The wind and solar power myth has finally been exposed
By Paul Homewood
The necessary miracle doesn’t exist
By Bryan Leyland
Many governments in the Western world have committed to “net zero” emissions of carbon in the near future. The US and UK both say they will deliver by 2050. It’s widely believed that wind and solar power can achieve this. This belief has led the US and British governments, among others, to promote and heavily subsidise wind and solar.
These plans have a single, fatal flaw: they are reliant on the pipe-dream that there is some affordable way to store surplus electricity at scale.
In the real world a wind farm’s output often drops below 10 per cent of its rated “capacity” for days at a time. Solar power disappears completely every night and drops by 50 per cent or more during cloudy days. “Capacity” being a largely meaningless figure for a wind or solar plant, about 3000 megawatts (MW) of wind and solar capacity is needed to replace a 1000 MW conventional power station in terms of energy over time: and in fact, as we shall see, the conventional power station or something very like it will still be needed frequently once the wind and solar are online.
The governments of countries with a considerable amount of wind and solar generation have developed an expectation that they can simply continue to build more until net zero is achieved. The reality is that many of them have kept the lights on only by using existing fossil fired stations as backup for periods of low wind and sun. This brings with it a new operating regime where stations that were designed to operate continuously have to follow unpredictable fluctuations in wind and solar power. As a result operating and maintenance costs have increased and many stations have had to be shut down.
In fact it’s already common to see efficient combined-cycle gas turbines replaced by open-cycle ones because they can be throttled up and down easily to back up the rapidly changing output of wind and solar farms. But open-cycle gas turbines burn about twice as much gas as combined cycle gas turbines. Switching to high-emissions machinery as part of an effort to reduce emissions is, frankly, madness!
Certain countries are helped because their power systems are supported by major inter-connectors to adjacent regions that have surplus power available. The increasingly troubled French nuclear fleet, which formerly had plenty of spare energy on tap, for a long time helped to make renewables plans look practical across Western Europe.
But this situation is not sustainable in the long term. Under net-zero plans, all nations will need to generate many times more electricity than they now can, as the large majority of our energy use today is delivered by burning fossil fuels directly. Neighbouring regions will be unable to provide the backup power needed; emissions from open cycle gas turbines (or new coal powerplants, as in the case of Germany at the moment) will become unacceptable; more existing base load stations will be forced to shut down by surges in renewables; more and more wind and solar power will have to be expensively dumped when the sun is shining and the wind is blowing.
Power prices will soar, making more or less everything more expensive, and there will be frequent blackouts.
None of this is difficult to work out. Building even more renewables capacity will not help: even ten or 100 times the nominally-necessary “capacity” could never do the job on a cold, windless evening.
Only one thing can save the day for the renewables plan. Reasonable cost, large scale energy storage, sufficient to keep the lights on for several days at a minimum, would solve the problem.
What are the options?
First we need to consider the scale of the issue. Relatively simple calculations show that that California would need over 200 megawatt-hours (MWh) of storage per installed MW of wind and solar power. Germany could probably manage with 150 MWh per MW. Perhaps this could be provided in the form of batteries?
The current cost of battery storage is about US$600,000 per MWh. For every MW of wind or solar power in California, $120 million would need to be spent on storage. In Germany it would be $90 million. Wind farms cost about $1.5 million per MW so the cost of battery storage would be astronomical: 80 times greater than the cost of the wind farm! A major additional constraint would be that such quantities of batteries are simply not available. Not enough lithium and cobalt and other rare minerals are being mined at the moment. If prices get high enough supply will expand, but prices are already ridiculously, unfeasibly high.
Some countries are gambling on hydro pumped storage. Here the idea is to use electricity to pump water uphill into a high reservoir using surplus renewables on sunny, windy days: then let it flow back down through generating turbines as in a normal hydropower plant when it’s dark and windless.
