preventing a customer from misfueling with E15. This concern is not without justification. In the past, retailers have been held accountable for the actions of their customers. For example, because unleaded fuel was more expensive than leaded fuel, some consumers physically altered their vehicle fill pipes to accommodate the larger leaded nozzles either by using can openers or by using a funnel while fueling. We may see similar behavior in the future given the high price of gasoline relative to ethanol. As in the past, the retailer will not be able to prevent such practices, but in the case of leaded gasoline the EPA levied fines against the retailer for not physically preventing the consumer from bypassing the misfueling counter measures. To EPA’s credit, they have asserted in meetings with NACS and SIGMA that they would not be targeting retailers for consumer misfueling. But that provides little comfort to retailers. EPA policy can change in the absence of specific legal safeguards. Additionally, the Clean Air Act includes a private right of action and any citizen can file a lawsuit against a retailer that does not prevent misfueling. Whether the retailer is found guilty does not change the fact that defending against such claims is very expensive. Further, the consumer may seek to hold the retailer liable for their own actions. Using the wrong fuel could void an engine’s warranty, cause engine performance problems or even compromise the safety of some equipment. In all situations, some consumers may seek to hold the retailer accountable even when the retailer was not responsible for the improper use of the fuel. Once again, defending such claims is expensive.

An EPA decision to approve E15 for 2001 and newer vehicles is not consistent with the terms of most warranty policies issued with these affected vehicles. Consequently, while using E15 in a 2009 vehicle might be lawful under the Clean Air Act, it may in fact void the warranty of the consumer’s vehicle. Retailers have no mechanism for ensuring that consumers abide by their vehicle warranties – it is the consumer’s responsibility to comply with the terms of their contract with their vehicle manufacturer. Therefore, H.R. 4345 stipulates that no person shall be held liable in the event a self-service customer introduces a fuel into their vehicle that is not covered by their vehicle warranty.

General Liability Exposure Finally, there are widespread concerns throughout the retail community and with our product suppliers that the rules of the game may change and we could be left exposed to significant liability. For example, EI5 is approved only for certain engines and its use in other engines is prohibited by the EPA due to associated emissions and performance issues. What if E 15 does indeed cause problems in non-approved engines or even in approved engines? What if in the future the product is determined defective, the rules are changed and E 15 is no longer approved for use in commerce? There is significant concern that such a change in the law would be retroactively applied to anyone who manufactured, distributed, blended or sold the product in question.

Contrary to popular misconception, fuel marketers prefer cheap gasoline. The less the consumer pays at the pump, the more money the consumer has to spend in our stores, where our profit margins are significantly greater.

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Can Geothermal power make up for declining fossil fuels?

Preface. Geothermal power plants are cost justified only in places where volcanic or tectonic activity brings heat close to the surface, mainly in “ring of fire” nations and volcanic hot spots like Hawaii.   Even then drilling can only be done where the rocks below are fractured in certain ways with particular chemistries.  A great deal of heat needs to be fairly close to the surface as well, since drilling deeply is quite expensive.

The reasons drilling is so difficult and expensive are:

  1. You have to remove all the rock you’ve cut from the hole which gets harder and harder as the hole gets deeper
  2. Drilling erodes the drill bit and pipe so you have to keep replacing them
  3. Drilling heats the rock up, so it has to be cooled down to keep the equipment from getting damaged
  4. The deeper you go, the hotter it gets, and the more expensive the drilling equipment gets using special metallurgy
  5. the fluids wreak havoc on boreholes by destroying their liners and concrete plugs, and are very corrosive,  it’s scary stuff (Oberhaus 2020)
  6. Pipes have to be thick and heavy to survive pumping pressures, about 40-50 pounds per foot. A deep well might have a million pounds of piping.  Just its own weight can break it if not well made, and at some point it’s hard to find hoisting equipment with enough power to lift it
  7. If the rocks aren’t stable, the hole may collapse
  8. There are often pressurized fluids that want to flow up the hole that can cause a dangerous blowout
  9. Some deep rock leaches toxic or radioactive materials, which increases costs to dispose of them and can make the drilling equipment hazards to touch
  10. drilling deeper than 1,500 meters (4900 feet) requires special care because the unknown factors relating to the subsurface increase. “Below these depths, the stability of the drilling site is more and more difficult and poor decisions could trigger an earthquake.” (Minetto 2020)

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Geothermal provides less than half a percent of U.S. electric power.

NREL (2016) recently looked at whether the current 3.8 GWe could be doubled to 7.6 GWe by 2020,  and found that only .784 GWe was likely, with another .856 GWe possible with expedited development (these projects often take 5 years), and another 1.722 GWe if financing could be found and permits given. The report concluded it was unlikely that doubling geothermal electricity capacity could happen by 2020.

There’s not enough geothermal to make a dent in the “imminent liquid fuels crunch (Murphy 2012).

Abundant, potent, or niche? Hmmm. It’s complex. On paper, we have just seen that the Earth’s crust contains abundant thermal energy, with a very long depletion time. But extraction requires a constant effort to drill new holes and share the derived heat. Globally we use 12 TW of energy.  Heat released from all land is 9 TW, but practical utilization is impossible. For one thing, the efficiency with which we can produce electricity dramatically reduces the cap to the 2 TW scale. And for heating just 1 home, you’d need to capture heat from an area 100 meters on a side. Clearly, geothermal energy works well in select locations (geological hotspots). But it’s too puny to provide a significant share of our electricity, and direct thermal use requires substantial underground volumes/areas to mitigate depletion. All this on top of requirements to place lots of tubing infrastructure kilometers deep in the rock (do I hear EROEI whimpering?). And geothermal is certainly not riding to the rescue of the imminent liquid fuels crunch.

Geothermal consumes massive amounts of water & energy

Geothermal plants use a lot of energy to keep the water hot enough to prevent minerals from precipitating out and clogging pipes and heat exchangers. Some were poorly managed and exhausted after running out of water. Maintenance costs are high due to corrosion from corrosive gases and aerosols, etc.

“As with fossil fuel power plants and concentrating solar power, increases in air and water temperatures can reduce the efficiency with which geothermal facilities generate electricity, according to DOE’s 2013 assessment. Geothermal power plants can also withdraw and consume significant quantities of water, according to DOE, making them susceptible to water shortages caused by changes in precipitation or warming temperatures” (USGAO 2014).

94% of all known U.S. geothermal resources are located in California.

Figure 1. Map of United States geothermal regions.

Figure 1. Map of United States geothermal regions.

Source: NREL 2016. United States geothermal total estimated project capacity (in megawatts) by geothermal region (2012-2015). This figure highlights areas that had significant proportions of projects that were either discontinued or postponed: Idaho Batholith (100%), Gulf of California Rift Zone (77%), Alaska (45%), Northwest Basin and Range (47%), the Walker-Lane Transition Zone (44%), and the Northern Basin and Range (36%).

Figure 2. Source: NREL 2016. United States geothermal total estimated project capacity (in megawatts) by geothermal region (2012-2015). This figure highlights areas that had significant proportions of projects that were either discontinued or postponed: Idaho Batholith (100%), Gulf of California Rift Zone (77%), Alaska (45%), Northwest Basin and Range (47%), the Walker-Lane Transition Zone (44%), and the Northern Basin and Range (36%).

Lack of transmission lines strands many geothermal sites

Only a few urban areas in California and other states with geothermal resources (i.e. volcanoes, hot springs, and geysers) are near enough to exploit them.  This is because the cost of adding very long transmission lines to faraway geysers can make a geothermal resource too expensive – they’re already very expensive even when closer to cities.  On top of that, unless the geothermal resource is very large, more of the power is lost over transmission lines than conventional power plants (CEC 2014 page 73).

Getting the financing is hard

The current environment for financing independent power projects is challenging. These challenges include weak corporate profits, changes in corporate direction, and heightened risk aversion. As a result, a number of the financial institutions that were lead underwriters in the past are either pulling out of the market or are taking a lower profile in project financing.

Biomass and geothermal projects are considered riskier than natural gas, solar, and wind projects. This is seen in the lower leverage, higher pricing, and higher DSCRs than for the other generating technologies. The higher level of project risk for biomass and geothermal projects is partly attributed to the technology and fuel sources. Solid fuel power plants require more project infrastructure than do other fuel types. Geothermal projects have inherently uncertain steam supplies as has been seen at the Geysers. Some of the risk also is based on the relatively small number of these projects being developed.

The steadily increasing wheeling access charges the California ISO expects to put in place over the next decade represent a growing, significant cost to renewable developers who find their best renewable resources in locations that are distant from demand.

They can be risky to develop since they don’t always work out. In June 1980, Southern California Edison (SCE) began operation of a 10 MW experimental power plant at the Brawley geothermal field, also in Imperial County. However, after a few years of operation further development was ceased due to corrosion, reservoir uncertainties, and the presence of high salinity brines.

Issues with geothermal installations

There are two components to the geothermal resource base: hydrothermal (water heated by Earth) that exists down to a depth of about 3 km, and enhanced geothermal systems (EGS) associated with low-permeability or low-porosity heated rocks at depths down to 10 km.

