Meticulous Research Review Questions Environmental Impacts and Feasibility of “Green Energy” Transition
A meticulous new review published in the scientific journal, Energies, conducted by a team of Irish and US-based researchers including CERES researchers, raises surprising and unsettling questions about the feasibility and the environmental impacts of the transition to renewable energy sources. Concern for climate change has driven massive investment in new “green energy” policies intended to reduce greenhouse gas (GHG) emissions and other environmental impacts from the fossil fuel industry. The world spent US$3,660 billion on climate change projects over the eight-year period 2011–2018. A total of 55% of this sum was spent on solar and wind energy, while only 5% was spent on adapting to the impacts of extreme weather events.
Surprising environmental impacts
The researchers discovered that renewable energy sources sometimes contribute to problems they were designed to solve. For example, a series of international studies have found that both wind and solar farms are themselves causing local climate change. Wind farms increase the temperature of the soil beneath them, and this warming causes soil microbes to release more carbon dioxide. So, ironically, while wind energy might be partially reducing human “carbon emissions”, it is also increasing the “carbon emissions” from natural sources.
Photographs showing two different kinds of “wake effect” at off-shore wind farms off the shores of Denmark. (a) Photograph by Christian Steiness shows the wake effect of cold humid air passing over a warmer sea surface, adapted from Figure 2 of Hasager et al. (2013), reproduced under Creative Commons copyright license CC BY 3.0. (b) Photograph by Bel Air Aviation Denmark – Helicopter Services shows the wake effect of warm humid air passing over a cooler sea surface, adapted from Figure 2 of Hasager et al. (2017). Reproduced under Creative Commons copyright license CC BY 4.0.
Green energy technologies require a 10-fold increase in mineral extraction compared to fossil fuel electricity. Similarly, replacing just 50 million of the world’s estimated 1.3 billion cars with electric vehicles would require more than doubling the world’s annual production of cobalt, neodymium, and lithium, and using more than half the world’s current annual copper production.
Solar and wind farms also need 100 times the land area of fossil fuel-generated electricity, and these resulting changes in land use can have a devastating effect on biodiversity. The effects of bioenergy on biodiversity are worse, and the increased use of crops such as palm oil for biofuels is already contributing to the destruction of rainforests and other natural habitats.
Perplexing financial implications
Surprisingly, more than half (55%) of all global climate expenditure in the years 2011‒2018 was spent on solar and wind energy ‒ a total of US$2,000 billion. Despite this, wind and solar energy still produced only 3% of world energy consumption in the year 2018, while the fossil fuels (oil, coal and gas) produced 85% between them. This raises pressing questions about what it would cost to make the transition to 100% renewable energies, as some researchers suggest.
As lead author Coilín ÓhAiseadha says: “It cost the world $2 trillion to increase the share of energy generated by solar and wind from half a percent to three percent, and it took eight years to do it. What would it cost to increase that to 100%? And how long would it take?”
World energy consumption by source, 2018. Data from BP (2019).
Daunting engineering challenges
Engineers have always known that large solar and wind farms are plagued by the so-called “intermittency problem”. Unlike conventional electricity generation sources which provide continuous and reliable energy 24/7 on demand, wind and solar farms only produce electricity when there is wind or sunlight.
“The average household expects their fridges and freezers to run continuously and to be able to turn on and off the lights on demand. Wind and solar promoters need to start admitting that they are not capable of providing this type of continuous and on-demand electricity supply on a national scale that modern societies are used to,” says Dr Ronan Connolly, co-author of the new review.
The problem is not easily solved by large-scale battery storage because it would require huge batteries covering many hectares of land. Tesla has built a large battery to stabilize the grid in South Australia. It has a capacity of 100 MW/129 MWh and covers a hectare of land. One of the papers reviewed in this new study estimated that, if the state of Alberta, Canada, were to switch from coal to renewable energy, using natural gas and battery storage as back-up, it would require 100 of these large batteries to meet peak demand.
Some researchers have suggested that the variations in energy production can be evened out by building continental electricity transmission networks, e.g., a network connecting wind farms in north-west Europe with solar farms in the south-east, but this requires massive investment. It is likely to create bottlenecks where the capacity of inter-connections is insufficient, and does not do away with the underlying vulnerability to lulls in sun and wind that can last for days on end.
