This story was originally published by Grist and has been republished here as part of the Climate Desk collaboration. Full disclosure: Earthjustice is an advertiser with Grist, but advertisers have no role in Grist’s editorial decisions.
As countries around the world firm up their commitments to cut carbon emissions, many are turning to an emerging solution with an uncertain future: hydrogen gas. This lesser-known fuel has been called the “Swiss Army knife” of climate solutions. It has the potential to replace fossil fuels in industrial processes, transportation, buildings, and power plants, and does not emit any greenhouse gases when it’s burned.
But this idea of an emissions-free, hydrogen-fueled world is a long way off. Currently, hydrogen is primarily used by oil refineries and in the production of fertilizer. Today, 99 percent of the world’s supply of hydrogen is made from natural gas and coal, producing annual emissions on par with those of the United Kingdom and Indonesia combined, according to the International Energy Agency.
Scaling up cleaner ways to produce hydrogen and new ways to use it will require significant investments in research and development, and likely subsidies or a price on carbon to make hydrogen competitive with fossil fuels. The Biden administration is starting down this path, with a goal to cut the cost of clean hydrogen by 80 percent by 2030. The bipartisan infrastructure bill that passed the Senate in early August allocates $8 billion to create four “clean hydrogen hubs” that would demonstrate its production and use in four different applications.
But with the clock ticking to prevent climate impacts from getting worse, experts are debating whether chasing after clean hydrogen for every possible use is wise. Some climate advocates are worried that it risks taking attention and resources away from technologies that are already available and could cut emissions more quickly. For example, natural gas utilities say they eventually want to deliver clean hydrogen to people’s homes to power their heaters and stoves, but electric heating and cooking appliances that can be powered by renewable electricity are already on the market now.
“We’re really rooting for hydrogen to work,” said Sasan Saadat, a senior research and policy analyst at the environmental nonprofit Earthjustice. “But we don’t want to be wasting this resource in ways just to ensure there’s a longer life for the business model of combustion-based energy incumbents.” Saadat is one of the authors of a recent report that distinguishes between the most promising “least-regrets” ways to use clean hydrogen and areas where policymakers should forget hydrogen and pursue other solutions.
It’s a complicated debate that turns more on politics, money, and time than it does on technology. None of the experts Grist spoke with disagreed that there’s a stronger case for using hydrogen to decarbonize some activities than others. But several said it was too early to rule out its widespread potential.
“It is reasonable to ask how people should spend taxpayer money in the most productive way,” said Julio Friedmann, a senior research scholar at Columbia University’s Center on Global Energy Policy. “But at the same time, we’re trying to do something so unprecedented and difficult that I think it is premature to amputate emerging ideas and options.”
To wrestle with these arguments, it’s important to understand clean hydrogen’s central challenge. Unlike fossil fuels, it cannot be dug out of the earth. We have to make it. And no matter how it’s made, energy is lost in the process.
Unlike the hydrogen produced with natural gas or coal today, so-called green hydrogen is made by zapping a water molecule with renewable electricity, splitting it into hydrogen and oxygen. With existing technology, this results in a loss of 20 to 40 percent of the initial energy. That loss jacks up the price of green hydrogen, making it harder for it to compete with other sources of energy. It also means that relying on green hydrogen requires building a lot more wind and solar power than we might otherwise have to. Wind and solar projects already face challenges overcoming community opposition, and some countries have limited land availability to support renewables.
Another possibility is to add carbon capture technology to existing, natural gas–based hydrogen production to make so-called blue hydrogen. But this method requires additional energy to run the carbon capture and storage machinery. The potential climate benefits of blue hydrogen are also diminished, if not erased, by the fact that the natural gas system is rife with leaks that send the potent greenhouse gas methane into the atmosphere. Those leaks would have to be greatly reduced for the emissions math on blue hydrogen to equal “clean.”
So the biggest constraint on what we use clean hydrogen for is supply. But as hard as it will be to produce cleaner varieties of hydrogen, virtually all experts agree that it is necessary for at least one reason: fertilizer. “Our demand for fertilizer isn’t gonna go away,” said Rebecca Dell, director of the industry program at the ClimateWorks Foundation, a philanthropic group that supports climate solutions. “We need to move that to a clean process in the future, and there isn’t really a substitute process.”
