I am grateful to Robert Bryce for publishing the following article which concisely sets forth the truth of the hype about the use of hydrogen to save the planet and “power” our world which is not at all feasible for the many reasons he sets forth.
For starters, hydrogen in and of itself is not a source of energy. It must be manufactured.
The Sun is mainly made of hydrogen. But there is nothing new under the Sun, and that includes hydrogen.
That Old Testament reference — “what has been will be done again; there is nothing new under the sun” — is appropriate here because the hype about hydrogen seems nearly as old as the Bible itself.
President George W. Bush bought the hydrogen hype. In his 2003 State of the Union Address, he said, “With a new national commitment, our scientists and engineers will overcome obstacles” to taking hydrogen-fueled automobiles “from laboratory to showroom so that the first car driven by a child born today could be powered by hydrogen, and pollution-free.” A few months after that speech, his administration announced a collaborative effort with the European Union for the “development of a hydrogen economy,” including the technologies “needed for mass production of safe and affordable hydrogen-powered fuel cell vehicles.” The White House claimed in a 2003 press release that the effort would “improve America’s energy security by significantly reducing the need for imported oil.”
The history of the hype matters because we live in ahistorical times. Or, as author Jeff Minick explained in 2022, we are plagued by “presentism.” Presentism, Minick wrote, “is the reason so many young people can name the Kardashians but can’t tell you the importance of Abraham Lincoln or why we fought in World War II.”
Presentism helps explain why, on April 30, the New York Times published a piece headlined, “Hydrogen Offers Germany a Chance to Take a Lead in Green Energy,” which ignores the long history of hydrogen’s failure to live up to the forecasts. But blaming presentism can’t account for the vapidity of the article, which hinges on this nut graf:
The concept of hydrogen as a renewable energy source has been around for years, but only within the past decade has the idea of its potential to replace fossil fuels to power heavy industry taken off, leading to increased investment and advances in the technology. (Emphasis added.)
The idea of hydrogen may (or may not) be taking off, but hydrogen is not a “source” of energy, it’s an energy carrier. Calling hydrogen an energy “source” is like calling Stormy Daniels an “actress.”
Hydrogen is abundant in the universe. But it’s not a source of energy. Instead, like electricity and gasoline, it must be manufactured. The most common ways are by splitting water through electrolysis, or via steam-methane reforming, which uses high-pressure steam to produce hydrogen from methane.
There are other forehead-slapping statements in the Times article written by Stanley Reed and Melissa Eddy, who traveled to the German city of Duisburg to visit a factory that makes electrolyzers. “If adopted widely,” they wrote, “the devices could help clean up heavy industry such as steel-making, in Germany and elsewhere.” Well, yes, if “adopted widely.” But despite decades of frothy predictions from Rifkin and others, electrolyzers haven’t been adopted widely because making and using hydrogen on a large scale is — as my friend, Steve Brick, puts it — “a thermodynamic obscenity.”
The cover of Rifkin’s 2003 book.
Reed and Eddy ignore the energy intensity of making hydrogen, only offering that by using “electricity to split water” the electrolyzer “produces hydrogen, a carbon-free gas that could help power mills like the one in Duisburg.” That’s true. But how much electricity is needed? And where the heck is German industry, which is already being hammered by expensive gas and power, going to get the juice? At what cost? Those questions are not addressed.
To be clear, lots of other media outlets are hyping hydrogen. And the hype is surging because of fat government subsidies. Reed and Eddy explain that the German government has earmarked some $14.2 billion “for investment in about two dozen projects to develop hydrogen.” Here in the U.S., the 45V tax credit in the Inflation Reduction Act provides lucrative subsidies for hydrogen production. Big business is lining up to get those subsidies. In February, energy giant Exxon Mobil warned that it might cancel a proposed hydrogen project at its Baytown, Texas refinery depending on how the Treasury Department interpreted the “clean” hydrogen rules in the IRA.