A National Academy of Sciences concluded that hydrothermal resources are too small to have a major overall impact on total electricity generation in the United States — at best 13 GW of electric power capacity in identified resources (NAS 2009).

The largest geothermal installation in the world is the Geysers in Northern California, occupying 30 square miles. The 15 power plants have a total net generating capacity of about 725 MW of electricity—enough to power 725,000 homes (Heinberg).

  • Geothermal plants often emit hydrogen sulfide, CO2, and toxic sludge containing arsenic, mercury, sulfur, and silica  compounds.
  • Extra land may be needed to dispose of wastes and excess salts
  • groundwater and freshwater can be a limiting force since both hydrothermal and dry rock systems need water
  • Maintenance costs are high because the steam is corrosive and deposits minerals, which clogs pipes and destroys valves.
  • When you extract energy from just about anything it decreases, the same is true for geothermal. So you endlessly need to keep looking for more prospects. For example, the “Geysers” area of Northern California has gone from 2000 MWe to 850 MWe since it was first tapped for power. J. Coleman. 15 Apr 20001. Running out of steam: Geothermal field tapped out as alternative energy source. Associated Press.
  • We need a breakthrough in materials that won’t melt to drill deeply enough to get significant power in non-geothermal areas.
  • You can lose a significant amount of steam because the water you pour down the hole is so hot it fractures rocks and escapes into cracks before it can return up the steam vent. Over time, less and less steam for power generation is produced.
  • If you wanted to tap the heat without any geothermal activity, it becomes energy intensive, because you have to drill much deeper (geothermal sources are already near the surface), the rock below has to be fractured (which it already is in geothermal regions) to release steam, and fracturing and keeping the rock fractured takes far more ongoing energy than the initial drilling.
  • No one has figured out how to do hot dry rock economically – time’s running out.
  • Even if Geodynamics succeeds in scaling their experiments into a real geothermal power plant, it will in huge part be due to the location: “This is the best spot in the world, a geological freak,” Geodynamics managing director Bertus de Graaf told Reuters. “It’s really quite serendipitous, the way the elements — temperature, tectonics, insulating rocks — have come together here.

Although it would be great if we could access the heat 3 to 10 km below the earth, such operations would cool down so much that they’d have to be shut down within 20 to 30 years, and production wells would need to be re-drilled every 4 to 8 years meanwhile.  We don’t know how to do this anyhow.  Despite oil and gas drilling, we don’t have much experience going this deep or know how to enhance heat transfer performance for lower-temperature fluids in power production. Another challenge is to improve reservoir-stimulation techniques so that sufficient connectivity within the fractured rock can be achieved.  France has been trying to make this work for over 2 decades, so don’t hold your breath (NAS 2009).

Geothermal Technology Costs

Geothermal technologies remain viable in California, although they are subject to a number of limitations that are likely to reduce the number of sites developed in California.

Geothermal resource costs are driven largely by the highly variable and significant costs of drilling and well development. These costs are unique to each site and represent a significant risk on the part of the developer. While a successful well may be able to produce electricity at low cost, other wells in the same area may require much more investment in time and resources before they are producing efficiently. Costs for new geothermal plants are projected to increase slightly over the coming years. Limitations of location and drilling are unlikely to see improvement in California, while nationally there are very few geothermal projects under development.

Factors Affecting Future Geothermal Development

California’s relative abundance of geothermal resources in comparison to the rest of the United States does not mean that geothermal power production would be viable or cost-effective everywhere in the state. Developers must consider multiple factors of cost and viability when deciding where to locate new geothermal plants. In turn, these considerations drive the estimates of future costs of new geothermal power plants in California. Considerations for developing geothermal power plants in liquid-dominated resources include (Kagel, 2006):

  • Exploration Costs- Exploration and mapping of the potential geothermal resource is a critical and sometimes costly activity. It effectively defines the characteristics of the geothermal resource.
  • Confirmation Costs-These are costs associated with confirming the energy potential of a resource by drilling production wells and testing their flow rates until about 25 percent of the resource capacity needed by the project is confirmed.
  • Site/Development Costs- Covering all remaining activities that bring a power plant on line, including:   Drilling- The success rate for drilling production wells during site development average 70 percent to 80 percent (Entingh, et al., 2012). The size of the well and the depth to the geothermal reservoir are the most important factors in determining the drilling cost.
  • Project leasing and permitting-Like all power projects, geothermal plants must comply with a series of legislated requirements related to environmental concerns and construction criteria.
  • Piping network- The network of pipes are needed to connect the power plant with production and injection wells. Production wells bring the geothermal fluid (or brine) to the surface to be used for power generation, while injection wells return the used fluid back to the geothermal system to be used again.
  • Power plant design and construction- In designing a power plant, developers must balance size and technology of plant materials with efficiency and cost effectiveness. The power plant design and construction depends on type of plant (binary or flash) as well as the type of cooling cycle used (water or air cooling).
  • Transmission- Includes the costs of constructing new lines, upgrades to existing lines, or new transformers and substations.

Another important factor contributing to overall costs is O&M costs, which consist of all costs incurred during the operational phase of the power plant (Hance, 2005). Operation costs consist of labor; spending for consumable goods, taxes, royalties; and other miscellaneous charges.

Maintenance costs consist of keeping equipment in good working status. In addition, maintaining the steam field, including servicing the production and injection wells (pipelines, roads, and so forth) and make-up well drilling, involves considerable expense.

Development factors are not constant for every geothermal site. Each of the above factors can vary significantly based on specific site characteristics.

Make-up drilling aims to compensate for the natural productivity decline of the project start-up wells by drilling additional production wells. drive costs for geothermal plants (not mentioned directly above since they are highly project specific) are project delays, temperature of the resource, and plant size.

The temperature of the resource is an essential parameter influencing the cost of the power plant equipment. Each power plant is designed to optimize the use of the heat supplied by the geothermal fluid. The size, and thus cost, of various components (for example, heat exchangers) is determined by the temperature of the resource. As the temperature of the resource increases, the efficiency of the power system increases, and the specific cost of equipment decreases as more energy is produced with similar equipment. Since binary systems use lower resource operating temperatures than flash steam systems, binary costs can be expected to be higher. Figure 33 provides estimates for cost variance due to resource temperature. As the figure shows, binary systems range in cost from $2,000/kWh to slightly more than $4,000/kWh, while flash steam systems range from $1,000/kWh to just above $3,000/kWh (Hance, 2005).

Technology Development Considerations

In addition to the cost factors listed in the previous section of the report addressing geothermal binary plants, for some flash plants a corrosive geothermal fluid may require the use of resistive pipes and cement. Adding a titanium liner to protect the casing may significantly increase the cost of the well. This kind of requirement is rare in the United States, found only in the Salton Sea resource in Southern California (Hance, 2005).

Bradley, Robert L., Jr. Geothermal: The Nonrenewable Renewable. National Center for Policy Analysis.

CEC. 2014. Estimated cost of new renewable and fossil generation in California. California Energy Commission.

Hance, C. August 2005. Factors Affecting Costs of Geothermal Power Development, Geothermal Energy Association.

Heinberg, Richard. September 2009. Searching for a Miracle. “Net Energy” Limits & the Fate of Industrial Society. Post Carbon Institute.

Kagel, A. October 2006. A Handbook on the Externalities, Employment, and Economics of Geothermal Energy. Geothermal Energy Association.

Minetto, Riccardo, et al. 2020. Tectonic and Anthropogenic Microseismic Activity While Drilling Toward Supercritical Conditions in the Larderello-Travale Geothermal Field, Italy. Journal of Geophysical Research: Solid Earth

Murphy, Tom. 10 Jan 2012. Warm and Fuzzy on Geothermal? Do the Math.

NAS 2009. America’s Energy Future: Technology and Transformation. 2009. National Academy of Sciences, National Research Council, National Academy of Engineering.

NREL. January 2016. Doubling Geothermal Generation Capacity by 2020: A Strategic Analysis.  National Renewable Energy Laboratory.  Technical Report NREL/TP-6A20-64925

Oberhaus, D. 2020. Want Unlimited Clean Energy? Just Drill the World’s Hottest Well.

USGAO. January 2014. CLIMATE CHANGE Energy Infrastructure Risks and Adaptation Efforts GAO-14-74. United States Government Accountability Office.

Posted in Alternative Energy, Energy, Geothermal | Tagged | Comments Off on Can Geothermal power make up for declining fossil fuels?

Global oil discovered 7.7 times less than consumption in 2019

This image has an empty alt attribute; its file name is global-oil-discoveries-2019-rystad-energy.jpg

Source: Rystad Energy (2020) in “Global oil and gas discoveries reach four-year high in 2019, boosted by ExxonMobil’s Guyana success“.

Preface.  The global conventional discovery chart above lists natural gas and oil discoveries since 2013.  The fossil fuel that really matters is oil, since it’s the master resource that makes all others available, including natural gas, coal, transportation, and manufacturing.

