The "hydrogen economy" is like a zombie: no matter how many times it is slain, it keeps coming at you. Like a Hollywood zombie movie, hydrogen seems to exert a tremendous fascination because it is being sold to people as a way to keep doing everything we have been doing without any need for sacrifices or for changing our ways. Unfortunately, reality is not a movie, and the reverse is also true. Hydrogen is a pie in the sky that delays the real innovation that would make it possible to phase out fossil fuels from the world's energy mix. (image source)
This post was originally published on "Cassandra's Legacy" on Dec 21, 2020
This is a re-worked and updated version of a post that I published in 2007, in Italian, during one more of the periodic returns of the "hydrogen economy," a fashionable idea that leads nowhere. For more technical information on the hydrogen scam, see the exhaustive treatment by Antonio Turiel in three posts on his blog "Crash Oil", in Spanish, "The Hydrogen Fever" One, two, and Three, all written by "Beamspot."
Confessions of a Former Hydrogenist
By Ugo BardiI think it was in 2004 when an Italian company based in Tuscany developed a hydrogen car and organized a presentation for the president of the Tuscan regional government. I was invited to attend as the local fuel cell expert.
So, I showed up in the courtyard of the Tuscan government building where a truck had unloaded the car. It turned out to be a modified Fiat Multipla that you may know as having been awarded the 2014 prize for the ugliest car ever made. Of course, that was not the problem. It was that it was not a fuel cell car. It was just an ordinary car fitted with two compressed hydrogen cylinders under the body. The hydrogen went directly into the internal combustion engine.
Before the President appeared, I had a chance to drive that car. I managed to make a full tour of the courtyard of the building, but it was like riding an asthmatic horse. The technician of the company told me that, yes, the regulation of the carburetor was not so easy. I could only agree on that.
When the President showed up, he clearly had no idea of what was going on and what he was supposed to do. He sat at the wheel, drove the car for a few meters in heavy bumps, then he gave up and just sat there in order to be photographed by the journalists. The day after, the local newspapers showed the photos of the president driving the "hydrogen car," a prodigy of the Tuscan inventive. Then the car disappeared forever into the dustbin of history, together with the long list of hydrogen-powered prototypes that were made, shown, and scrapped over the years.
That was just part of a story that had started for me in 1980, when I arrived in Berkeley, in California, to do a post-doc stage at the Lawrence Berkeley Laboratory. At that time, the worst of the first oil crisis was over but the shock was still felt, and everywhere in the US and in the world it was a flourishing of research projects dedicated to new forms of energy.
In Berkeley, I worked for two years on fuel cells; the technology that was to be used to transform hydrogen into electricity and that was - and still is - essential to the concept of "hydrogen-based economy" (The idea was already well known in the 1980s, Rifkin didn't invent anything with his 2002 book). It was an interesting field, even fascinating, but very difficult. We were studying the "core" of the device, the catalyst. How it worked and what could be done to improve its performance. I think we did some good research work, although we found nothing revolutionary.
With the end of my contract at the Lawrence Berkeley Lab approaching, I started looking for a job. I remember that I was told that there was someone in Canada who had set up a company dedicated to developing fuel cells. I vaguely thought about sending them a resume but, eventually, I didn't. For what I was told, that company was little more than a garage staffed with a few enthusiasts. Not the kind of thing that promised a bright future for a researcher.
It was a mistake on my part. Later on, the company grew and its leader, Geoffrey Ballard, became famous. They improved a fuel cell design that had been developed earlier on by NASA and the result was a major advance. It made possible the first fuel-cell bus in the world (1993). That led to Ballard being nominated "hero of the planet" in 1999.
In the 1990s it occurred to me several times that, if in 1982 I had sent that resume to Ballard, maybe I could have been one of the developers of what seemed to be the revolution of the century. Maybe I would have been named "Hero of the Planet" too! The polymer membrane fuel cell (PEMFC) was the device that would have made possible the hydrogen-based economy: clean prosperity for everyone. Ans I would have made a lot of money.
