FOR IMMEDIATE RELEASE
November 15, 2023
CONTACT: Tommy Jaime, 608-265-6175, tjaime@lafollette.wisc.edu
As policymakers, researchers and climate activists from around the world prepare to meet for the UN Climate Change Conference beginning on November 30, 2023, one lingering question is if climate technology is developing and scaling quickly enough to meet the demands of the Paris Agreement. Two new studies led by one of the leading scholars on climate technology can help inform discussions around the scaling of carbon dioxide removal technologies.
MADISON, Wis., – The rate of development for carbon dioxide removal (CDR) technologies that could be critical tools to combat climate change is in line with similar technologies over the last century but outpaced by policy targets and industry projections, according to a new study led by Professor Gregory Nemet of the La Follette School of Public Affairs at the University of Wisconsin–Madison.
Another new study led by Nemet finds that novel CDR methods need to scale at a much faster rate to meet the Paris Agreement’s temperature goal of limiting warming to 2 or 1.5 degrees Celsius, which would require removing hundreds of gigatons of carbon dioxide from the atmosphere over the course of the century.
CDR involves capturing CO2 from the atmosphere and storing it in a variety of ways. Examples of conventional CDR include reforestation, wetland restoration and improved forest management. All other CDR methods have only been deployed at small scale and are collectively known as novel CDR. Examples include bioenergy with carbon capture and sequestration (BECCS), direct air carbon capture and storage (DACCS), and biochar.
An innovative database puts CDR in historical context
In their paper published October 30, 2023, in Communications, Earth & Environment, Nemet and his research team debut the Historical Adoption of TeCHnology (HATCH) dataset—an innovative project that tracks and analyzes a variety of agricultural, industrial, and consumer technologies adopted over the past century that can provide insight into the scale-up of new technologies such as carbon removal.
The study analyzed the emergence and growth of 148 technologies across 11 categories going back to the early 20th century. It then cross-referenced this data with model CDR scenarios established by the Intergovernmental Panel on Climate Change (IPCC), company announcements of CDR scale-up plans, and CDR targets in policy announcements.
While the paper found evidence that the required scale-up of carbon removal technologies fits within the historical range of previous efforts, company announcements and government targets implied much faster growth than the historical record and IPCC CDR scenarios.
“The scale-up rates needed for carbon removal to meet the 2- and 1.5-degree Celsius targets are within the range of historical experience, even if at the high end,” says Nemet. “We can learn from that experience to facilitate getting carbon removal to climate-relevant scale over the next three decades.”
Novel CDR must scale rapidly to reach net zero CO2 emissions by 2050
In their paper published November 15, 2023, in Joule, Nemet and his research team find that 2 gigatons of carbon dioxide removal per year is taking place currently, with nearly all of it from forestry and only 0.1% from novel CDR.
This is all despite modeling scenarios that show that we need to remove hundreds of gigatons of carbon dioxide from the atmosphere over the course of the century to meet the Paris Agreement and ensure the sustained wellbeing of our planet.
The study finds that virtually all scenarios that limit warming to 1.5 or 2 degrees Celsius require novel CDR. On average, scenarios increase novel CDR by a factor of 1,300 by mid-century.
By looking at the formative phase of technologies similar to DACCS, the paper’s results suggest that the formative phases for DACCS and other novel CDR methods must accelerate to meet the needs of a warming planet. The formative phase of a technology takes place between first commercialization and rapid scale-up. Case studies of innovation show the importance of this period in technology adoption.
“To become climate relevant, the formative phases for air filter systems and other novel methods of carbon removal need to be at least as active as the fastest historical analogues,” says Jan Minx, head of the MCC working group Applied Sustainability Science and a co-author of both studies. “This will require more serious commitments toward novel removal technologies than are currently in place. The required levels will only be feasible if we see substantial development of novel CDR’s formative phase in the next 15 years.”
The results of these studies will also be included in the forthcoming 2023 UN Emissions Gap Report, which includes a chapter on carbon removal with contributions by Minx and Nemet.