This image has an empty alt attribute; its file name is oil-discovery-Rystad-Oil-consumed-BP.jpg

Source: discoveries Rystad (2020), consumption BP statistical review of world energy (2020

As you can see, in 2019 the world burned 7.7 times more oil than was discovered, with a shortfall of 31.74 billion barrels of oil to be discovered to break even in the future.  This can’t end well, as anyone whose covid-19 pantry is emptying can easily grasp. 

FYI from Peak Oil Review Feb 10, 2020: worldwide production of oil was 60.27% sourced from conventional on-shore oil, 21.59% conventional offshore shallow-water oil, 8.1%  conventional offshore deep water, 6.93% U.S. Tight Oil (Fracking), and 3.10% Canadian Oil Sands oil extraction 3.10%.

And an editorial in notes that: “US oil production has peaked, and it will be difficult to climb back to these levels ever again, given how much capital markets have soured on the industry. The EIA said that the US will once again become a net petroleum importer later this year, ending a brief spell during which the US was a net exporter”.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Mikael, H. August 29, 2016. Oil Discoveries at 70-Year Low Signal Supply Shortfall Ahead. Bloomberg.

2016 figure only shows exploration results to August. Discoveries were just 230 million barrels in 1947 but skyrocketed the next year when Ghawar was discovered in Saudi Arabia, and is till the world's largest oil field.  Source: Wood Mackenzie

2016 figure only shows exploration results to August. Discoveries were just 230 million barrels in 1947 but skyrocketed the next year when Ghawar was discovered in Saudi Arabia, and it is still the world's largest oil field, though recently it was learned that Ghawar is in decline at 3.5% a year. Source: Wood Mackenzie

Explorers in 2015 discovered only about a tenth as much oil as they have annually on average since 1960. This year, they’ll probably find even less, spurring new fears about their ability to meet future demand.

With oil prices down by more than half since the price collapse two years ago, drillers have cut their exploration budgets to the bone. The result: Just 2.7 billion barrels of new supply was discovered in 2015, the smallest amount since 1947, according to figures from Edinburgh-based consulting firm Wood Mackenzie Ltd. This year, drillers found just 736 million barrels of conventional crude as of the end of last month.

That’s a concern for the industry at a time when the U.S. Energy Information Administration estimates that global oil demand will grow from 94.8 million barrels a day this year to 105.3 million barrels in 2026. While the U.S. shale boom could potentially make up the difference, prices locked in below $50 a barrel have undercut any substantial growth there. Ten years down from now this will have a “significant potential to push oil prices up. Given current levels of investment across the industry and decline rates at existing fields, a “significant” supply gap may open up by 2040″.

Oil companies will need to invest about $1 trillion a year to continue to meet demand, said Ben Van Beurden, the CEO of Royal Dutch Shell Plc, during a panel discussion at the Norway meeting. He sees demand rising by 1 million to 1.5 million barrels a day, with about 5 percent of supply lost to natural declines every year.

New discoveries from conventional drilling, meanwhile, are “at rock bottom,” said Nils-Henrik Bjurstroem, a senior project manager at Oslo-based consultants Rystad Energy AS. “There will definitely be a strong impact on oil and gas supply, and especially oil.

Global inventories have been buoyed by full-throttle output from Russia and OPEC, which have flooded the world with oil despite depressed prices as they defend market share. But years of under-investment will be felt as soon as 2025, Bjurstroem said. Producers will replace little more than one in 20 of the barrels consumed this year, he said.

There were 209 wells drilled through August this year, down from 680 in 2015 and 1,167 in 2014, according to Wood Mackenzie. That compares with an annual average of 1,500 in data going back to 1960.

Overall, the proportion of new oil that the industry has added to offset the amount it pumps has dropped from 30 percent in 2013 to a reserve-replacement ratio of just 6 percent this year in terms of conventional resources, which excludes shale oil and gas, Bjurstroem predicted. Exxon Mobil Corp. said in February that it failed to replace at least 100 percent of its production by adding resources with new finds or acquisitions for the first time in 22 years.

“That’s a scary thing because, seriously, there is no exploration going on today,” Per Wullf, CEO of offshore drilling company Seadrill Ltd., said by phone.

Posted in How Much Left, Peak Oil | Tagged , | 4 Comments

Ugo Bardi: Collapse. Where can we find a safe refuge?

Preface. This is from the excellent blog of Ugo Bardi’s posted here. I agree that a small town or city might be best, but only if near agriculture, most towns in the desert SouthWest of the U.S. are not going to survive. Also, the younger you are, the better to be as far from large cities as possible, at some point they will collapse too since they’re so far over carrying capacity.

Roman times were different in that there was a whole lot more land to retreat to, most people had not only farming skills, but one or more of hunter-gatherer knowledge, fishing skills, and were able to herd cattle, goats, and sheep, as the book “Against the Grain” argues (and also that these pre-fossil civilizations depended on slave labor to a huge extent).

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Does it make sense to have a well-stocked bunker in the mountains to escape collapse?

Sometimes, you feel that the world looks like a horror story, something like Lovecraft’s “The Shadow Over Innsmouth..” Image from F.R: Jameson.

Being the collapsnik I am, a few years ago I had the idea that I could buy myself some kind of safe haven in the mountains, a place where I and my family could find refuge if (and when) the dreaded collapse were to strike our civilization (as they say, when the Nutella hits the fan). It is a typical idea of collapse-oriented people: run away from cities, imagined being the most vulnerable places in a Mad Max-style scenario.

Maybe I was thinking also of Boccaccio’s Decameron, when he describes how in the mid-14th century a group of wealthy Florentines finds refuge from the plague in a villa, outside Florence. And they had a leisured time telling stories to each other. I don’t oven a villa in the countryside, but I took a tour of villages in the Appennini mountains, a few hundred km from Florence, to seek for a hamlet of some kind to buy. I was accompanied by a friend of mine who is a denizen of the area and whom I had infected with the collapse meme.

We found several houses and apartments for sale in the area. One struck me as suitable, and the price was also interesting. It was a two-floor apartment with the windows opening on the central square of the village where it was located, among wooden hills. It had a wood stove, the kind of heating system you can always manage in an emergency. And it was at a sufficient height you could be reasonably safe from heat waves, even without air conditioning.

Then, I was looking at the village from one of the windows when a strange sensation hit me. People were walking in the square, and a few of them raised their glance to look at me. And, for a moment, I was scared.

Did you ever read Lovecraft’s short story “The Shadow over Innsmouth“? It tells the story of someone who finds himself stuck in a coastal town named Innsmouth that he discovers being inhabited by fish-like humanoids, the “deep Ones,” practicing the cult of a marine deity called Dagon.

Don’t misunderstand me: the people I was seeing in the square were not alien cultists of some monstrous divinity. What had scared me was a different kind of thought. It was that I knew that every adult male in that area owns a rifle or a shotgun loaded with slug ammunition. And every adult male in good health engages in wild boar hunting every weekend. They can kill a boar at 50 meters or more, then they are perfectly able to gut it and turn it into ham and sausages.

Now, if things were to turn truly bad, would some of those people consider me as the equivalent of a wild boar? For sure, I couldn’t even dream to be able to match the kind of firepower they have. I thanked the owner of the place and my friend, and I drove back home. I never went back to that place.

A few years later, with a real collapse striking us in the form of the COVID-19 epidemics,  I can see that I did well in not buying that apartment in the mountains. At the time of Boccaccio, wealthy Florentine citizens could reasonably think of moving to a villa in the countryside. These villas were nearly self-sufficient agricultural units, where one could find food and shelter provided by local peasants and servants (at that time not armed with long-range rifles). But that, of course, is not the case anymore.

The current crisis is showing us what a real collapse looks like. And it shows that some science fiction scenarios were totally wrong. The typical trope of a post-holocaust story is that people run away from flaming cities after having stormed the shops and the supermarkets, leaving empty shelves for those who arrive late. That didn’t happen here. At most, people seemed to think that what they needed most in an emergency was toilet paper and they emptied the supermarket shelves of it. But that was quickly over. Maybe we’ll arrive at that kind of scenario, but what is happening now is not that the supermarkets are running out of goods, everything is available if you have the money to buy it. The problem is that people are running out of money.

In this situation, the last thing the government wants is food riots. And they especially care about cities — if they lose control of the cities, everything is lost for them. So they are acting on two levels: they are providing food certificates for the poor, and, at the same time, clamping down on cities with the police and the army to enforce the lockdown. People are facing criminal charges if they dare to take a walk on the street.

Not an easy situation, but at least we have food and the cities are quiet. Think of what would have happened if I had bought that apartment in the mountains. I wouldn’t even have been able to go there during the coronavirus epidemics. But, if somehow I had managed to dodge the police, then I would be stuck there. And no supermarkets nearby: there is a small shop selling food in the village, but would it be resupplied during the crisis? The locals have ways to survive also with local food, but a town dweller like me doesn’t. And I never tried to shoot a wild boar, I think it is not easy — to say nothing about gutting it and turning it into sausage. Worse, I am sure that no police would patrol that small village, surely not the woods. So, maybe the local denizens would not shoot me and boil me in a cauldron, but if I were to run out of toilet paper, where could I find some? And, worse, what if I were to run out of food?