Hurting the poorest
A series of studies from Europe, the U.S. and China shows that carbon taxes tend to lay the greatest burden on the poorest households and rural-dwellers.
Although the primary motivation for green energy policies is concern over climate change, only 5% of climate expenditure has been dedicated to climate adaptation. Climate adaptation includes helping
developing countries to better respond to extreme weather events such as hurricanes. The need to build climate adaptation infrastructure and emergency response systems may conflict with the need to reduce greenhouse gas emissions, because fossil fuels are generally the most readily available source of cheap energy for development.
With regards to indigenous peoples, the review highlights the fact that all energy technologies can have severe impacts on local communities, particularly if they are not properly consulted. Cobalt mining, required to make batteries for e-vehicles, has severe impacts on the health of women and children in mining communities, where the mining is often done in unregulated, small-scale, “artisanal” mines. Lithium extraction, also required for manufacturing batteries for e-vehicles, requires large quantities of water, and can cause pollution and shortages of fresh water for local communities.
As lead author, Coilín ÓhAiseadha, points out: “There was worldwide coverage of the conflict between the Standing Rock Sioux Tribe and the Dakota Access Pipeline, but what about the impacts of cobalt mining on indigenous peoples in the Democratic Republic of the Congo, and what about the impacts of lithium extraction on the peoples of the Atacama Desert? Remember the slogan they chanted at Standing Rock? Mni Wiconi! Water is life! Well, that applies whether you’re Standing Rock Sioux worried about an oil spill polluting the river, or you’re in the Atacama Desert worried about lithium mining polluting your groundwater.”
Overview of the paper
The review, published in a Special Issue of the journal Energies on 16 September, covers 39 pages, with 14 full-color figures and two tables, detailing the breakdown of climate change expenditure and the pros and cons of all of the various options: wind, solar, hydro, nuclear, fossil fuels, bioenergy, tidal and geothermal. For the review, the researchers searched meticulously through hundreds of research papers published throughout the whole of the English-speaking world, in a wide range of fields, including engineering, environment, energy and climate policy. The final report includes references to 255 research papers covering all of these fields, and it concludes with a table summarizing the pros and cons of all of the various energy technologies. Research team members were based in the Republic of Ireland, Northern Ireland, and the United States.
The review was published as an open-access peer-review paper and can be downloaded for free from the following URL: https://www.mdpi.com/1996-1073/13/18/4839 .
The full citation is as follows: ÓhAiseadha, C.; Quinn, G.; Connolly, R.; Connolly, M.; Soon, W. Energy and Climate Policy—An Evaluation of Global Climate Change Expenditure 2011–2018. Energies 2020, 13, 4839.
Funding: C.Ó., G.Q., and M.C. received no external funding for works on this paper. R.C. and W.S. received financial support from the Center for Environmental Research and Earth Sciences (CERES), while carrying out the research for this paper. The aim of CERES is to promote open-minded and independent scientific inquiry. For this reason, donors to CERES are strictly required not to attempt to influence either the research directions or the findings of CERES. Readers interested in supporting CERES can find details at Link.
A meticulous new review published in the scientific journal, Energies, conducted by a team of Irish and US-based researchers including CERES researchers, raises surprising and unsettling questions about the feasibility and the environmental impacts of the transition to renewable energy sources. Concern for climate change has driven massive investment in new “green energy” policies intended to reduce greenhouse gas (GHG) emissions and other environmental impacts from the fossil fuel industry. The world spent US$3,660 billion on climate change projects over the eight-year period 2011–2018. A total of 55% of this sum was spent on solar and wind energy, while only 5% was spent on adapting to the impacts of extreme weather events.
Surprising environmental impacts
The researchers discovered that renewable energy sources sometimes contribute to problems they were designed to solve. For example, a series of international studies have found that both wind and solar farms are themselves causing local climate change. Wind farms increase the temperature of the soil beneath them, and this warming causes soil microbes to release more carbon dioxide. So, ironically, while wind energy might be partially reducing human “carbon emissions”, it is also increasing the “carbon emissions” from natural sources.