Many pumped systems have been built in China, Japan and United States but they have storage sufficient for only 6 to 10 hours operation. This is tiny compared with the several days storage that is needed to back up wind and solar power through routine sunless calm periods. Much larger lakes at the top and bottom of the scheme are needed. There are very few locations where two large lakes can be formed with one located 400-700 m above the other and separated by less than 5-10 km horizontally. Such a location must also have an adequate supply of make-up water to cope with evaporation losses from the two lakes. Another problem is that at least 25 per cent of the energy is lost while pumping and then generating.
Hydro pumped storage will seldom be a feasible option. It cannot solve the problem on a national scale even in countries like the USA which have a lot of mountains.
Carbon capture and storage (CCS) for fossil fuel stations is also touted as way of avoiding the problems of wind and solar power. But this is not a technology, just a case of wishful thinking. In spite of many years of work and enormous amounts of money spent, nobody has yet devised a technology that can provide large scale, low cost CCS. Even if capture worked and didn’t consume most or all the energy generated, storing the carbon dioxide is a huge problem because three tonnes of carbon dioxide are produced for every tonne of coal burned.
Hydrogen is another technology which is often suggested for energy storage: but its problems are legion. At the moment hydrogen is made using natural gas (so-called “blue” hydrogen). This, however, will have to stop in a net-zero world as the process emits large amounts of carbon: you might as well just burn the natural gas. Proper emissions-free “green” hydrogen is made from water using huge amounts of electrical energy, 60 per cent of which is lost in the process. Storing and handling the hydrogen is extremely difficult because hydrogen is a very small molecule and it leaks through almost anything. At best this means that a lot of your stored hydrogen will be gone by the time you want to use it: at worst it means devastating fires and explosions. The extremely low density of hydrogen also means that huge volumes of it would have to be stored and it would often have to be stored and handled cryogenically, creating even more losses, costs and risks.
The conclusion is simple. Barring some sort of miracle, there is no possibility that a suitable storage technology will be developed in the needed time frame. The present policies of just forcing wind and solar into the market and hoping for a miracle have been memorably and correctly likened to “jumping out of an aeroplane without a parachute and hoping that the parachute will be invented, delivered and strapped on in mid air in time to save you before you hit the ground.”
Wind and solar need to be backed up, close to 100 per cent, by some other means of power generation. If that backup is provided by open-cycle gas or worse, coal, net zero will never be achieved: nor anything very close to it.
There is one technology that can provide a cheap and reliable supply of low-emissions electricity: nuclear power. Interest in nuclear power is increasing as more and more people realise that it is safe and reliable. If regulators and the public could be persuaded that modern stations are inherently safe and that low levels of nuclear radiation are not dangerous, nuclear power could provide all the low cost, low emissions electricity the world needs for hundreds or thousands of years.
But if we had 100 per cent nuclear backup for solar and wind, we wouldn’t need the wind and solar plants at all.
Wind and solar are, in fact, completely pointless.
https://www.telegraph.co.uk/news/2023/05/10/wind-solar-renewables-pointless-waste/
Bryan Leyland MSc, DistFEngNZ, FIMechE, FIEE(rtd) is a power systems engineer with more than 60 years experience on projects around the world. He is a member of the GWPF’s Academic Advisory Council
Comments are closed.
NOT A LOT OF PEOPLE KNOW THAT 
Oh no! A power systems engineer who knows what he is talking about. Facts getting in the way of feelings. Off with his head.
The Telegraph will not make the mistake again of allowing somebody who knows what he is talking about to write such an excellent article. They will no doubt continue to promote government propaganda.
If ever such an informative article were to makes it to the BBC, we would know that the renewable energy disaster was coming to an end. But pigs will fly first.
The devil incarnate, Bill Gates, might take his cash back from the Telegraph.
Phillip, the comments on the article piled in and many ripped him for being an old fogey spouting old philosophies – as if electricity generation was such an old technology – with some openly saying he was well past it.