Regardless of tax credits and subsidies, making and using hydrogen is a high-entropy, high-cost process. As a friend in the oil refining business told me last year, “If you like $6-per-gallon gasoline, you’re gonna love $14-to-$20-per-gallon hydrogen.”
As for Brick’s “thermodynamic obscenity” line, the numbers — which I’ll examine in a moment — are easy to understand. Hydrogen is insanely expensive, in energy terms, to manufacture. It takes about three units of energy, in the form of electricity, to produce two units of hydrogen energy. In other words, the hydrogen economy requires scads of electricity (a high quality form of energy) to make a tiny molecule that’s hard to handle, difficult to store, and expensive to use.
Among the biggest challenges in handling and storing the gas is the problem of “hydrogen embrittlement,” which can occur when metals are exposed to hydrogen. That means we can’t use existing gas pipelines or tanks to move and store the gas. As for using the gas, yes, it can be blended with natural gas and put into turbines or reciprocating engines. However, the best way to use it is in a fuel cell. And from where will those devices come? I’m old enough to collect Social Security. I’ve been reporting about the energy sector for nearly four decades, and yet, in all that time, I’ve seen precisely three fuel cells.
How much would the hydrogen economy cost? In 2020, Bloomberg NEF estimated that producing enough “green” hydrogen to meet 25% of global energy demand would require “more electricity than the world now generates from all sources and an investment of $11 trillion in production and storage.”
The obscene thermodynamics of hydrogen can be understood by looking at an announcement made last year by Constellation Energy. According to a March 10, 2023 article in Nuclear NewsWire, a new hydrogen production project at the company’s Nine Mile Point nuclear plant in New York, “is part of a $14.5 million cost-shared project between Constellation and the Department of Energy.” Of that sum, $5.8 million was coming from the DOE. The article explained that “Using 1.25 megawatts of zero-carbon energy per hour,” the plant’s electrolyzer will produce “560 kilograms of clean hydrogen per day.”
The math is simple. The plant uses 30 megawatt-hours of electricity to produce 560 kg of hydrogen per day. One MWh of electricity is equal to 3,600 megajoules of energy, and one kg of hydrogen contains about 130 MJ of energy. Therefore, Nine Mile Point uses 108,000 MJ of electricity to produce 72,800 MJ of hydrogen, or 1.5 MJ of electricity for 1 MJ of hydrogen.
Such a lousy EROEI (energy return on energy invested) should immediately disqualify hydrogen from serious energy policy discussions. But that, of course, hasn’t happened. It must also be noted that the EROEI is worse than what I stated above because the hydrogen, once produced, must be stored and fed back into another energy conversion device to make electricity or heat. In that process, more energy will be lost.
I’ll end with a bit more history. In 2004, the National Research Council and the National Academy of Engineering published a 267-page report called “The Hydrogen Economy: Opportunities, Costs, Barriers, and R&D Needs.” In the concluding section, the report said, “making hydrogen from renewable energy through the intermediate step of making electricity, a premium energy source, requires further breakthroughs in order to be competitive.” It continued:
There are major hurdles on the path to achieving the vision of the hydrogen economy; the path will not be simple or straightforward. Many of the committee’s observations generalize across the entire hydrogen economy: the hydrogen system must be cost-competitive, it must be safe and appealing to the consumer, and it would preferably offer advantages from the perspectives of energy security and CO2 emissions. Specifically for the transportation sector, dramatic progress in the development of fuel cells, storage devices, and distribution systems is especially critical. Widespread success is not certain.
Widespread success of the hydrogen economy wasn’t certain in 2004, and it’s not certain now. Or, to put it in ecclesiastical terms, there’s nothing new under the hydrogen sun.
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.
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Wowie zowie, more subsidies to enrich the already uber-wealthy! Human stupidity knows no bounds, but the consequences of our idiocy are catching up with us.
Wowie zowie, more subsidies to enrich the already uber-wealthy! Human stupidity knows no bounds, but the consequences of our idiocy are catching up with us.