Photographs showing two different kinds of “wake effect” at off-shore wind farms off the shores of Denmark. (a) Photograph by Christian Steiness shows the wake effect of cold humid air passing over a warmer sea surface, adapted from Figure 2 of Hasager et al. (2013), reproduced under Creative Commons copyright license CC BY 3.0. (b) Photograph by Bel Air Aviation Denmark – Helicopter Services shows the wake effect of warm humid air passing over a cooler sea surface, adapted from Figure 2 of Hasager et al. (2017). Reproduced under Creative Commons copyright license CC BY 4.0.
Green energy technologies require a 10-fold increase in mineral extraction compared to fossil fuel electricity. Similarly, replacing just 50 million of the world’s estimated 1.3 billion cars with electric vehicles would require more than doubling the world’s annual production of cobalt, neodymium, and lithium, and using more than half the world’s current annual copper production.
Solar and wind farms also need 100 times the land area of fossil fuel-generated electricity, and these resulting changes in land use can have a devastating effect on biodiversity. The effects of bioenergy on biodiversity are worse, and the increased use of crops such as palm oil for biofuels is already contributing to the destruction of rainforests and other natural habitats.
Perplexing financial implications
Surprisingly, more than half (55%) of all global climate expenditure in the years 2011‒2018 was spent on solar and wind energy ‒ a total of US$2,000 billion. Despite this, wind and solar energy still produced only 3% of world energy consumption in the year 2018, while the fossil fuels (oil, coal and gas) produced 85% between them. This raises pressing questions about what it would cost to make the transition to 100% renewable energies, as some researchers suggest.
As lead author Coilín ÓhAiseadha says: “It cost the world $2 trillion to increase the share of energy generated by solar and wind from half a percent to three percent, and it took eight years to do it. What would it cost to increase that to 100%? And how long would it take?”
World energy consumption by source, 2018. Data from BP (2019).
Daunting engineering challenges
Engineers have always known that large solar and wind farms are plagued by the so-called “intermittency problem”. Unlike conventional electricity generation sources which provide continuous and reliable energy 24/7 on demand, wind and solar farms only produce electricity when there is wind or sunlight.
“The average household expects their fridges and freezers to run continuously and to be able to turn on and off the lights on demand. Wind and solar promoters need to start admitting that they are not capable of providing this type of continuous and on-demand electricity supply on a national scale that modern societies are used to,” says Dr Ronan Connolly, co-author of the new review.
The problem is not easily solved by large-scale battery storage because it would require huge batteries covering many hectares of land. Tesla has built a large battery to stabilize the grid in South Australia. It has a capacity of 100 MW/129 MWh and covers a hectare of land. One of the papers reviewed in this new study estimated that, if the state of Alberta, Canada, were to switch from coal to renewable energy, using natural gas and battery storage as back-up, it would require 100 of these large batteries to meet peak demand.
Some researchers have suggested that the variations in energy production can be evened out by building continental electricity transmission networks, e.g., a network connecting wind farms in north-west Europe with solar farms in the south-east, but this requires massive investment. It is likely to create bottlenecks where the capacity of inter-connections is insufficient, and does not do away with the underlying vulnerability to lulls in sun and wind that can last for days on end.
Hurting the poorest
A series of studies from Europe, the U.S. and China shows that carbon taxes tend to lay the greatest burden on the poorest households and rural-dwellers.
Although the primary motivation for green energy policies is concern over climate change, only 5% of climate expenditure has been dedicated to climate adaptation. Climate adaptation includes helping
developing countries to better respond to extreme weather events such as hurricanes. The need to build climate adaptation infrastructure and emergency response systems may conflict with the need to reduce greenhouse gas emissions, because fossil fuels are generally the most readily available source of cheap energy for development.
With regards to indigenous peoples, the review highlights the fact that all energy technologies can have severe impacts on local communities, particularly if they are not properly consulted. Cobalt mining, required to make batteries for e-vehicles, has severe impacts on the health of women and children in mining communities, where the mining is often done in unregulated, small-scale, “artisanal” mines. Lithium extraction, also required for manufacturing batteries for e-vehicles, requires large quantities of water, and can cause pollution and shortages of fresh water for local communities.