Beyond fertilizer, there’s rough consensus that clean hydrogen is a strong contender to cut emissions from many of the “hard to decarbonize” parts of the economy—activities that cannot easily be powered by clean electricity. These include long-haul trucking, shipping, aviation, and steelmaking. Hydrogen company Air Liquide, which produces both fossil fuel–based and renewable energy–based hydrogen, told Grist that producing hydrogen at scale for these uses “will then allow nascent segments to emerge and thrive.”
“Looking at end uses one by one without considering the entire system would not allow each and any of them to benefit from one another,” spokesperson David Asselin said.
But Sara Gersen, a lawyer for Earthjustice and co-author of the organization’s recent report on the potential for hydrogen technology, said she sees a disconnect between these more clear-cut cases for clean hydrogen and the ones the fossil fuel industry is lobbying for, like burning it in power plants.
“Utilities and project proponents are trying to get approval for new fossil gas plants under the guise of, ‘oh, maybe one day, this could be converted at some unknown cost to operate on green hydrogen,’ ” she said. The report mentions Danskammer, an upstate New York energy company that has proposed building a new natural gas–fired power plant and argued it is in line with climate goals because the plant will be capable of burning a blend of clean hydrogen and natural gas, which would lower emissions and could eventually be converted to run fully on hydrogen. Entergy Texas, an electric utility, recently made a similar proposal.
“We want policymakers to shut that down and say, ‘No, you need to take advantage of the clean energy solutions that are available today,’ ” said Gersen. Danskammer did not respond to Grist’s request for comment.
A key argument from hydrogen’s proponents is that it can make use of existing fossil fuel infrastructure, and in some cases, utilities are repurposing existing power plants to use hydrogen. In Utah, an old coal plant is being retrofitted to run on a blend of natural gas and clean hydrogen, with a goal of eventually using 100 percent clean hydrogen. New York state is testing blending at an existing natural gas plant in Long Island.
But blending hydrogen with natural gas is unlikely to significantly reduce carbon emissions in the near term. Jack Brouwer, director of the Advanced Power and Energy Program at the University of California–Irvine, where he conducts research on a broad range of hydrogen applications, told Grist that commercially available power plant technology can currently burn a blend of up to 30 percent hydrogen gas and 70 percent methane. According to a peer-reviewed study from 2019, a 30 percent hydrogen blend would only reduce the emissions from burning natural gas by about 12 percent.
Gas utilities are also proposing blending hydrogen into the natural gas delivered to homes and buildings. But much of the pipeline system in the U.S. is unable to carry more than about 20 percent hydrogen, if that much, because it damages the pipes. Higher loads of hydrogen would require utilities to replace their pipelines with different materials, likely passing those costs on to customers. Customers would also need to either modify their current appliances or buy new ones.
For Brouwer, blending green hydrogen into the natural gas system, whether for power plants or homes, is still very much worth doing—not so much for the greenhouse gas benefits, but to create a new market for solar and wind power. Right now, California has a problem where prices for solar energy are getting very low in the middle of the day at peak generation, which is discouraging the development of more solar in the state. If California set a green hydrogen blending mandate, for example, it would create more demand, since renewable energy is needed to make green hydrogen. But Brouwer said that blending clean hydrogen with natural gas is only a steppingstone. “The gas system has to be either eliminated or completely decarbonized,” he said.
Critics of hydrogen have another concern that has nothing to do with efficiency or economics or even climate change. While burning hydrogen in a power plant or furnace doesn’t emit greenhouse gases, it does emit nitrogen oxides, a pollutant that is harmful to human health. “We have this opportunity as we’re decarbonizing our economy to finally address the deep environmental injustices of burning fuel in power plants in communities that don’t benefit from the costs of low energy, but do bear the health costs of its pollution,” said Saadat.
However, Saadat and Gersen do believe clean hydrogen could be useful to the electricity grid via a different solution: hydrogen fuel cells. Fuel cells generate electricity through a chemical reaction rather than combustion, and do not produce pollution. They are much smaller systems than power plants and could be hooked up to the grid in an array, similar to grid-scale battery projects.
Gniewomir Flis, the hydrogen project manager at the Berlin-based think tank Agora Energiewende, said fuel cells are unlikely to be an option for at least a decade because at this point they are much more expensive than traditional combustion-based power plant technology. He also noted that the companies that build power plant technology are working to lower nitrogen oxide emissions, and that the industry has said it can solve this issue within the decade.
