The short list of climate actions that will work
· 10 min read
I spend a lot of time critiquing solutions for low-carbon transformation, most recently the current hydrogen gold rush Europe is trying to start in northern Africa, and that leads, inevitably, to people asking me: what works? What should we be doing? A couple of years ago that came in the form of a question that was well enough formed to trigger me to write down the solution set: “What exactly is the current scientific consensus on steps to combat climate change?“
Consensus is an interesting word. I tend to prefer consilience, where multiple lines of investigation lead to the same conclusions. That said, the following are the solutions or approaches that I see from my investigations and discussions as gaining consensus and consilience. It’s not the how, but the what. There are many paths that lead to these realities. One way to read the following is to consider that it describes the world in 2050.
This list doesn’t necessarily map easily to Project Drawdown because its approach is a cost-benefit analysis of CO2e reductions for dollars, while this is a more aggressive transformational vision.
Convert all energy services to work directly from electricity instead of fossil fuels. Transportation, industry, and agriculture. All of it. All gas appliances must go. All road transport must be electric. Most trains and a lot of planes must shift to electric. Electricity creating biofuels or hydrogen for the small subset of transportation that can’t be electrified. All heat from electricity. The US throws away two-thirds of all primary energy, mostly in the form of waste heat from fossil fuels used in inherently inefficient combustion processes. We only have to replace a third of the actual primary energy we use today to maintain our lifestyle and economy.
All other forms of generation with the exception of nuclear were overbuilt, so we’ll do the same with wind and solar, and they are really cheap, so that is not that expensive. Also a bit of geothermal and some biomass. After all, only $3 trillion of renewables would provide all primary energy for everything the US does today.
And improve existing ones. High-voltage direct current (HVDC) became much more viable with high-speed hybrid circuit breakers in 2011, and is an essential technology for long-distance, low-loss electrical transmission. It can replace some AC transmission during upgrades and be buried along existing right-of-ways.
While storage of electricity is an overstated concern given overbuilt renewables and continent-scale grids, some is still required. Closed-loop, off-river, pumped hydro resource potential is far greater than the need, is efficient, and uses stable, known technologies. Shifting existing hydro-electric dams to be passive, on-demand storage as opposed to baseload is also key. Fast response grid storage can be provided by existing lithium-ion technologies, as Tesla has proven in California and Australia. Redox flow batteries will bridge lithium ion and pumped hydro. By 2050, we’ll have roughy 20 TWh of batteries on wheels in US cars alone, available both for demand management to reduce peak demand, soak up excess generation, and to provide some vehicle-to-grid electricity.
We have cut down about 50% of the six trillion trees that used to grow on earth. Planting a trillion trees would buy us a lot of time as they sucked about a ton of CO2 from the atmosphere per tree over 40 years.
High-tillage agriculture is a process that keeps releasing carbon captured by the soil back into the atmosphere. Switching to low-tillage farming would buy us a lot of time as the CO2 captured by farmland would stay in the soil a lot longer, and some of it would be permanently sequestered. Making precision agriculture universal and leveraging agrigenetics to tweak nitrogen fixing microbes and plants to mostly eliminate CO2e-heavy nitrogen fertilizers clears up the rest. Eliminate subsistence farming.
8% of global CO2 emissions come from making Portland cement. It’s absolutely critical to urban densification and industry, so we won’t stop making it. But it’s a huge source of CO2, about half from the energy and half from CO2 that bakes off limestone as it is turned into quicklime. Electrifying that energy flow helps a lot, but capturing that CO2 is one of the few places where mechanical carbon capture will make sense. Steel will mostly be fixed by aggressively turning internal combustion cars, refineries, pipelines and other fossil fuel infrastructure into new steel using electric minimills. 70% of North American steel is already made this way. And transform high-emitting industrial processes like bicarbonate manufacturing.
The simplest way to get a lot of people and industries to shift away from emitting lots of CO2 is to make it expensive. That’s what carbon taxes do.
Getting rid of coal is already happening, but it’s still by far the biggest single source of CO2 emissions. Aggressive actions to eliminate burning coal are needed. For gas, the question is how few gas plants can we build, how many of them can we run on biologically sourced methane and how fast can we shut them down.