But, as it has often happened to me in my life, I found myself in the wrong place and out of sync with the rest of the world. In 1982, when I was looking for a job, the oil crisis seemed to be over and oil prices had fallen sharply. The interest in alternative energies was waning and, with the foresight typical of human beings, research programs on energy were being abandoned. There was little room, as a result, for a fuel cell expert. The best I could find in the US was an offer to work in a research center in Montana. It did not attract me so much and, in the end, I decided to return to my university, in Italy. There, I tried to set up a research program on fuel cells, but nobody was interested (again, the typical foresight of human beings). So after a few years, I moved to different subjects.
In the meantime, the interest in new forms of energy waxed and waned with the vagaries of oil prices. In 1991, the first gulf war was already an alarm bell, but the 9/11 attacks of 2001 made it clear to everyone that the supply of crude oil to the West was not guaranteed. Perhaps as a consequence, in 2002 there came Jeremy Rifkin's book "The Hydrogen Based Economy." Promoted by a high-profile campaign, it was a huge success and the idea became rapidly popular. Hydrogen was understood as the way to solve all energy problems in a single sweep: not only hydrogen was clean and renewable, but it required no changes in people's lifestyle or habits. It was just a question of filling up your car's tank with something that was not gasoline, all the rest would remain unchanged. It was in perfect agreement with what George W. Bush had said, "The American lifestyle is not up for negotiation."
Even though I had not been working on fuel cells in Italy, Rifkin's success caused me to be shining of reflected light. It turned out that I was one of the few researchers in Italy having some hands-on experience with fuel cells. I was invited to speak at conferences and public presentations and some people even started calling me "Professor Hydrogen."(!!)
I must admit that, in the beginning, I spoke as if I believed in the idea of the hydrogen-based economy, and maybe I did. But, gradually, I started having serious doubts. I even had a chance to meet Rifkin in person in 2006 at a conference that I had organized in Tuscany. His talk was all hype and no substance. When he was asked technical questions, all he could answer was something like "have faith," and then he would change subject.
As I started being more and more bothered by the hype on hydrogen, soon I saw what the real problem was. Back in the 1980s, in Berkeley, we already knew that the critical feature of fuel cells of the kind that can work near room temperature (called PEM, polymer electrode membrane cells) is the need for a catalyst at the electrodes. Without a catalyst, the cell just doesn't work at room temperature and the only catalyst that can make the cell work is platinum.
Of course, platinum is expensive, but that's not the main problem, as I discovered when I started getting involved in studies on mineral depletion. If you were to replace the current vehicles with fuel cells, there would be no way to produce enough platinum from mines (for details, you can see this 2014 article of mine). Indeed, the two years I had spent at the Lawrence Berkeley Lab were dedicated to finding ways to use less platinum, or something else in place of platinum. It wasn't just me working on it, it was a whole research group, one of the several engaged on the subject.
There are several tricks you can play to reduce the platinum loading in fuel cells. You can use small particles and exploit their large surface/volume ratio. But small particles are highly active, they move, react with each other to form larger particles, and, eventually, your electrode no longer works. Of course, there are tricks to stabilize small particles: one of the things I worked on was platinum alloys. At times, some of these alloys seemed to work little miracles. But the problem was that the miracle worked only for a while, then something happened, the alloy "de-alloyed" and the catalyst didn't work anymore. Not the right kind of behavior for something that you expect to work on a commercial vehicle for at least ten years.
Today, the problem has not been solved. I looked at a recent review on this subject and I saw that people are still struggling with the same problems I had when I worked as a young postdoc in Berkeley: reducing the platinum loading on the electrode by using alloys. I am sure that good progress has been made in nearly 40 years, but technological progress is subjected to diminishing returns, just like many human activities. You can move forward, but the farther you go, the more expensive it becomes -- to say nothing of the reliability problems of highly sophisticated technologies that deal with dispersed nanoparticles. And no way has been found, so far, to replace platinum with some other metal in low temperature fuel cells. Without a substitute for platinum, the hydrogen-based economy remains a pie in the sky.