As lead author, Coilín ÓhAiseadha, points out: “There was worldwide coverage of the conflict between the Standing Rock Sioux Tribe and the Dakota Access Pipeline, but what about the impacts of cobalt mining on indigenous peoples in the Democratic Republic of the Congo, and what about the impacts of lithium extraction on the peoples of the Atacama Desert? Remember the slogan they chanted at Standing Rock? Mni Wiconi! Water is life! Well, that applies whether you’re Standing Rock Sioux worried about an oil spill polluting the river, or you’re in the Atacama Desert worried about lithium mining polluting your groundwater.”
Overview of the paper
The review, published in a Special Issue of the journal Energies on 16 September, covers 39 pages, with 14 full-color figures and two tables, detailing the breakdown of climate change expenditure and the pros and cons of all of the various options: wind, solar, hydro, nuclear, fossil fuels, bioenergy, tidal and geothermal. For the review, the researchers searched meticulously through hundreds of research papers published throughout the whole of the English-speaking world, in a wide range of fields, including engineering, environment, energy and climate policy. The final report includes references to 255 research papers covering all of these fields, and it concludes with a table summarizing the pros and cons of all of the various energy technologies. Research team members were based in the Republic of Ireland, Northern Ireland, and the United States.
The review was published as an open-access peer-review paper and can be downloaded for free from the following URL: https://www.mdpi.com/1996-1073/13/18/4839 .
The full citation is as follows: ÓhAiseadha, C.; Quinn, G.; Connolly, R.; Connolly, M.; Soon, W. Energy and Climate Policy—An Evaluation of Global Climate Change Expenditure 2011–2018. Energies 2020, 13, 4839.
###
If you would like more information about this scientific review paper, please contact (available Monday‒Friday, 10h‒18h GMT):
Ronan Connolly at +353 89 250 1433 (phone or WhatsApp) or ronan@ceres-science.com
Coilín ÓhAiseadha at +353 89 245 4313 (phone or WhatsApp) or coohais@gmail.com
https://www.ceres-science.com/content/Renewables.html
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Just to let people know, here in France there is a crowdfunding site for a new documentary to be made about the windmill gravy train.
https://www.documentaire-et-verite.com/projet/eoliennes-casse-du-siecle/
The title roughly translates to “Wind turbines – Swindle of the Century”.
Just to make it clear, the people behind the project are far from being some “right wing, oil supported, think tank”, in fact they are all in agreement about the changing climate, but they are also in agreement about the worthlessness of these machines.
Stick a translator on their website to find out more.
Any smart, inquisitive high school student using basic arithmetic, a spreadsheet and the Internet could in a short while determine that solar, wind and biomass (in any form or combination) are a hopeless failure and gigantic waste of money for powering a modern economy. One just has to ask insightful, data-focused questions, ignoring the incessant hype and misinformation. This present analysis just adds to the extensive list of experts and laypersons who have realistically examined the data and concluded the same.
Sorry to disappoint Griff, et al., who apparently have never gone through this exercise for themselves. Of course, low information automatons like Griff don’t value independent thinking. They have already been assimilated into the Borg collective.
I think griff is paid by the green blob. Otherwise he’s negative IQ.
So it cost $3.66 trillion to enable solar and wind energy to supply 3% of the world’s energy demand. If this was a linear trend, $122 trillion would be needed to convert 100% of the world’s energy to wind and solar, IF there was enough wind and sunshine available to be converted to electricity at relatively low efficiency. This is about 6 times the USA’s GDP, meaning that AOC’s estimate of $92 trillion was a little low, and the USA would spend all its industrial production for 6 years to set up the Green New Deal, with nothing left for little niceties like food. Mmm, no thanks!
If nothing is done about sea level rise, at a rate of 2.5 mm/year the sea level would rise by 200 mm, or a little less than 8 inches, by the year 2100. How much would it cost to build an 8-inch-high seawall around all “vulnerable” low-lying areas over the next 80 years? Probably less than $3.66 trillion, and spread over 80 years that would be about $46 billion per year, or about 0.23% of US GDP. That seems like a much more worthwhile investment!
Approximately $2 trillion was spent on wind and solar, and the share of electricity consumption that they generated increased from 0.5% to 3.0%, i.e. an increase of 2.5 percentage points. So, to get to 100%?
From the article: “The world spent US$3,660 billion on climate change projects over the eight-year period 2011–2018.”
