NIST’s testing apparatus, first described in 2023 in the journal Industrial & Engineering Chemistry Research, is designed to put solid sorbents through their paces. Research chemist Jeffrey Manion, who helped create it, says it provides some of the “best-in-the-world measurements” to determine “exactly how well the material does in absorbing carbon.”
The newly built DAC plant in California can remove a maximum of 1,000 metric tons of CO₂ per year, the equivalent of removing roughly 200 cars from the road. But by 2050, the IEA predicts many more DAC facilities will be built with the combined ability to remove nearly 1 billion metric tons of CO₂ per year.
For the RGTMs—the first of which are expected next year—NIST researchers will test sorbents commonly used in the DAC industry.
Now, NIST aims to facilitate the development of this rapidly emerging technology that the International Energy Agency (IEA) says will be a “key technology” for combating global warming.
NIST scientists have developed a high-precision testing apparatus for benchmarking the performance of the materials, called sorbents, used in DAC plants to trap and remove carbon from the air.
“We need to scale this technology up by approximately six orders of magnitude to have the needed climate impact,” says Pamela Chu, coordinator of NIST’s Carbon Accounting and Decarbonization Program. “More research and development are needed to make this technology as efficient and economically viable as possible.”
More than 100 facilities designed to remove carbon dioxide (CO₂) from the atmosphere are in various stages of development around the world. In the United States, the first DAC plant opened last fall in Northern California. The U.S. Department of Energy is funding four more regional DAC hubs with billions of dollars in seed money.
To combat global warming, companies are building direct air capture (DAC) facilities worldwide to remove carbon from the atmosphere. The National Institute of Standards and Technology (NIST) has developed a new method for testing the materials used in these plants to capture carbon. The agency plans to release an early-stage reference material that the DAC industry can use to test equipment.
Global warming results when greenhouse gases, including carbon dioxide, methane, nitrous oxide, and fluorinated compounds, accumulate in the atmosphere. The gases absorb infrared radiation, leading to higher temperatures near the Earth’s surface.
“Many companies right now are developing new types of sorbents,” she says. “They will want to know they work in the lab before they scale up. These RGTMs will let them test their lab equipment and give them confidence in their measurements.”
There are natural methods for removing carbon from the air, such as planting trees and soil restoration. Still, scientists believe additional approaches will be needed to fight global warming.
NIST research chemist Elisabeth Mansfield says the agency might eventually develop SRMs for DAC sorbents but, at this point, is working to provide the fast-growing and highly competitive industry with reference material as quickly as possible.
Typically, DAC plants use giant fans to suck in air that is then pushed through a filter containing sorbents. When heated (or through another method), the sorbent material releases, or desorbs, the carbon. The carbon can be buried deep in the ground or repurposed for industrial uses such as concrete and synthetic fuels.
Companies will have the option of using the RGTMs to calibrate their equipment, making sure they get the same results as NIST does when they test materials. They can also use the materials as part of their research and development process, benchmarking the carbon-removal performance of their materials against NIST’s.
“Our test and the RGTMs will allow for the critical and impartial evaluation of new, emerging DAC materials and a more comprehensive understanding of their performance,” says NIST research chemist Sean McGivern. “We hope this will help advance the development of measurements and standards for the DAC industry.”
Published May 14, 2024, in NIST News.