But I guess many failed to take note of one truism when he said:
“Switching to high-emissions machinery as part of an effort to reduce emissions is, frankly, madness!”
The problem is getting politicians in the “Western world” to actually look at facts and not ignore them.
The solution is to replace the politicians as they are incapable of learning.
There is unfortunately the little matter of getting an election to happen.
>>The solution is to replace the politicians as they are incapable of learning
You can find all about Bryan Leyland here – well worth reading:
http://www.bryanleyland.co.nz/
From his site:
Climate Change
“I am seriously sceptical of claims that global warming is man-made, real and dangerous. These predictions rely upon computer models that failed to predict that there would be no warming for the last 18 years. This means that they are worthless. The climate is always changing and we must be prepared for climate change – be it warming or cooling. History tells us that cooling is more dangerous than warming. As you can see from my page on “global temperature prediction” we can, to some extent, predict temperatures from records of the Southern Oscillation Index (El Nino effect). I wonder how the global warmers are going to explain this?“
Well, That would be it in a nutshell!
great article.
Who is Nick Stokes and where is he?
Nick is Australian but is frequently in the UK. He is expert on warming related matters and believes in human induced warming. However in the opinion of many -including myself-he tends to indulge in group think and his beliefs trump reality. He is a very nice and courteous man. He has a good web site.
Thanks – comment was partly rhetorical, but with a grain of seriousness.
“He is expert on warming related matters and believes in human induced warming.”
Don’t doubt his technical acumen – I try desperately hard to remove my confounding bias and look dispassionately at the AWG/CC groupthink (and others); I acknowledge it is difficult to have a settled position as a non scientist – I rely on others; but the AWG/CC groupthink is extremely difficult to take seriously given a huge amount of non aligned experts information I have read which runs counter across the widest spectrum (same with SARS COV2….vaccines….Pharmaharma)…
Nick Stokes is an ‘Ex Burt’ in everything ( in his own mind ) !!
Stokes is a pita on WUWT and enjoys getting masses of down-votes on topics – the last one being his support for BOM not making public their historical (publicly-funded) temperature record. His comments are an experience…
The so-called green energy revolution was never about being practical or even feasible for application at scale. Just read Klaus Schwab’s Great Reset; it’s all in there. They KNOW this will never work. It is not supposed to work. It’s sole purpose is to bring down the economies of the West and transition them to a One World Global governance. Stop trying to reason with communists already.
O/T but for my debate here I need info on the one Norwegian ferry driven by HYDROGEN. They have 60 out of 200 battery or hybrid but HOW DOES THE HYDROGEN ONE WORK? Gas under pressure in a fuel tank? How many bars? Used on fuel cells to produce electricity or burnt to produce rotation or steam? Safety? Leakage? Refuelling? COSTS?
Is that the ferry company that has banned EVs because of the risk of fire?
Hi liardetg.
“MF Hydra uses liquid hydrogen, two 200 kW fuel cells, a 1.36 MWh battery, and two 440 kW diesel generators. The hydrogen tanks and the fuel cells are located on top of the ferry. The hydrogen is trucked from Leipzig in Germany.
The ferry qualifies as zero emission waterborne transport, or ZEWT. Ballard is supplying the fuel cell power systems for two of Norled’s zero-emission ferries.”
“The vessel specification includes an 80m3 (CBM) tank for hydrogen storage.”
http://elizabethqueenseaswann.com/HISTORY/LH2_Ships_Ferries_Yachts_Hydrogen_Projects/MF_Hydra_Norled_Car_Ferry_Norway_Liquefied_Hydrogen_Liquide.html
In terms of energy density, liquid hydrogen, achieves approx 2.3 kWh/litre. So its 80m^3 storage tank holds approx 184,000kWh.