Note also that the platinum supply is just one of the problems plaguing the idea of the "hydrogen economy." There are many others: storage, safety, durability, efficiency, energy return, and probably more. No surprise that I stopped believing in the idea. I became a "former hydrogenist," one of those people who had approached the hydrogen idea with plenty of hopes, but who soon became disillusioned.
That doesn't mean there don't exist niche markets for hydrogen as an energy storage technology, but fuel cells are still mainly used for prototypes or toys. There is one commercial hydrogen car, the Toyota Mirai, an expensive and exotic car in a world where lithium batteries provide the same performance at a much lower cost. Hydrogen powered planes are a possibility, but there are none flying today, likely because they are an engineering nightmare. Perhaps a good use for hydrogen could be powering marine vessels, although fuel cells may be too expensive for this purpose. As energy storage systems, coupling electrolysis and fuel cell systems may do the job, but they are more expensive than batteries and their efficiency is also much smaller.
So, what's left of the grand idea of a "Hydrogen Based Economy," the promise of a world both prosperous and clean? Very little, it seems to me. Nevertheless, nowadays, the idea seems to be enjoying a renaissance, at least in terms of the surrounding hype, this time with the label of "blue hydrogen." This is hydrogen that should be created from fossil fuels, while the carbon generated in the process should be captured and stored underground. Clearly, it is just a trick to make it possible for the fossil fuel industry to keep going for a while longer.
And why "blue" hydrogen? Ah.... well, that's the miracle of our times: propaganda. Just as we can have "colored revolutions" it seems that we can invent "colored technologies." We have also "green hydrogen" and "grey hydrogen" and the latest fad seems to be "green kerosene." Karl Rove had understood it so well when he said that "nowadays we create our own reality." It is so powerful that it can turn hydrogen blue and you can read here how this miracle was performed. But it will be harder to create platinum that is just not there. In the meantime, the hydrogen zombie keeps marching on!
Great that you at least mentioned the possibility of a few niche areas where hydrogen might still be useful. To my mind, it's good to leave a face-saving way out for proponents – something positive to keep hold of. I would agree with you – let's go for a completely redesigned fleet of hydrogen-powered aircraft, with air travel being fully costed and therefore very infrequent. And tie that into airships as the main, slower, form of air transport. I totally agree with your main premise: that everyone needs to recognise that we absolutely must drastically limit doing many of the things we are currently doing that consume energy or load the environment with CO2. Back to the idea of rationing both carbon and energy. Rationing as the most equitable form of distributing a scarce resource.
ReplyDeleteThe Ford Nucleon does not seem to have doors. How about the six-wheel Ford Seattle at https://i.redd.it/r9kncpl1jg401.jpg? At least it has a door. But why does it have four tail pipes? (Low-level waste?)
ReplyDeleteMany organizations have set a target of ‘Net Zero by 2050’. This means that all these good ideas, such as hydrogen fuel cell automobiles, have not only to work, but they have to be implemented world-wide within just 29 years. We hear a lot of calls on the lines of “listen to the scientists”. I would say, “listen to the project managers and engineers” — they will provide a reality check.
Some pictures show that you would lift the cockpit (?) to enter the car. It had only two seats! Sort of a waste for a nuclear reactor.
DeleteYes I too have been interested in alternative sources of energy and employ most of them but today I just used our draft horses for plowing a field, logging in the woods and them giving me a ride around the farm on horseback as I survey the land looking for the many plants that are appearing this spring. I have the solar cells, sunflower oil instead of diesel,a wood fired stove but nothing beats the horse that eats hay and works all day. -mat
ReplyDeleteI agree with your approach to energy and ways of using it, but your lovely horses can only deliver food (the ultimate end product of land-working) by the use of muscle power. Humankind needs for more than that for basic existence and ongoing survival.
DeleteYou don't say how big the field was.