So, where can we find refuge from collapse? I can think of scenarios where you could be better off in a bunker somewhere in an isolated area, where you stocked a lot of supplies. But in most cases, that would be a terribly bad idea. A well-stocked bunker is the ideal target for whoever is better armed than you, and they can always smoke you out. Of course, you can think of a refuge for an entire group of people, with some of them able to shoot intruders, others to cultivate the fields, others to care for you if you get sick. Maybe, but it is a complicated story. You could join the Amish, but would they want you? It has been done often on the basis of religious ideas and in some cases, it may have worked, at least for a while. And never forget the case of Reverend Jim Jones in Guyana.

In the end, I think the best place to be in a time of crisis is exactly where I am: in a medium-sized city. It is the last place that the government will try to keep under control as long as possible, and not a likely target for someone armed with nukes or other nasty things. Why do I say that? Look at the map, here.

This is a map of the Roman Empire at its peak. Note the position of the major cities: the Empire collapsed and disappeared, but most of the cities of that time are still there, more or less with the same name, the new buildings built in place of the old ones, or near them. Those cities were built in specific places for specific reasons, availability of water, resources, or transportation. And so it made sense for the cities to be exactly where they were, and where they still are. Cities turned out to be extremely resilient. And how about Roman villas in the countryside? Well, many are being excavated today, but after the fall of the Empire, they were abandoned and never rebuilt. It must have been terribly difficult to defend a small settlement against all the horrible things that were happening at the time of the fall of the Empire.

So, overall, I think I did well in moving from a home in the suburbs to one downtown. Bad times may come, but I would say that it offers the best chances of survival, even in reasonably horrible times. Then, of course, the best plan of mice and men tend to gang agley, as we all know.  In any case, collapses are bad and that’s doesn’t change for collapsniks.

Posted in Ugo Bardi, Where to Be or Not to Be | Tagged , | 3 Comments

The U.S. May Soon Have the World’s Oldest Nuclear Power Plants

Preface. This is nuts. Sea level rise threatens many nuclear power plants and drought has shut plants down since they need cooling to operate.

As nuclear reactor age, they require more intensive monitoring and preventive maintenance to operate safely. But reactor owners have not always taken this obligation seriously enough. Given that older reactors require more attention from the regulator, not less, it is perplexing that the NRC wants to scale back its inspections of the aging reactor fleet and its responses to safety violations. Six years ago, the US Government Accountability Office pointed out that “NRC’s oversight will soon likely take on even greater importance as many commercial reactors … are reaching or have reached the end of their initial 40-year operating period.” (Lyman 2019).

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick JensenPractical PreppingKunstlerCast 253KunstlerCast278Peak Prosperity , XX2 report


Natter, A. 2020. The U.S. May Soon Have the World’s Oldest Nuclear Power Plants. Bloomberg.

In December federal regulators approved Florida Power & Light Co.’s request to let the facility’s twin nuclear reactors remain in operation for another 20 years beyond the end of their current licenses. By that point they’ll be 80, making them the oldest reactors in operation anywhere in the world.

“That’s too old,” said Rippingille, a lawyer and retired Miami-Dade County judge who was wearing a blue print shirt with white sea turtles on it. “They weren’t designed for this purpose

With backing from the Trump administration, utilities across the nation are preparing to follow suit, seeking permission to extend the life of reactors built in the 1970s to the 2050s as they run up against the end of their 60-year licenses.

“We are talking about running machines that were designed in the 1960s, constructed in the 1970s and have been operating under the most extreme radioactive and thermal conditions imaginable,” said Damon Moglen, an official with the environmental group Friends of the Earth. “There is no other country in the world that is thinking about operating reactors in the 60 to 80-year time frame.”

Indeed, the move comes as other nations shift away from atomic power over safety concerns
Critics such as Edwin Lyman, a nuclear energy expert with the Union of Concerned Scientists, argue that older plants contain “structures that can’t be replaced or repaired,” including the garage-sized steel reactor vessels that contain tons of nuclear fuel and can grow brittle after years of being bombarded by radioactive neutrons. “They just get older and older,” he said. If the vessel gets brittle, it becomes vulnerable to cracking or even catastrophic failure. That risk increases if it’s cooled down too rapidly—say in the case of a disaster, when cold water must be injected into the core to prevent a meltdown.

The commission’s decision doesn’t sit well with Philip Stoddard, a bespectacled biology professor who serves as the mayor of South Miami, a city of 13,000 on about 18 miles away from the Turkey Point plant. He keeps a store of potassium iodide, used to prevent thyroid cancer, large enough to provide for every child in his city should the need arise.

“You’ve got hurricanes, you’ve got storm surge, you’ve got increasing risks of hurricanes and storm surge,” said Stoddard, 62, from the corner office in a biology building on Florida International University’s palm-tree lined campus. All of this not only increases the likelihood of a nuclear disaster, it also complicates a potential evacuation, which could put even more lives at risk. “Imagine being in a radiation cloud in your car and you’re sitting there running out of gas because you’re in a parking lot in the freeway,” he said.

Climate change is also one of the main cases against extending the life of Turkey Point, said Kelly Cox, the general counsel for Miami Waterkeeper, a six-person environmental group that has joined with the Natural Resources Defense Council and Friends of the Earth to challenge the NRC’s approval in the United States Court of Appeals for the District of Columbia Circuit. New data show sea level rise in the area reach as high as 4.5 feet by 2070, but regulators from the Nuclear Regulatory Commission didn’t take those updated figures into account, said Cox.


Lyman, E. 2019. Aging nuclear plants, industry cost-cutting, and reduced safety oversight: a dangerous mix. Bulletin of the Atomic Scientists.

Posted in Nuclear Power | Tagged , , | 1 Comment

High-level nuclear waste storage degrades faster than thought

Preface. Burying nuclear waste ought to be a top priority, now that it appears peak oil may have happened in November of 2018 (Patterson 2019) and perhaps even sooner if covid-19 crashes the world economy (Tverberg 2020). It won’t happen after oil production peaks, when it is rationed to agriculture and other essential services. Our descendants shouldn’t have to cope with nuclear waste on top of all the other destruction we’re causing in the world.

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


OSU. 2020. High-level nuclear waste storage materials will likely degrade faster than previously thought. Ohio State University.

Study finds the materials — glass, ceramics and stainless steel — interact to accelerate corrosion.

The materials the United States and other countries plan to use to store high-level nuclear waste will likely degrade faster than anyone previously knew because of the way those materials interact, new research shows.

The findings, published today in the journal Nature Materials, show that corrosion of nuclear waste storage materials accelerates because of changes in the chemistry of the nuclear waste solution, and because of the way the materials interact with one another.

“This indicates that the current models may not be sufficient to keep this waste safely stored,” said Xiaolei Guo, lead author of the study and deputy director of Ohio State’s Center for Performance and Design of Nuclear Waste Forms and Containers, part of the university’s College of Engineering. “And it shows that we need to develop a new model for storing nuclear waste.”

The team’s research focused on storage materials for high-level nuclear waste — primarily defense waste, the legacy of past nuclear arms production. The waste is highly radioactive. While some types of the waste have half-lives of about 30 years, others — for example, plutonium — have a half-life that can be tens of thousands of years. The half-life of a radioactive element is the time needed for half of the material to decay.

The United States currently has no disposal site for that waste; according to the U.S. General Accountability Office, it is typically stored near the plants where it is produced. A permanent site has been proposed for Yucca Mountain in Nevada, though plans have stalled. Countries around the world have debated the best way to deal with nuclear waste; only one, Finland, has started construction on a long-term repository for high-level nuclear waste.

But the long-term plan for high-level defense waste disposal and storage around the globe is largely the same. It involves mixing the nuclear waste with other materials to form glass or ceramics, and then encasing those pieces of glass or ceramics — now radioactive — inside metallic canisters. The canisters then would be buried deep underground in a repository to isolate it.

In this study, the researchers found that when exposed to an aqueous environment, glass and ceramics interact with stainless steel to accelerate corrosion, especially of the glass and ceramic materials holding nuclear waste.

The study qualitatively measured the difference between accelerated corrosion and natural corrosion of the storage materials. Guo called it “severe.”

“In the real-life scenario, the glass or ceramic waste forms would be in close contact with stainless steel canisters. Under specific conditions, the corrosion of stainless steel will go crazy,” he said. “It creates a super-aggressive environment that can corrode surrounding materials.”

To analyze corrosion, the research team pressed glass or ceramic “waste forms” — the shapes into which nuclear waste is encapsulated — against stainless steel and immersed them in solutions for up to 30 days, under conditions that simulate those under Yucca Mountain, the proposed nuclear waste repository.

Those experiments showed that when glass and stainless steel were pressed against one another, stainless steel corrosion was “severe” and “localized,” according to the study. The researchers also noted cracks and enhanced corrosion on the parts of the glass that had been in contact with stainless steel.