Liquifying hydrogen is very energy intensive. Efficiencies may have improved since this 2009 paper was published:
“Hydrogen liquefaction involves multiple process steps and some degree of complexity in addition to compression. This leads to significantly higher energy requirements and a broader range of actual energy requirements which vary with liquefaction plant scale. Peschka [6] estimates an energy requirement of 10 kWh/kg LH2 for a conventional LH2 plant with improvements in compression and turbine efficiencies. Bracha shows as much as 13.3 kWh/kg LH2 for liquefaction at small industrial scales [11]. Discussions with industrial gas companies led to an estimated range of 8-12 kWh/kg LH2 for new plants with capacities of 5,000-200,000 kg LH2/day[5]. The largest liquefier in operation in the US today is about 55,000 kg LH2 /day[10] Current research shows a strong potential to achieve 7 kWh/kg LH2 based on active magnetic regenerative liquefiers[7]. The technology is potentially capable of lower costs than conventional liquefaction plants especially at small liquefaction scales (2,000 to 5,000 kg LH2/day) [7].”
Click to access 9013_energy_requirements_for_hydrogen_gas_compression.pdf
Hope that info helps.
Liquifying hydrogen:
“State of the art hydrogen liquefaction technology has a power consumption of 12 kWh/kg. This is equivalent to 36% of the useable energy contained in 1 kg of hydrogen (33.33 kWh/kg, see above).”
https://www.idealhy.eu/index.php?page=lh2_outline#:~:text=Under%20ambient%20conditions%2C%20a%20cubic,kWh%2Flitre%20at%20700%20bar.
That was an awful lot of facts and figures for what amounts to a pipe-dream–liquid hydrogen vehicles.
Do I assume that liquifaction involves cooling to cryogenic temperatures? That must cost a lot of German electricity?
To liardetg
You’re correct.
So it’s ironic that Greenies & enviros often quote Norway as a user of ‘clean’ energy, when their electricity is the dirtiest in Western Europe.
Norway’s answer to the Hindenburg
“These plans have a single, fatal flaw: they are reliant on the pipe-dream that there is some affordable way to store surplus electricity at scale.”
Two months ago, the BBC enthused:
https://www.bbc.co.uk/news/uk-scotland-highlands-islands-65015217
The article makes no mention of its energy storage capacity. (It’ll be 30GWh)
The article’s only reference to performance is “Scottish ministers approved the 1.5GW pumped storage facility in 2020.”
A formal complaint has pointed out that electricity and natural gas are both forms of energy, and as Britain has 40,000GWh of natural gas storage capacity, its claim was inaccurate.
Even the 1.5GW discharge capability isn’t ‘double’ anything. Dinorwig has a power discharge capability of 1.8GW; Rough natural gas energy storage facility can discharge at 63GW.
As has been pointed out to them, pumped storage costs a third of the energy used for pumping. At least that’s a better return on wind.
I just checked the latest figures. Pumped storage over the last year was 75.5% efficient in the UK. Meanwhile the Hornsdale Power Reserve – the Big South Australian Battery – is seeing its efficiency dip below 75% in recent months (74.79% in April). Perhaps the batteries are wearing out quicker than they hoped. It’s about 3 years since they added substantially to the capacity. Also notable that they are not achieving as high a throughput as they were.
Harry,
as I frequently point out, pumped hydro is not designed or built to assist renewable’s miserable performance. Indeed it pre dates renewables.
It’s advantage is that it can provide a lot of power very quickly should there be a sudden deficit of supply for whatever reason. Otherwise the frequency would go out of limits and there would be load shedding of the grid.
It is also a source of ‘black start’ power should there be a grid failure as power plants require electricity to restart. (Some have their own back up generators also)
It is too much for the media to understand the technicalities of the grid, not that they seem to try?
Joe Public, Australia threw money at a similar scheme in our Snowy Hydro system. The tunnel digger was moving extremely slowly and is now stuck in the early stage of the tunnel and they have to destroy it by digging it out. The cost has more than doubled the estimates.
