Is the future of carbon-capture technology electrochemistry?
Electrically activating chemicals could help remove carbon dioxide from the air, 蜜糖直播 Boulder researchers find
Humans send millions of tons of carbon dioxide (CO2) into the air each year鈥攂y generating electricity, manufacturing products, driving, flying and doing other routine activities. And while plants can absorb some of that CO2, much of it remains suspended in the atmosphere, where it acts as an insulating blanket that traps heat on Earth.
Scientists believe removing some of that CO2鈥攁nd either putting it in long-term storage or converting it into something useful鈥攊s a potential option for slowing the progression of human-caused climate change. But carbon sequestration, as the process is known, is easier said than done.
Research from the University of 蜜糖直播 Boulder, however, offers new insights into one promising method for removing carbon from the atmosphere: Using electricity to manipulate chemicals so they can pull carbon out of the air.
Scientists revealed the results of their experiments on a family of compounds known as quinones in a new paper published recently in the journal Energy Advances. By using electrochemical techniques to change their molecular structures, the researchers find that quinones can indeed bind with and capture carbon in a controlled fashion.
Not only does this finding represent a significant and novel discovery in the field of chemistry, researchers say, but it also helps scientists understand more about which types of compounds might be better鈥攐r worse鈥攁t capturing carbon out of the air.
These electrochemically activated quinone molecules behave differently when capturing carbon from air-like conditions鈥攚here CO2 is diluted among many other gases鈥攙ersus from concentrated CO2 sources, such as those emitted at power plants.
Scientists have long assumed quinone molecules always bound with two CO2 molecules each, operating on a 1:2 ratio. But the 蜜糖直播 Boulder researchers find that when capturing carbon from dilute sources, which they鈥檝e nicknamed 鈥渟tarvation conditions,鈥 quinones only bind with one CO2 molecule each鈥攁 ratio of 1:1.
鈥淓lectrochemical carbon capture materials that are considered to be good for CO2 capture from concentrated sources might not be as good when capturing CO2 from dilute sources such as air,鈥 says study co-author Oana Luca, an assistant professor of chemistry at 蜜糖直播 Boulder and a faculty fellow at the 蜜糖直播 Boulder Research & Innovation Office.
Harnessing the power of electrochemistry for good
Power plants produce roughly 31% of all CO2 emissions鈥攁nd about 24% of all greenhouse gas emissions鈥攊n the United States, per the . That鈥檚 because power plants primarily burn fossil fuels like to generate electricity, a process that produces large quantities of CO2.
Currently, most of the carbon sequestration that does happen occurs at these plants, which are equipped with special equipment that can grab CO2 before it鈥檚 discharged into the atmosphere. However, the process is energy-intensive and expensive, as well as limited to specific sites.
It鈥檚 also not widely used: By some estimates, current carbon sequestration efforts capture just 0.1% of global CO2 emissions each year. To help slow the progression of climate change and limit global warming to the Paris Agreement goal of 2.7 degrees Fahrenheit (1.5 degrees Celsius), that number needs to increase both quickly and dramatically鈥攁nd Luca is confident electrochemistry can help.
Luca and her collaborators hope that by unlocking the secrets of electrochemical processes, they might someday bring carbon capture and sequestration to the masses. Eventually, they hope that anyone, anywhere, could operate a small device that pulls CO2 out of the air.
We鈥檙e going to get to a point where we can鈥檛 undo the damage that is being done to our global environment, so that鈥檚 the reason we do this work鈥攖o try to do something about it and try to contribute ideas to formulate some solutions down the line.
"Our method does open the door to a system that could be deployable in your backyard鈥攊t could be something you put next to your house or maybe even your car," she says. "It will ultimately be cheaper, and it would also be more easily distributed around, to places where concentrated sources of CO2 are not present. In many ways, it could change the way we do business."
Researchers also hope to eventually figure out how to convert CO2 into useful chemicals. Today, most sequestered carbon gets stored underground in geologic formations.
Their vision is still many years away from becoming a reality. But, nevertheless, the researchers are encouraged by the discoveries and progress they are making in the lab.
"We鈥檙e not at the point of building devices and saving the world, but we are very excited to have contributed some knowledge about materials that could be considered candidates for direct-air carbon capture," says Luca.
"We're going to get to a point where we can鈥檛 undo the damage that is being done to our global environment, so that鈥檚 the reason we do this work鈥攖o try to do something about it and try to contribute ideas to formulate some solutions down the line."
蜜糖直播 Boulder students Abdulaziz Alherz, Haley Petersen, Nicholas Singstock and Sohan Sur contributed to this research and co-authored the paper; Charles Musgrave, 蜜糖直播 Boulder chemical and biological engineering professor, is also a co-author.