Part of the problem lies in the Periodic Table. Stainless steel is made primarily of iron mixed with other elements, including nickel and chromium. Iron has a chemical affinity for silicon, which is a key element of glass.

The experiments also showed that when ceramics — another potential holder for nuclear waste — were pressed against stainless steel under conditions that mimicked those beneath Yucca Mountain, both the ceramics and stainless steel corroded in a “severe localized” way.

Reference: “Self-accelerated corrosion of nuclear waste forms at material interfaces” by Xiaolei Guo, et al., 27 January 2020, Nature Materials.
DOI: 10.1038/s41563-019-0579-x


Patterson, R. 2019. Was 2018 the peak for crude oil production?

Tverberg, G. 2020. Economies won’t be able to recover after shutdowns.

Posted in Nuclear Waste | Tagged | 10 Comments

Concentrated Solar Power is dying out in the U.S.

Preface.  Concentrated Solar Power (CSP) contributes only 0.06 % of U.S. electricity, mainly in California (64 %) and Arizona (24 %) because extremely dry areas with no humidity, haze, or pollutants are required. Of the 1861 MW power they can generate, only 25% of these plants can also store electricity using thermal energy storage. This is their only advantage over solar panels, the ability to continue to generate electricity after the sun goes down, since CSP costs astronomically more than solar PV.

Energy is stored as heat, usually in molten salt, with total CSP storage rated at 510 MW.

CSP is more capital expensive than any other power generation plant except nuclear. Eight plants cost a total of $9 billion (Solana, Genesis, Mojave, Ivanpah, Rice, Martin, Nevada solar 1, Crescent Dunes (NREL 2013).

Almost all CSP plants also have fossil backup to diminish night thermal losses, prevent molten salt from freezing, supplement low solar irradiance in the winter, and for fast starts in the morning.

CSP electricity generation in winter is significantly less than other seasons, even in the best range of latitudes between 15° and 35°.

To provide seasonal storage, CSP plants would need to use stone, which is much cheaper than molten salt. A 100 MW facility would need 5.1 million tons of rock taking up 2 million cubic meters (Welle 2010).

Since stone is a poor heat conductor, the thick insulating walls required might make this unaffordable (IEA 2011b).

Nevada’s 110 MW Crescent Dunes opened in 2015 with 10 hours of storage and is expected to provide an average of 0.001329 Twh a day. Multiply that by 8265 more Crescent Dune scale plants and presto, we’ll have one day of U.S. electrical storage (11.12/0.001329 TWh).

Or maybe not, the $1 billion dollar Crescent Dunes has gone out of business (Martin 2020).

CSP with thermal energy storage is seasonal, so it can not balance variable power or contribute much power for half the year.

Without storage, solar CSP and solar PV do nothing to keep the grid stable or meet the peak morning and late afternoon demand.

And it appears to be dying out, with just one CSP developer left (Deign 2020).

Alice Friedemann  author of “When Trucks Stop Running: Energy and the Future of Transportation”, 2015, Springer, Barriers to Making Algal Biofuels, and “Crunch! Whole Grain Artisan Chips and Crackers”. Podcasts: Collapse Chronicles, Derrick Jensen, Practical Prepping, KunstlerCast 253, KunstlerCast278, Peak Prosperity , XX2 report


Concentrated Solar Power not only needs lots of sunshine, but no humidity, clouds, dust, smog or or anything else that can scatter the sun’s rays.  Above 35 degrees latitude north or south, the sun’s rays have to pass through too much atmosphere to produce high levels of power, and these regions tend to be too cloudy as well.  Between 15 degrees north and south of the equator is also not ideal, it’s too cloudy, rainy, and humid.  That leaves very dry and hot regions in the 15-35 degrees of latitude.  Only deserts are suitable, such as America’s Southwest, southern Africa, the Middle East, north-western India, northern Mexico, Peru, Chile, the western parts of China and Australia,  the extreme south of Europe and Turkey, some central Asian countries, and places in Brazil and Argentina.

The problem with arid, dry regions is that CSP needs water for condenser cooling. Dry-cooling of steam turbines can be done but it costs more and lowers efficiency.

CSP doesn’t wean us totally from fossil fuels, nearly all use fossil fuel as back-up, to remain dispatchable even when the solar resource is low, and to guarantee an alternative thermal source that can compensate night thermal losses, prevent freezing and assure a faster start-up in the early morning.

Even in ideal locations, CSP is highly seasonal:

CSP electric production seasonal low Jan high May

The average CSP capacity factor in the United States in December 2014 was 5.5%, while in August it was 25% (EIA. 2015. Table 6.7.B. Capacity Factors for Utility Scale Generators Not Primarily Using Fossil Fuels, January 2008-November 2014. U.S. Energy Information Administration).

This means that CSP requires seasonal storage, since it provides almost nothing in winter, yet CSP with thermal energy storage (TES) IS one of the few ways even a few hours of energy storage can be accomplished, since there’s very limited pumped hydro storage, compressed air energy storge, and battery storage.

“Averages” are irrelevant.  The seasonal nature of CSP with thermal storage makes balancing variable renewables and year-round power on a national grid — or even within the Southwest some days, weeks, or seasons — impossible without months of energy storage.   

Concentrating Solar Power Average Daily Solar Radiation Per Month, 1961]1990 (NREL 2011b)

Concentrating Solar Power Average Daily Solar Radiation Per Month, 1961-1990 (NREL 2011b)

There will be days or weeks when solar radiation is very low.  Below are some minimums and maximums for an East-West Axis Tracking Concentrator Daily solar radiation per month (NREL 2011b).

January mininum

January minimum

January maximum

January maximum

July minimum

July minimum

July maximum

July maximum

This means, for example, that in central Nevada may reach 10 kWh/m2/day or higher during July, but January average values may be as low as 3 kWh/m2/day, or even zero on a daily basis as a result of cloud cover (NREL 2011a).

The best CSP is in just a few unpopulated, drought-stricken states (AZ, CA, NM, NV)(NREL 2012):

CSP NREL solar resource 2012

The Seasonal Nature of sunshine (International Energy Agency. 2011. Solar Energy Perspectives)

Seasonal storage for CSP plants would require stone storage. The volume of stone storage for a 100 MW system would be no less than 2 million m3, which is the size of a moderate gravel quarry, or a silo of 250 meter diameter and 67 meter high. This may not be out of proportion, in regions where available space is abundant, as suggested by the comparison with the solar collector field required for a CSP plant producing 100 MW on annual average.

Stones are poor heat conductors, so exchange surfaces should be maximized, for example, with packed beds loosely filled with small particles. One option is then to use gases as HTFs from and to the collector fields, and from and to heat exchangers where steam would be generated. Another option would be to use gas for heat exchanges with the collectors, and have water circulating in pipes in the storage facility, where steam would be generated. This second option would simplify the general plan of the plant, but heat transfers between rocks and pressurized fluids in thick pipes may be problematic.

Annual storage may emerge as a useful option, as generation of electricity by CSP plant in winter is significantly less than in other seasons in the range of latitudes – between 15° and 35° – where suitable areas for CSP generation are found. However, skeptics point out the need for much thicker insulation walls as a critical cost factor.

Square miles needed to produce 25,000 TWh/year with CSP

CSP is more efficient than PV per surface of collectors, but less efficient per land surface, so its 25,000 TWh of yearly production would require a mirror surface of 38,610 square miles (100,000 sq km) and a land surface of about 115,831 square miles (300,000 km2).

Best locations for CSP

Tropical zones thus receive more radiation per surface area on yearly average than the places that are north of the Tropic of Cancer or south of the Tropic of Capricorn. Independent of atmospheric absorption, the amount of available irradiance thus declines, especially in winter, as latitudes increase. The average extraterrestrial irradiance on a horizontal plane depends on the latitude (Figure 2.4).

IEA 2011 figure 2.4 average yearly irradiance by latitude

Irradiance varies over the year at diverse latitudes – very much at high latitudes, especially beyond the polar circles, and very little in the tropics (Figure 2.5).  Seasonal variations are greater at higher latitudes:

IEA 2011 figure 2.5 total daily irradiance on a plane horizontal to earth surface

IEA 2011 figure 2.8 yearly profile mean daily solar radiation

Figure 2.8 The yearly profile of mean daily solar radiation for different locations around the world. The dark area represents direct horizontal irradiance, the light area diffuse horizontal irradiance. Their sum, global horizontal irradiance (GHI) is the black line. The blue line represents direct normal irradiance (DNI). Key point: Temperate and humid equatorial regions have more diffuse than direct solar radiation.

So for solar CSP, the blue line is important and needs to be above 6 for a project to be commercially viable.  The South Pacific Islands have too much moisture (blue line), and northern europe likewise plus not enough irradiance.  Concentrating technologies can be deployed only where DNI largely dominates the solar radiation mix, i.e. in sunny countries where the skies are clear most of the time, over hot and arid or semi-arid regions of the globe. These are the ideal places for concentrating solar power (CSP), concentrating photovoltaics (CPV).  PV can work fine in humid regions, but not CSP or CPV.