When is there ever excess wind generation? Excess wind generation has never happened.
It gets curtailed and you get to pay for no output.
‘These plans have a single, fatal flaw: they are reliant on the pipe-dream that there is some affordable way to store surplus electricity at scale.’
Well, yeah, but that’s not how it evolved. For many years, they proclaimed that renewables could provide your electricity. Persistent questions about intermittency evoked the ‘storage’ response. ‘Storage’ isn’t about storing electricity. It’s about STFU.
Of course storage can’t be done at scale. But, more importantly, RENEWABLES can’t be done at scale.
“If regulators and the public could be persuaded ..”
Did Mr Leyland overlook persuading private investors? If so “cheap and reliable” and a superior to the best alternatives, private investors should be queuing up to commit capital in new nuclear power stations? Why do we not see private investors leading the charge?
“nuclear power could provide all the low cost, low emissions electricity the world needs for hundreds or thousands of years”
It will still be able to do so in 100 years’ time. Or after 200 years for that matter.
Delay has the benefit of gains in “the learning curve”, so we should be even better prepared to exploit and manage nuclear energy in 100-200 years.
Why does Mr Leyland suggest nuclear today when the economic case doesn’t stack up against perfectly good fossil fuel alternatives.
Nukes will do fine after the current generation dies off. BS like linear no-threshold poisoned their minds. The science will advance when the current experts die.
Jordan,
I would say it is an extremely difficult task to persuade the powers that be that renewables are not going to work, and that is putting it mildly, but then say that CO2 is not a problem and fossil fuels can do the job at a lower cost is just too much for them to accept.
So nuclear being Hobson’s choice of non CO2 emitting generation it has to be.
Gamecock – nukes will not do fine in the private sector.
The magnitude of the costs and liabilities in the development, construction and operating phases mean it is only a game where behemoths can play. The only players are Governments. The duration of the long-term waste management liabilities leave no private sector mechanism suitable for the private sector to underwrite/provide for – the only pragmatic option is to “socialise” waste management by passing it to Government. The only players are Governments.
Notice how I said nothing about nuclear safety risk and regulatory compliance. I don’t need to.
Ian Reid – Mr Leyland’s conclusions are wrong. He roundly criticises other technologies for their flaws, then turns to an equally flawed technology as his answer.
There is nothing to gain by making excuses for him, or for touting flawed arguments. We can defend the high ground if we criticise flawed arguments, no matter who is making the flawed argument, or whether we like the conclusion.
Jordan, I think you’ll find that the future isn’t what it used to be.
Gamecock, give it time.
Enjoyed the article but a nit pick..quote: In Germany it would be $90 million. Wind farms cost about $1.5 million per MW so the cost of battery storage would be astronomical: 80 times greater than the cost of the wind farm!
Isn’t 90/1.5 = 60 and not 80?
Like it or not we live in an age of attention span deficit and a general population which is ill informed about science. So the facts need to be presented in a readily understood manner. The facts may be there but they are just about indigestible. Want to get the message across then include an “executive” summary.
Excellent point. Years ago it was considered a success if adults could read at a six-grade level; i.e., they could read the day’s newspaper. But thanks to the destruction of the public education system in the U.S. by the powerful teacher unions, NEA and NTA, 60 to 80% of high school graduates cannot read at a sixth-grade level. Alas, even a well crafted executive summary would be unreadable by most of the population. What would help is regulators and politicians that were not all-in of the grift that is Climate Change.