What a huge waste of money and effort to fix a CO2 problem that has never been shown to exist.
A science fraud of historic proportions.
Obviously, many human beings are easily led astray by misinformation.
We’ll get an idea of the percentage of their numbers in the coming November 3, presidential election. Are the morons outnumbered, or do the morons outnumber the sane? A lot will hinge on the answer to that.
It is disgusting to see such a waste of money and resources which would have been better used to truly help people in need by funding sensible projects around the globe.
Yes,Yes, Yes!!!!~
The second half of the article had a sense of déjà vu.
SMR’s will be a game changer on a multitude of levels.
The French had a character in a book a French knight tilting at windmills that he believed were dragons.
If my memory serves me correctly Cervantes was his name.
We need now some characters that will take on this new crop of dragons and slay them.
Spanish.
You got almost everything wrong. He believe the windmills to be giants.
https://en.wikipedia.org/wiki/Don_Quixote
“Don Quixote is a Spanish novel by Miguel de Cervantes. It was published in two parts, in 1605 and 1615. A founding work of Western literature, it is often labeled “the first modern novel” and many authors consider it to be the best literary work ever written.”
You should know more about it if you want to be a cultivated person.
WJob:
Wonderful analogy!
However it’s Miguel Cervantes’ Spanish novel about Don Quixote and his faithful servant Sancho.
Hey! Maybe now it’s M. Mann and sidekick B. Nye racing around saving the planet from imaginary evils?
But instead of a sword he’d use a hockey stick (of course!). LOL
Solar power is pretty unreliable. I have solar panels on my house, and they produce electricity during the day, but none at all at night.
I’m sure there’s something wrong with them.
You’ll need to hook up some floodlights powered by a gas generator to light them up at night. Then they’ll produce power 24 hours a day!
Much worrying if molten salt reactors would work. Also much worrying about Small Modular Reactors (SMRs). But when you think about it, every nuclear submarine has a SMR. It has to be small to fit inside the hull, and they are churned out by the dozen.
See https://www.world-nuclear.org/information-library/non-power-nuclear-applications/transport/nuclear-powered-ships.aspx for some info re nuclear powered ships – mostly submarines.
Above all, remember that a nuclear power plant is just another means of boiling water.
Spending on climate adaptation not only also covers the case where the climate change is natural, so is actually the best precautionary principle. but is also cheaper.
The GDP boost to high latitude countries from CO2 and warming can easily pay for adaptation in Africa.
I think people here will be interested in checking this site:
https://www.ceres-science.com/index.html
It appears to be Willie Soon’s child.
This article is just their first press release pasted twice:
https://www.ceres-science.com/content/Renewables.html
I wish them the best.
While the article, and most of the comments, are 100% correct, they are 100% a waste of (electronic) ink. Why? Who was it said, “The issue is never the issue.”? Because protesters don’t want the “problem” solved, if it were solvable, there wouldn’t be an issue to protest, and they lose. In fact, this “Climate Change” scam is the perfect “problem” to spark a revolution, since it’s not a problem to begin with of course there are no viable solutions. The fact that their “constructive alternative” would require and/or result in a reduction of the human population by ≥80% is a feature, not a bug.
Globally $80 trillion … wasn’t the figured cost of the proposed U.S. GND $94 trillion over 10 years?
That’s 80 million times a million dollars. As Bernie Sanders would say, it’s “yuuuge”. Or, as Mr Trump would say: “Billions and billions and billions and billions …”
It’s almost four times the entire GDP of the United States ($21 trillion in 2019). More than four times the GDP of the European Union ($18 trillion). About 5.5 times China’s GDP ($14 trillion).
Is it plausible?
How much nuclear could have been brought online for 2 trillion?!
You’re right. Harjanne & Korhonen (2019) do a good job of debunking the word “renewable”. See reference in the paper. But don’t yell at us, please, write to your policymakers.
Thanks for all the very insightful and witty comments! My co-authors and I are delighted to see the review generate such a lively response among people who are already so well-informed.
If you are perplexed by the way climate expenditure is being allocated, please do as follows:
Read the full research paper.
Share with friends, colleagues and policymakers.
Challenge them to “Respect science!”
Please share!
Thank you!