Formulations such as “a daily average of 5.5 hours of sunshine over the year” are casually used, however, to mean an average irradiance of 5.5 kWh/m2/d (2 000 kWh/m2/y), i.e. the energy that would have been received had the sun shone on average for 5.5 hours per day with an irradiance of 1,000 W/m2. In this case, one should preferably use “peak sunshine” or “peak sun hours” to avoid any confusion with the concept of sunshine duration.

Ground data measurements for 1-2 years before building a CSP plant

Ground measurements are critically necessary for a reliable assessment of the solar energy possibilities of sites, especially if the technology is CSP or CPV. Satellite data can be used to complement short ground measurement periods of one or two years with a longer term perspective. Ten years is the minimum necessary to have a real perspective on annual variability, and to get a sense of the actual average potential and the possible natural deviations from year to year. Satellite data should be used only when they have been bench-marked by ground measurements.

All parabolic trough plants currently in commercial operation rely on a synthetic oil as heattransfer fluid (HTF) from collector pipes to heat exchangers, where water is preheated, evaporated and then superheated. The superheated steam runs a turbine, which drives a generator to produce electricity. After being cooled and condensed, the water returns to the heat exchangers. Parabolic troughs are the most mature of the CSP technologies and form the bulk of current commercial plants. Investments and operating costs have been dramatically reduced, and performance improved, since the first plants were built in the 1980s. For example, special trucks have been developed to facilitate the regular cleaning of the mirrors, which is necessary to keep performance high, using car-wash technology to save water.

Most first-generation plants have little or no thermal storage and rely on combustible fuel as a firm capacity back-up. CSP plants in Spain derive 12% to 15% of their annual electricity generation from burning natural gas. More than 60% of the Spanish plants already built or under construction, however, have significant thermal storage capacities, based on two-tank molten-salt systems, with a difference of temperatures between the hot tank and the cold one of about 100°C.

Salt mixtures usually solidify below 238°C and are kept above 290°C for better viscosity, however, so work is needed to reduce the pumping and heating expenses required to protect the field against solidifying [my comment: so fossil energy to keep the salts hot subtracts from efficiency]

Energy storage

Worldwide energy storage: The volume of electricity storage necessary to make the electricity available when needed would likely be somewhere between 25 TWh and 150 TWh – i.e. from 10 to 60 hours of storage. If 20 TWh are transferred from one hour to another every day, then the yearly amount of variable renewable electricity shifted daily would be roughly 7,300 TWh. Allowing for 20% losses, one may consider 9,125 TWh in and 7,300 TWh out per year.

Studies examining storage requirements of full renewable electricity generation in the future have arrived at estimates of hundreds of GW for Europe (Heide, 2010), and more than 1,000 GW for the United States (Fthenakis et al., 2009). Scaling-up such numbers to the world as a whole (except for the areas where STE/CSP suffices to provide dispatchable generation) would probably suggest the need for close to 5,000 GW to 6,000 GW storage capacities. Allowing for 3,000 GW gas plants of small capacity factor (i.e. operating only 1 000 hours per year) explains the large difference from the 2,500 GW of storage capacity needs estimated above. However, one must consider the role that large-scale electric transportation could possibly play in dampening variability before considering options for large-scale electricity storage.

V2G possibilities certainly need to be further explored. They do entail costs, however, as battery lifetimes depend on the number, speeds and depths of charges and discharges, although to different extents with different battery technologies. Car owners or battery-leasing companies will not offer V2G free to grid operators, not least because it reduces the lifetime of batteries. Electric batteries are about one order of magnitude more expensive than other options available for large-scale storage, such as pumped-hydro power and compressed air electricity storage.

IEA 2014. Technology Roadmap. Solar Thermal Electricity. International Energy Agency

Global horizontal irradiance (GHI) is a measure of the density of the available solar resource per unit area on a plane horizontal to the earth’s surface. Global normal irradiance (GNI) and direct normal irradiance (DNI) are measured on surfaces “normal” (i.e., perpendicular) to the direct sunbeam. GNI is relevant for two-axis, sun-tracking, “1-sun” (i.e., non-concentrating) PV devices.

DNI is the only relevant metric for devices that use lenses or mirrors to concentrate the sun’s rays on smaller receiving surfaces, whether concentrating photovoltaics (CPV) or CSP generating STE. All places on earth receive 4,380 daylight hours per year — i.e., half the total duration of a year – but different areas receive different yearly average amounts of energy from the sun.

When the sun is lower in the sky, its energy is spread over a larger area and energy is also lost when passing through the atmosphere, because of increased air mass; the solar energy received is therefore lower per unit horizontal surface area.

Inter-tropical areas should thus receive more radiation per land area on a yearly average than places north of the Tropic of Cancer or south of the Tropic of Capricorn.

However, atmospheric absorption characteristics affect the amount of this surface radiation significantly. In humid equatorial places, the atmosphere scatters the sun’s rays. DNI is much more affected by clouds and aerosols than global irradiance. The quality of DNI is more important for CSP plants than for concentrated photovoltaics (CPV), because the thermal losses of a CSP plant’s receiver and the parasitic consumption of the electric auxiliaries are essentially constant, regardless of the incoming solar flux. Below a certain level of daily DNI, the net output is null (Figure 2 above).

High DNI is found in hot and dry regions with reliably clear skies and low aerosol optical depths, which are typically in subtropical latitudes from 15° to 40° north or south. Closer to the equator, the atmosphere is usually too cloudy, especially during the rainy season. At higher latitudes, weather patterns also produce frequent cloudy conditions, and the sun’s rays must pass through more atmosphere mass to reach the power plant. DNI is also significantly higher at higher elevations, where absorption and scattering of sunlight due to aerosols can be much lower. Thus, the most favorable areas for CSP resource are in North Africa, southern Africa, the Middle East, north- western India, the south-western United States, northern Mexico, Peru, Chile, the western parts of China and Australia. Other areas that are suitable include the extreme south of Europe and Turkey, other southern US locations, central Asian countries, places in Brazil and Argentina, and some other parts of China.

Areas with sufficient direct irradiance for CSP development are usually arid and many lack water for condenser cooling (Box 1). Dry-cooling technologies for steam turbines are commercially available, so water scarcity is not an insurmountable barrier, but it leads to an efficiency penalty and an additional cost. Wet-dry hybrid cooling can significantly improve performance, with water consumption limited to heat waves.

Almost all existing CSP plants use some fossil fuel as back-up, to remain dispatchable even when the solar resource is low and to guarantee an alternative thermal source that can compensate night thermal losses, prevent freezing and assure a faster start-up in the early morning.

Investment costs for CSP plants have remained high, from USD 4 000/kW to 9 000/kW, depending on the solar resource and the capacity factor, which also depends on the size of the storage system and the size of the solar field, as reflected by the solar multiple.

Costs were expected to decrease as CSP deployment progressed, following a learning rate of 10% (i.e., 10% cost reduction for each cumulative capacity doubling). This decrease has taken a long time to materialize, however, because market opportunities for CSP plants have diminished and the cost of materials has increased, particularly in the most mature parts of the plants, the power block and balance of plant (BOP). Other causes are the dominance of a single technology (trough plants with oil as heat transfer fluid

The few larger plants that have been or are being built elsewhere are either the first of their find in the world, with large development costs and technology risks (e.g., in the United States),

Levelized cost of electricity (LCOE)3 of STE varies widely with the location, technology, design and intended use of plants. The location determines the quantity and quality of the solar resource (Box 1), atmospheric attenuation at ground level, variations in temperature that affect efficiency (e.g., cold at night increases self-consumption, warmth during daylight reduces heat losses but also thermodynamic cycle efficiency) and the availability of cooling water. A plant designed for peak or mid-peak generation with a large turbine for a relatively small solar field will generate electricity at a higher cost than a plant designed for base load generation with a large solar field for a relatively small turbine. LCOE, while providing useful information, does not represent the entire economic balance of a CSP plant, which depends on the value of the generated STE.

Recent CSP plant in the United States secured PPA at USD 135/MWh, but taking investment tax credit into account, the actual remuneration is about USD 190/MWh.  The US DoE’s Sunshot program expects more rapid cost reductions based on current trends, and even aims for LCOE of USD 60/MWh as soon as 2020 [dream on…]

Barriers encountered, overcome or outstanding

Developers have encountered several barriers to establishing CSP plants. These include insufficiently accurate DNI data; inaccurate environmental data; policy uncertainty; difficulties in securing land, water and connections; permitting issues; and expensive financing, leading to difficult financial closure Inaccurate DNI data can lead to significant design errors. Ground-level atmospheric turbidity, dirt, sand storms and other weather characteristics or events may seriously interfere with CSP technologies. Permits for plants have been challenged in courts because of concerns about their effects on wildlife, biodiversity and water use. Some countries prohibit the large-scale use as HTF of synthetic oil or some molten salts, or both.

The most significant barrier is the large up-front investment required. The most mature technology, PT with oil as HTF, with over 200 cumulative years of running, may have limited room for further cost reductions, as the maximum temperature of the HTF limits the possible increase in efficiency and imposes high costs to thermal storage systems. Other technologies offer greater prospects for cost reductions but are less mature and therefore more difficult to obtain finance for. In countries with no or little experience of the technology, financing circles fear risks specific to each country.