I speculate that there are occasions where wind power is a net drain on the grid
I have created an Excel file from demand and wind data for 2022 downloaded from the Gridwatch website to attempt to calculate the excess installed wind power and energy storage capacity required to guarantee supply matches demand without the use of fossil fuels. For hydrogen storage to run hydrogen powered turbines, I calculate the installed wind capacity needs to be 6.75 times the average demand and for battery storage 4.5 times the average demand. Taking the NG ESO FES LTW for 2035 figure of 76 GW average demand I calculate, for hydrogen storage, we need 513 GW of installed wind power at a cost of £2.4tn with £347bn of electrolysers and a hydrogen storage capacity of 2.8m tonnes. Battery storage requires 342 GW of installed wind power at a cost of £1.6tn and 76 TWhrs of battery storage at a cost of £28tn. If anyone would like to check my Excel spreadsheet and calculations please email me at jbxcagwnz@gmail.com and I will be happy to send a copy.
RR SMRs would of course be a much better option….
“Taking the NG ESO FES LTW for 2035 figure of 76 GW average demand ”
Goodness, how far does this kind of negligence have to go before it become misconduct in a public office for the politicians & civil servants involved especially as many seem to be financially benefiting for these irrational decisions.
How is it possible we have the expectation that electricity demand overall and peak demand (that will be impractical to time shift) is to increase due to plans to electrify space heating and transport but no clear plan to increase electricity generating capacity even if we include planned increases of wind & solar capacity pretending its dispatchable.
Then there seems to be a drive to increase the number of interconnects to neighbouring grids but National grid clearly have a conflict of interest to highlight the need for new dispatchable capacity like a vertically integrated utility would as this means new/upgraded transmission capacity.
I will leave a link to a relevant consultation in case you missed it but does anyone think I would be worth writing to our MPs asking if there is any consideration to a 1947 or 63 style winter in the electrification/energy/net zero plans or what is the expected capacity margin for 2035 and who is responsible if their are shortfalls that led to rota disconnections/ load shedding at peak time.
https://www.gov.uk/government/consultations/strategy-and-policy-statement-for-energy-policy-in-great-britain
As I would personally struggle to vote for MP who doesn’t understand what a capacity margin is and want to make sure we have at enough generating capacity to meet expected demand and is aware of what happened in February 21 in Texas – Extreme cold spell with no wind (so it irrelevant/red herring if the wind turbines froze) so electricity from wind decrease just as demand due to space heating increased getting to the point of having no operating margin for things going wrong like transmitting line being taken out due to the weather or power stations tripping offline so should have started planned rolling blackout the evening of the 14th Feb instead they waited till the frequency started to decline (due to demand continuing to go up and supply going down) to point that they were minutes away from generators disconnecting themselves to avoid damage so had to indiscriminately shed-load to bring the frequency back up unfortunately there wasn’t clear planning to protect electricity supplies to natural gas compressor which had no backup generator (these used to be powered by gas from the same pipeline but due to sudden concerns about air pollution and the fact electric natural gas compressor are cheaper to buy and maintain) meant many gas power station had no fuel so had to shut down and although gas power station can also burn petroleum and unlike in the past when they would keep backup fuel on site now they will only do so in deregulated markets if require to do so (See Ireland) or there are clear financially incentives. This meant that by the early morning practically every circuit that didn’t have something considered eventual on it like a hospital was turned off and there was an attempt to start rolling blackout but this wasn’t possible in some places (e.g. Austin) I suspect in part due to the way the level of load shielding was distributed between different electricity distributors without concern to the essential load so some were without power for days.
May 5th 2023 provided ideal evidence of the risks of Renewable Energy. Gas provided 54.5% and 17.4GW of UK Electricity with Wind providing 1.79% and 0.56GW. What answers can they give to that when Labour threaten to close down all Gas by 2030.
Intermittent renewables have been selected to replace fossil fuels instead of nuclear because it is known they will be an expensive failure and cause grid collapse and energy, food, heating and travel rationing.
The fact that nuclear, the only low CO2 emission source of power which is affordable, reliable and abundant is ignored is proof that anthropogenic CO2 emissions have little or no effect on the climate.
But even nuclear power will require conventional vehicles for installation, just like solar and wind farm projects. There will be little replacement for gasolines and renewable biofuels anytime soon. The “climate crisis” will have to wait.