By Richard Heinberg
Human activity, mostly the burning of fossil fuels, has raised Earth’s atmospheric carbon content by 50 percent, from 280 parts per million to 420ppm. Since the start of the Industrial Revolution, we’ve released approximately 950 billion metric tons of carbon into the air.
Every year, humans emit more than 40 billion metric tons of carbon dioxide into the atmosphere, as of 2021 measurements. Even if we stop burning fossil fuels now, the amount of CO2 already in the atmosphere will cause Earth’s climate to continue warming for decades, triggering heatwaves, droughts, rising sea levels, and extreme weather.
Climate scientists warn that if we want to avert catastrophe, a significant amount of excess atmospheric CO2 must be captured and sequestered. The process is called carbon-dioxide removal (CDR), and it has been receiving more attention as nations, states and industries strive to meet their climate goals. But how should we go about doing it?
There are two broad strategies: biological and mechanical.
Nature already absorbs and emits about 100 billion metric tons of carbon dioxide every year through the natural processes in the biosphere, including plant growth, an amount 2.5 times humanity’s annual carbon output. So, according to advocates for biological carbon removal, our best bet is simply to help the planet do a little more of what it is already doing to absorb carbon.
We could accomplish this through reforestation, soil-building agricultural practices, and encouraging kelp growth in oceans.
On the other hand, advocates for mechanical carbon removal point to technologies that successfully capture CO2 in the laboratory; if these machines were scaled up, those advocates tell us, we could create an enormous new industry with plenty of jobs while removing atmospheric carbon and reducing climate risk.
Scientists are exploring several chemical pathways for direct air capture (DAC) of carbon and ways to sequester CO2 in porous rock formations. Revenue streams come from government subsidies or from the use of captured CO2 in enhanced oil recovery (EOR).
So, which pathway—nature or machines—holds more promise?
In its sixth assessment report, released in March, the Intergovernmental Panel on Climate Change (IPCC), the United Nations body that regularly assesses the current state of climate science, points out that “biological CDR methods like reforestation, improved forest management, soil carbon sequestration, peatland restoration and coastal blue carbon management can enhance biodiversity and ecosystem functions, employment and local livelihoods.”
On the other hand, notes the IPCC, the implementation of mechanical DAC along with underground sequestration of CO2 “currently faces technological, economic, institutional, ecological-environmental and socio-cultural barriers.” Further, the current global rates of mechanical carbon capture and storage “are far below those in modeled pathways limiting global warming to 1.5-2 degrees Celsius.”
In a study published in the journal PLOS Climate in February, a team of American scientists analyzed the benefits and downsides of the two pathways in detail.
They used three criteria: effectiveness (“does the process achieve a net removal of CO2 from the atmosphere” once all inputs and outputs are accounted for?), efficiency (“at a climate-relevant scale … [of a billion metric tons of CO2 per year], how much energy and land are required?”), and impacts (“what are the significant co-benefits or adverse impacts [on nature and society]?”).
The team gathered data and crunched the numbers. The lead author, June Sekera, a carbon researcher and visiting scholar at the New School for Social Research in New York, concluded:
“Biological sequestration methods, including restoration of forests, grasslands, and wetlands and regenerative agriculture, are both more effective and more resource efficient in achieving a climate-relevant scale of CO2 removal than are techno-mechanical methods—which use machinery and chemicals to capture CO2.
“Additionally, the co-impacts of biological methods are largely positive, while those of technical/mechanical methods are negative. Biological methods are also far less expensive.”
In this comparative study, the scores for natural versus mechanical carbon removal methods were not close: Natural methods won in every category, and by a significant margin. The problem with machine-based carbon removal is not just that current technologies are immature (with the hope of getting better with more research and investment), but also that using machines is inherently inefficient, costly, and risky. On the other hand, removing carbon by restoring nature costs less, is more effective at reducing atmospheric carbon, and offers numerous side benefits.
The American study also noted that its findings “that biological methods exhibit superior effectiveness in comparison to DAC are consistent with data reported in the 2022 IPCC study.” It added in plain terms: “According to the IPCC, not only are biological methods of CDR more effective than DAC … but their effectiveness is projected to increase significantly over time.”
As if to underscore that conclusion, a separate study published in March in the journal Nature Climate Change concluded that the protection and rewilding of even a small targeted group of wildlife species would help facilitate the capture and storage of enough carbon to keep the global temperature below the tipping point of warming 1.5 degrees Celsius above pre-industrial levels.
You might expect, therefore, that policymakers would currently be directing all of their support toward natural carbon removal methods. But you’d be wrong. Government policy support in the form of subsidies is being shoveled mostly into mechanical carbon removal.
Researchers continue to spend time and money finding new chemical pathways to mechanical CO2 capture—resources that could instead be diverted to biological CO2 removal methods.
There are also subsidies that, in effect, promote nature-based CDR methods, including soil conservation and wetlands restoration programs, but these programs were not initially intended for carbon capture and sequestration, and they are not optimized for that purpose.
In November 2022, at the global COP27 climate summit in Cairo, the US government announced the “Nature-Based Solutions Roadmap,” an outline of strategic recommendations to put America on a path to “unlock the full potential of nature-based solutions” to address “climate change, nature loss, and inequity.”
The roadmap calls for updating policies, providing funding, training a nature-based solutions workforce, and prioritizing research, innovation, knowledge, and adaptive learning to advance nature-based solutions. However, the roadmap remains, for the most part, in the realm of good intentions.
There’s only so much funding available for climate solutions, and the total amount is woefully inadequate. Only strategic investment will obtain significant results for the dollars spent, and it is now clear which path will get results.
Given the clear superiority of nature-based solutions, why is so much support still going toward mechanical carbon capture? Poor judgments in the past have created funding streams and projects with a momentum of their own. Most of the gold-rush fever surrounding mechanical carbon capture can be attributed simply to the lure of subsidies for building new DAC plants and pipelines.
In a 2018 article published by the Thomson Reuters Foundation, Justin Adams, who at the time was the managing director for global lands at the US-based environmental non-profit Nature Conservancy, urged the European Union to take the lead on using nature-based solutions in the climate crisis fight.
“Many economists and policy advisers ignore the potential of natural climate solutions at our peril,” Adams’ article warned, calling a 2018 report by the European Academies’ Science Advisory Council (EASAC) “shortsighted” for playing down the potential of nature-based climate solutions.
“Natural climate solutions are in fact the world’s oldest negative emissions technology,” Adams wrote. “By managing carbon-dioxide-hungry forests and agricultural lands better, we can remove vast quantities of greenhouse gases from the atmosphere and store them in trees and soils.”
The science tells us that policymakers and investors have so far been wrong to advocate so strongly for mechanical CDR solutions to the detriment of biological ones. The fate of future generations is at stake, and we cannot afford to waste both time and money on techno-fixes that are ineffective at achieving our climate goals.
The clear path forward to addressing the looming catastrophic effects of climate change is to restore nature.
Richard Heinberg is a senior fellow at the Post Carbon Institute and the author of Power: Limits and Prospects for Human Survival.
Source: asiatimescom, May 23, 2023. This article was produced by Earth | Food | Life, a project of the Independent Media Institute.