In the United States, the loan guarantee program of the DoE has played a key role in overcoming financing difficulties and facilitating technology innovation.

Medium-term outlook

There are no new CSP projects in Spain, as incentives have been cut.

Plants in the approval process or ready to start construction represent 20 MW in France and 115 MW in Italy, while other projects are under development. The Italian environment legislation does not allow for extensive use of oil in trough plants, limiting the technology options to more innovative designs, such as DSG or molten salts as HTF. Projects that would produce several gigawatts are still under consideration or development in the United States, although not all will succeed in obtaining the required permits, PPAs, connections, and financing.

Current average LCOE is high because most existing plants have been built in Spain, which has relatively weak DNI. [my comment: if there is money for energy projects it’s spent regardless of how expensive and foolish – look at all the fracked natural gas by companies deeply in debt, the massive building of solar PV and CSP in Spain, ethanol subsidies, and all kinds of wasteful projects (and research) across the board.  I think this is why there’s no funding for EROI research — nobody wants to know!  Plus foolish projects provide jobs, it’s more important for democrats to provide “green” jobs than whether or not it’s a good idea. And why not, as long as there is oil we can build cities like Las Vegas in the desert that will be abandoned as soon as 2024 or whenever Lake Mead dries up, parking lots, cheap ugly housing projects, and so on]

As deployment intensifies in the southwestern United States and spreads to North Africa, South Africa, Chile, Australia and the Middle East, better resources will be used, improving performance.

Table 4: Projections of LCOE for new-built CSP plants with storage in the hi-Ren Scenario

The possible role of small-scale CSP devices – from 100 kW to a few MW – off-grid or serving in mini-grids, has not been included in the ETP model. There is too little industrial experience of such systems to make informed cost assumptions, whether the systems are based on PT, LFR, parabolic dishes, Scheffler dishes or small towers, using organic Rankin cycle turbines, micro gas-turbines or various reciprocating engines. If they allow thermal storage4 or fuel backup, small-scale CSP systems have to compete against PV with battery storage or fuel backup. They may find a role, although the fact that CSP technology seems to benefit more than PV from economies of scale suggests that smallscale CSP systems may face a greater competitive challenge than large-scale ones. Finding local skills for maintenance may also be challenging in remote, off-grid areas.

Storage is a particular challenge in CSP plants that use DSG. Because water evaporation is isothermal, unlike sensible heat addition or removal in the salt, a round-trip storage cycle would result in severe steam temperature and pressure drops, thereby destroying the efficiency of the thermodynamic cycle in discharge mode. Storing latent heat of saturated steam in pressurised vessels is expensive and provides no scale effect on cost. One option would use three-stage storage devices that preheat the water, evaporate the water and superheat the steam. Stages 1 and 3 would be sensible heat storage, in which the temperature of the storage medium changes. Stage 2 would best be latent heat storage, in which the state of the storage medium changes, using some phase change material. Another option could be to use liquid phase-change materials. The growing relevance of thermal storage in the context of intense competition from cheap PV favors using molten salts as both the heat transfer fluid and the storage medium (termed “direct storage”). If DSG spares heat exchangers for steam generation, the use of molten salts as HTF spares heat exchangers for storage. Salts are less costly than oil. Using salts allows raising the temperature and pressure of the steam, from 380°C to 530-550°C and from 10 to 12-15 megapascals (MPa) in comparison with oil as HTF, increasing the efficiency of the power block from 39% to 44-45% (Lenzen, 2014). Thanks to higher temperature differences between hot and cold salts (currently used salt mixtures usually solidify below 238°C), plants using molten salts as HTF need three times less salts than trough plants using oil as HTF, for the same storage capacity. This lowers the storage system costs, which represent about 12% of the overall plant cost for seven-hour storage of a trough plant. Also, the “return efficiency” of thermal storage, at about 93% with indirect storage (in which heat exchangers reduce the working temperature), is increased to 98% with direct storage. Finally, another advantage of molten salts as HTF over steam is that heat transfer can be carried out at low pressure with thin-wall solar receivers, which are cheaper and more effective. Overall, the substitution of molten salts for oil in CSP would allow for 30% LCOE reduction, according to Schott, the lead manufacturer of solar receiver tubes (Lenzen, 2014). Several companies are developing the use of molten salts as HTF in linear systems, and have built or are building experimental or demonstration devices. One challenge is to reduce the expense required to keep the salts warm enough (usually above 290°C) for better viscosity in long tubes at all times and protect the field against freezing.

Apart from the fundamental choice between DSG and molten salts for HTF, towers currently also offer a great diversity of designs – and present various trade-offs. The first relates to the size (and number) of heliostats that reflect the sunlight onto the receivers atop the tower. Heliostats vary greatly in size, from about 1 m2 to 160 m2. The small ones can be flat and offer little surface to winds. The larger ones need several mirrors that are curved to send a focused image of the sun to the central receiver, and need strong support structures and motors to resist winds. For similar collected energy ranges, however, small heliostats need to be grouped by the thousand, multiplying the number of motors and connections. Manufacturers and experts still have divided views about the optimum size. Heliostats need to be distanced from one another to reduce losses arising when a heliostat intercepts part of the flux received (“shading”) or reflected (“blocking”) by another. While linear systems require flat land areas, central receiver systems may accommodate some slope, or even benefit from it as it could reduce blocking and shadowing, and allow increasing heliostat density. Algorithmic field optimization may help reduce environmental impacts and required ground leveling work while maximizing output (Gilon, 2014).

In low latitudes heliostat fields tend to be circular and surround the central receiver, while in higher latitudes they tend to be more concentrated to the polar side of the tower. Larger fields tend to be more circular to limit the maximum receiver heliostat distance and minimise atmospheric attenuation.

Proper aiming strategy must be ensured by the heliostat field’s control system in order to optimise the solar flux map on the receiver, thereby allowing the highest solar input while avoiding any local overheating of the receiver tubes. This is more difficult with DSG receivers. The heat flux on the different types of solar panel of a DSG receiver differs significantly: superheater panels (poorly cooled by superheated steam) receive a much lower flux than evaporator and preheater panels. Another important design choice relates to the number of towers for one turbine. Heliostats that are in the last rows far from the tower need to be very precisely pointed towards it, and lose efficiency as the light must make a long trip near ground level. They also have greater geometrical (“cosine”) optical losses.

At over 1 million m2, the solar field associated with the 110 MW tower built by SolarReserve with 10-hour storage at Crescent Dunes, (Nevada, United States) is perhaps close to the maximum efficient size.

The additional costs of building several towers may be made up for by the greater optical and thermal efficiencies of multitower design (Wieghardt et al., 2014). However, the optimal field size and number of towers may depend on the atmospheric turbidity of the site considered, which varies greatly among areas suitable for CSP plants. The Californian company eSolar proposes 100 MW molten salt power plants based on 14 solar fields and 14 receivers on top of monopole towers (similar to current large wind turbine masts) for one central dry-cooled power block with 13-hour thermal storage and 75% capacity factor (Tyner, 2013).

As the share of variable energy increases, base load plants, even if technically flexible (which all are not) will become less economically efficient as their utilization rate diminishes. At the same time, more peaking and mid-merit plants become necessary. Below a certain load factor – about 2,000 full load hours – open-cycle gas turbines become a better economic choice than combined-cycle plants, but they are less energy-efficient as they generate large amounts of waste heat.

Open-cycle gas turbines could be integrated with a CSP plant with storage, however, of which the steam turbine is not being used with a very high capacity factor. When the sun does not shine, the otherwise wasted heat could be collected to a large extent in the hot tank of a two-tank molten-salt system. This energy could afterwards be directed to the steam turbine to deliver electricity whenever requested. If more power is needed when the sun shines sufficiently to run the steam turbine by itself, the heat from the gas turbine could be directed to the thermal storage. In both cases, a large part of the waste heat will be used. This concept differs from the existing ISCC in which solar only provides a complement, as the presence of thermal storage allows for a complete reversal of the proportion of solar and gas, which remains a backup, though a more efficient one (Crespo, 2014). The Hysol project, funded by the European Union’s Seventh Program for research, technological development and demonstration, aims to demonstrate the viability of the concept. Similarly, in areas with both high wind penetration and CSP plants, some thermal storage, which is equipped with electric heaters for security reasons, could be used in winter to reduce curtailment from excess wind power.

Molten salts decompose at higher temperatures, while corrosion limits the temperatures of steam turbines. Higher temperatures and efficiencies could rest on the use of fluoride liquid salts as HTFs up to temperatures of 700°C to 850°C,

There are a number of potential pathways to solar fuels. The straightforward thermolysis of water is the most difficult, as it requires temperatures above 2 200°C and may produce an explosive mixture of hydrogen and oxygen. The division of the single-step water-splitting reaction into a number of sub- reactions opens up the field of so called thermochemical cycles for H2 production. The necessary reaction temperature can be decreased even below 1 000°C, resulting in intermediate solid products like metals (e.g., aluminium, magnesium, or zinc), metal oxides, metal halides or sulphur oxides. The different reaction steps can be separated in time and place, offering possibilities for long-term storage of the solids and their use in transportation. These thermochemical cycles are also able to split CO2 into CO and oxygen. If mixtures of water and CO2 are used, even synthesis gas (mainly H2 and CO) can be produced, which can be further processed to synfuels, for example by the Fischer-Tropsch process.