I believe the origin of the 'acre' as a land area was rooted in old anglo Saxon as a reference to the area that could be ploughed before the ox team were exhausted. If you grow sunflower oil instead of diesel, then land must be set aside for that, as must several acres for horse feed.
I admire what you are doing, but let's not lose sight of the millions who can't do that.
From my perspective, The Seneca Effect was one of the most important books of the waning industrial era. It confirms the fundmental fact that the global industrial-consumer economy has already overshot the carrying capacity of the whole Earth System. The linear Newtonian model of economic development and growth allowed, for a time, the growth of the human population to reach far beyond the carrying capacity of the only viable habitat humanity will ever know--planet Earth.
ReplyDeleteThe unavoidable inference from the whole body of evidence on the human excessive use and waste of energy and materials is that the only path to a "sustainable" future is for networks of ecological communities to form in mutual aid to restore the ecosystems upon which they depend (thereby inherently resisting the globalized corporate state in ways mass protests cannot), in large part by refining and applying often old human and animal powered technologies to production of human necessities (and very few luxuries), thereby achieving a practical level of resilience that is impossible if attempted within the illusory eco-modernist ideology of "decoupling" endless economic growth from the disintegration of living Earth systems from which it has until now drawn its power.
Keep up your important work, but please find a publisher whose price for one of your books is less than the monthly payment on a giant gas guzzling SUV... Every literate person on the planet should read The Seneca Effect.
Best, RMC
Thank you - elaborate yet succinct. And somewhat giving the face saving opportunity to those that push the ‘solution’ to actually find the solution. In good time, I might add.
ReplyDeleteI am glad I found this blog. Besides the platinum problem, there is the problem of efficiently producing said hydrogen. As far as I know, electrolysis is the only real way to go, with an energy efficiency of order 70-80% under best case scenarios. Electrolyzers need an energy source.
ReplyDeleteBut where does the energy to break water comes from? Of all the renewables Photovoltaic has the best behavior because electrolyzers only work with reliable power sources (PV sometimes produces excess energy, which is well behaved and can readily be used to power an electrolyzers). Now I see the graph of Energy Return over Energy Invested at
https://consciousnessofsheep.co.uk/2020/10/26/lets-talk-croci/ (2nd figure)
and I wonder. (side note: the range for PV indicated in the figure seems to be a little low compared to a paper with Bardi among the authors, but much higher than a paper by Ferroni). The first thing I see is that PV is on an efficiency cliff and paying the electrolyzer efficiency will drop it down significantly.
But even without all the other problems, is there a way, even on paper, to turn a genuine renewable into hydrogen?
On paper: harvest a forest, Burn the wood in a big kiln; When the wood is all glowing charcoal, spray the char(coal) with water; C + H2O = H2 + CO ; separate the carbon monoxide off to use in a town gas supply; Cool and bottle the H2 ; While there is some glow left on the charcoal blow again with lots of air until it all glows white ; Repeat cycle until the forest is reduced to ash, CO2, CO, H2. Find another forest..........
ReplyDeleteCheers, the Walnutter
You are all (presumably) welcome to join this seminar on Green Hydrogen with https://www.zeroavia.com/ plus one other company.
ReplyDeletehttps://mailchi.mp/elementalexcelerator/celebrating-20-exits-the-road-beyond-net-zero-580204?e=f05fc96af4
One of the reasons we love H2 is that nothing but water comes out of the tailpipe. The cycle of water to fuel back to water is so clean. Imagine drinking what comes out of the tailpipe of your car. Why not look at H2 as a way to store intermittent power from renewables. Getting enough batteries to store excess electric power from a world of 100% renewables is another bottleneck (Ugo would know how much more abundant lithium is compared to platinum). But there are a lot of uses of H2 without catalysts. Just burn it to cook or to run an internal combustion engine, or to heat houses, etc. etc. Maybe the thing to abandon is the fuel cell, but the H2 is still a useful way to store sunlight that shortcuts the millions of years to make coal. Sunlight is abundant. So H2 can be abundant if PV panels can be cheap and numerous.
ReplyDelete