Exploration, extraction and use, just cut it out. The US alone spends tens of billions of dollars annually on subsidies of various kinds for the fossil fuel industry, and hasn’t done a thing about it since committing to eliminate them in 2009. The G7 and G20 have committed to eliminating subsidies, but progress has been very slow. The World Bank continues to finance coal, oil, and gas projects, despite commitments to end them.
The Kigali Amendment to the Montreal Protocol on Substances that Deplete the Ozone Layer targets the unforeseen side effects of displacing ozone-depleting CFCs with high global warming potential HFCs. Project Drawdown puts this at #1 on its ranked list of solutions by cost vs benefit. The US has still not ratified this Amendment, although 131 other countries including China and India have.
That’s empirical reality, not an advocacy statement. The conditions for rapid build that existed in a couple of places and times in the past don’t exist today. And we need a lot of clean electricity very quickly. Nuclear need not apply. Keep existing nuclear running until it needs major upgrades, don’t stop new nuclear buildout in China — pretty much the only place building new generation capacity — but don’t expect it to be more than a rounding error in a few decades. New nuclear technologies including SMRs are decades from commercial deployment at any scale, and we have technologies that are reliable, predictable, cheap, and fast to build, so there will be nothing for new nuclear to do once it actually makes it out of R&D.
This is an overhyped fig leaf for the fossil fuel industry. Virtually every CCS site is actually an enhanced oil recovery site which recovers oil that couldn’t be pumped out before, typically enough that 2–3 times more CO2 is generated from the oil than was put underground. Exceptions are natural gas wells with too high a concentration of CO2, leading to 25 times the emissions once the natural gas is burned. Expensive, unscalable, and wasteful. As stated, flue carbon capture might be useful for concrete.
Solutions such as Carbon Engineering’s direct-air-capture with hydrogen electrolysis to create synthetic fuels is a broken model. It’s vastly more expensive and higher CO2 emitting than electrification or biological pathway fuel synthesis. Any money spent on this would have vastly better results if spent on renewables instead. It’s not an either-or, but in this case policy makers should ignore this and governments shouldn’t fund it.
Hydrogen hype is high in the 2020s, but the molecule is better understood as a climate change problem, not a climate change solution. We use about 120 million tons of black hydrogen annually, with CO2e emissions about a billion tons per year. The biggest user is in oil refineries to reduce sulphur in gas, diesel, kerosene and other petroleum products, and that’s going away. The second biggest use is in nitrogen fertilizers, and that has to diminish radically as well. The remainder must be served by green hydrogen, and there is little room for wasting energy by turning renewable electricity into an inefficient and ineffective fuel. Long-duration grid storage is best served by much more efficient and effective closed-loop, off-river pumped hydro and redox flow batteries.
The military requires vast amounts of high energy fuel in places with no electrical supply chain, often for months at a time. The US military is considered by many to be the single largest CO2 emitting organization in the world. However, eliminating global fossil fuel strategic military actions — which describes virtually everything done in the Middle East for the last 100 years — will diminish the need for the US military substantially. A great deal of its emissions, which hopefully will start coming to light as the US has re-entered the Paris Accord, were related to the Middle Eastern deployments. There’s only so much we can do for biofuels, but to be clear, the world has been in a period of diminishing military conflict since the end of WWII. Globalization may have downsides, but the ties of trade and treaties which bind countries together have been highly effective in allowing diplomacy pathways to work, and making the military option increasingly difficult to consider.
Where approaches or recommendations from people or groups diverge from the above, question what lobbying groups are involved, where revenue will be lost or gained and in general what the motivations of the people or organizations involved are. This is all empirically grounded analysis. It’s not rocket science.
We have the solutions. We just need the will to execute, which is being sapped by the losers in this necessary transformation, predominantly the fossil fuel industry.
A version of this article is also published in CleanTechnica and The Future is Electric. Energy Voices is a democratic space presenting the thoughts and opinions of leading Energy & Sustainability writers, their opinions do not necessarily represent those of illuminem.
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