Concentrated solar radiation can also be used to upgrade carbonaceous materials. The most developed process is the steam reforming of methane to produce synthesis gas. Sources are either natural gas or biogas. Methane can also be cracked into hydrogen and carbon, thus producing a gaseous and a solid product. However, the required process temperature is extremely high and a homogeneous carbon product is unlikely to be produced because of the intermittent solar radiation conditions. Additionally, there is a discrepancy between the huge demand for hydrogen and the low demand for high-value carbon, such as carbon black or advanced carbon nano-tubes.

Hydrogen produced in concentrating solar chemical plants could be blended with natural gas and thus used in today’s energy system. Town gas, which prevailed before natural gas spread out, included hydrogen up to 60% in volume or about 20% in energy content. This blend could be used for various purposes in industry, households and transportation, reducing emissions of CO2 and nitrous oxides. Gas turbines in integrated gasification combined cycle (IGCC) power plants can burn a mix of gases with 90% hydrogen in volume. Many existing pipelines could, with some adaptation, transport such a blend from sunny places to large consumption centres (e.g. from North Africa to Europe).

Solar-produced hydrogen could also find niche markets today in replacing hydrogen production from steam-reforming of natural gas in its current uses, such as manufacturing fertilizers and removing sulfur from petroleum products. Regenerating hydrogen with heat from concentrated sunlight to decompose hydrogen sulphide into hydrogen and sulfur could save significant amounts of still gas in refineries for other purposes. Coal could be used together with methane gas as feedstock, and deliver dimethyl ether (DME), after solar-assisted steam reforming of natural gas, coal gasification under oxygen, and two-step water splitting. DME could be used as a liquid fuel, and its combustion would entail similar CO2 emissions to those from burning conventional petroleum products, but significantly less than the life-cycle emissions of other coal-to-liquid fuels.

Besides solar fuels, CSP technology could find a great variety of uses in providing high temperature process heat or steam, such as for enhanced oil recovery, and mining applications (where CSP is already in use), smelting of aluminium and other metals, and in industries such as food and beverages, textiles and pharmaceuticals. Various forms of cogeneration with STE can also be considered. For example, sugar plants require high temperature steam in spring, when the solar resource is maximal but electricity demand minimal. Solar fields providing steam for sugar plants could run a turbine and generate STE for the rest of the year.

STE is not broadly competitive today, and will not become so until it benefits from strong and stable frameworks, and appropriate support to minimise investors’ risks and reduce capital costs.

As with any large industrial projects, STE projects require several permissions, often delivered by many different government jurisdictions at various geographical levels, as well as many branches or agencies of each – local, regional, state, federal or national. Each may protect different interests, all of them legitimate.

Future values of PV and STE in California Researchers at the National Laboratory of Renewable Energy (NREL) in the United States have studied the future total values (operational value plus capacity value) of STE with storage and PV plants in California in two scenarios: one with 33% renewables in the mix (the renewable portfolio standard by end 2020), including about 11% PV, another with 40% renewables (under consideration by California’s governor), including about 14% PV. In both cases there is over 1 GW of electricity storage available on the grid. The main results indicate that at 33% renewable penetration, the bulk of the gap in favour of STE comes from its greater capacity value, which avoids the costs of building additional thermal generators to meet demand (Table 5). At 40% renewable penetration, the value of STE increases slightly, but the value of PV drops significantly, mostly reflecting the drop of its own capacity value (Jorgenson et al., 2014). For investment decisions and planning, system values are as much important as LCOE. Table 6: Total value in two scenarios of renewables penetration in California Value component 33% renewables 40% renewables STE with storage PV Value value (USD/MWh) (USD/MWh) STE with

The built-in storage capability of CSP is cheaper and more effective (with over 95% return efficiency, versus about 80% for most competing technologies) than battery storage and pumped-hydropower storage. Thermal storage allows separating the collection of the heat (during the day) and the generation of electricity (at will). This capability has immediate value in countries having significant increase in power demand when the sun sets, in part driven by lighting requirements. In many such countries, the electricity mix, which during daytime is often dominated by coal, becomes dominated by peaking technologies, often based on natural gas or oil products.

The greatest possible expansion of PV, which implies its dominance over all other sources during a significant part of the day, creates difficult technical and economic challenges to low-carbon base-load technologies such as nuclear power and fossil fuel with CCS. Natural gas is more suited to daily “stop-and-go” with rapid ramps up and down, and is more economical for mid-merit operations (between about 2,000 and 4,000 full-load hours).

changes in the rules applicable to investments already being made or in process can have long-lasting deterrent effects on investments if they significantly modify the prospects for economic returns. This is precisely what has happened over the last few years in Spain, where a series of measures aimed at reducing the return on investment on existing CSP plants. The high risk of losing investors’ confidence may have been deemed acceptable, as these measures followed the decision to stop CSP deployment. However it may have detrimental effects for future investments in CSP plants; for other investments in the energy sector; for other investments in any other sector that requires government involvement; and for investments in other countries

Financing CSP plants, like most renewable energy plants, are very capital-intensive, requiring large upfront expenditures. Financing is thus difficult, especially in new, immature markets, and for new, emerging sub-technologies. In the United States, some private investors have large amounts of money available and might be willing to invest in clean energy for a variety of reasons; but even in this context the risks may have appeared too high for large, innovative CSP projects – costing around USD 1 billion – to materialize, without the loan guarantee program of the US DoE. This program has been essential to the renaissance of CSP in the United States, in allowing projects to access debt at very low cost from a US government bank and facilitating financial closure at acceptable WACC of large projects.

In other countries, such as India, Morocco and South Africa, public low-cost lending has been essential for jump-starting the deployment of CSP. In India and South Africa, private banks would have not provided capital for the very long maturity involved. In Morocco, the presence of a government agency as equity partner significantly reduced the perception of policy risks among other partners. In Morocco and South Africa, international finance institutions provided concessional grants that reduced the overall costs of large CSP projects.

Subsidizing renewable energy projects through long-term and/or low-cost debt-related policies could reduce the total subsidies compared with per-kWh support. However, this transfers the burden of high capital-intensivity to governments, which may not have enough money at hand, and this carries a risk of slowing deployment. Interest subsidies and/or accelerated depreciation have much higher one-year budget efficiency.

Research is under way to test and evaluate methods of measuring DNI accurately using lower-cost instrumentation, and for producing long-term, high-quality DNI data sets by merging long-term, satellite-derived data of moderate accuracy with high-quality, highly accurate ground-based measurements that may only cover a year or less. This research also includes important studies on sunshape and circumsolar radiation, and how these factor into both DNI measurements and STE system performance. In addition, satellite-based methods for estimating DNI are constantly improving and represent a reliable and viable way of choosing the best sites for STE plants. Furthermore, the ability to accurately forecast DNI levels – from a few hours ahead to a few days ahead – is constantly improving, and will be an important tool for utilities operating STE systems.

Abbreviations: ARRA American recovery and reinvestment Act CCS carbon capture and storage CO2 carbon dioxide CPI Climate Policy Initiative CSF concentrated solar fuels CSP concentrating solar power CPV concentrating photovoltaic CRS central receiver system CTF Clean Technology Fund DC direct current DII Desertec Industry Initiative DLR Forschungszentrum der Bundesrepublik Deutschland für Luft- und Raumfahrt (German Aerospace Centre) DME Dimethyl ether DNI direct normal irradiance DSG direct steam generation EDF Électricité de France EIB European Investment Bank EPC engineering, procurement and construction ETP: Energy Technology Perspectives EU European Union EUR euro FiT feed-in tariff FiP feed-in premium G8 Group of Eight GHG greenhouse gas(es) GHI global horizontal irradiance GNI global normal irradiance Gt gigatonnes GW gigawatt (1 million kW)  GWh gigawatt hour (1 million kWh) Hi-Ren high renewables (Scenario) HTF heat transfer fluid HVDC high- voltage direct current IA implementing agreement IEA International Energy Agency IFI international financial institution IGCC integrated gasification combined cycle IRENA International Renewable Energy Agency ISCC Integrated Solar Combined-Cycle (plant) JRC Joint Research Centre kW kilowatt kWh kilowatt hour LCOE levelized cost of electricity LFR linear Fresnel reflectors MW megawatt (1 thousand kW) MWe megawatt electrical MWh megawatt hour (1 thousand kWh) MWth megawatt thermal NGO non-governmental organisation NREAP national renewable energy action plan NREL National Renewable Energy Laboratory (United States) OECD Organization for Economic Co-operation and Development O&M operation and maintenance PPA power purchase agreement PT parabolic trough  TWh terawatthour (1 billion KWh)

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