Whether for power plants or fuel cells, hydrogen can be stored underground in large quantities, much like natural gas, so many see it as a key tool to provide clean, long-duration backup electricity during seasons when there is less sun and wind to power the grid.
Perhaps the most controversial potential use for hydrogen is remaking our pipeline system to deliver it into homes and buildings. Flis called the idea of burning 100 percent hydrogen in buildings a “politically unpalatable solution.” By his analysis, since low-carbon hydrogen is so expensive, it would either mean handing enormous subsidies to utilities or raising customers’ rates by at least five times. Flis also estimates that in Europe, installing an electric heat pump would save a customer about $23,000 to $35,000 over the next 25 years compared with installing a hydrogen boiler.
Others, however, look at the challenge of fully electrifying buildings—and more or less forcing gas utilities to shutter—and find that politically unpalatable. “Yes, electric heating is much more efficient, but we need to consider the reality of abandoning massive infrastructure in place,” said Steve Griffiths, the senior vice president of research and development at Khalifa University in the United Arab Emirates, in an email.
Griffiths stressed that many other reports have looked at the future of clean hydrogen and come to similar conclusions as Earthjustice. But he argued that these analyses lack context. “Techno-economic factors alone are not what will make hydrogen a key fuel for energy transitions,” he said, writing that social, cultural, and political factors also help or hinder energy system changes. Griffiths was the lead author of a recent review paper on hydrogen that took into account these other factors.
Michael Liebreich, an independent energy analyst and adviser, said home heating is the “front line in the hydrogen culture wars.” “There’s enormously heavy lobbying for hydrogen in heating,” he said, “because it would use the gas distribution network, and that’s a very expensive asset we built over many, many decades, and the companies who own it don’t want to walk away.”
In the U.K., where Liebreich lives, gas utilities have been promoting a full switch to hydrogen since at least 2016, when an industry-sponsored study found that the gas network in the city of Leeds could be converted to carry low-carbon hydrogen to homes at minimal cost to customers. By 2023, a heavily subsidized pilot program in a neighborhood in Scotland will be the first to deliver 100 percent green hydrogen to a network of about 300 homes. Participants will receive free appliances, and their gas bills will not go up for the duration of the pilot, which is set to run through 2027.
In the U.S., gas utilities in New York, Massachusetts, California, and other states have said that clean hydrogen could be part of a low-carbon fuel mix they could deliver to customers in the future to meet climate goals. They are banking on public acceptance of clean hydrogen and other lower-carbon gases, like biogas, for survival. “We don’t make money on molecules,” Jonathan Peress, the senior director of business strategy and energy policy at SoCalGas, a California gas utility, told Grist. “We make money by providing a transportation and delivery service to our customers.” SoCalGas is engaged in several partnerships to ramp up the use of hydrogen, including an initiative to make Los Angeles a hub for affordable green hydrogen. The company has proposed blending hydrogen into its gas network, but its application to the California Public Utilities Commission was dismissed in July for being incomplete.
Liebreich, who has famously ranked the potential uses of clean hydrogen into a “ladder” based on which he thinks are most likely to succeed, doesn’t see much of a future for hydrogen in buildings. But he also doesn’t see a problem with governments spending some money to support these kinds of trials, because a lot of learning will come out of it. “We’ll just come to some point when they’ll say, ‘We have tried to build 67,000 homes heated by hydrogen, we now have a much better understanding of the economics—it makes no sense at all,’ ” he said. “Or, ‘It makes sense only in these very small numbers of niches.’ ”
But for Gersen and Saadat, who have watched as companies like SoCalGas have fought policies that would speed up the switch to all-electric buildings, there’s simply no time to wait around and see whether clean hydrogen will work out.
“We are really eager to make sure that the vague promise that hydrogen might be available as a decarbonization technology in the future doesn’t derail the urgent investments that we need today,” said Gersen.
These kinds of trade-offs are difficult to suss out. There’s no guarantee that the $2 billion or so the U.S. might spend on a residential heating “clean hydrogen hub” would otherwise go to electrification or any other climate solution. Or that it’s possible to get a bill passed in D.C. right now that doesn’t involve throwing some bones to the fossil fuel industry.
But storms, droughts, wildfires, and other impacts of climate change are already intensifying. Carbon is accumulating in the atmosphere, and the emissions we can avoid today and over the next 10 years may be worth a lot more—in terms of lives lost, communities displaced, damages from natural disasters—than a breakthrough solution to cut emissions in 2030.