Porous inorganic-organic material for removal of trace carbon dioxide from air or other gas streams
T2018-379 Adsorbent for carbon dioxide capture with low energy input for regeneration, and high adsorption capacity
46% of 2010 global greenhouse gas emissions came from electricity and heat production, or from fossil fuels burned for industrial use (EPA). A lot of effort has been put into research on CO2 capture by adsorbents or absorbents, in order to reduce these greenhouse gas emissions. Additionally, effective CO2 remediation from air is necessary to maintain habitable environments in confined environments such as submarines and spacecraft. Progress has been made in CO2 capture for these uses, however, current amine based solvents for absorption require high energy input to regenerate the solvent, and packed beds of zeolites and silica offer poor reliability and low CO2 removal efficiency. Currently, there is a need for an improved sorbent for CO2 capture that has a lower energy input for regeneration, while maintaining high efficiency of capture.
The Ohio State University researchers, led by Professor Casey Wade, have developed an adsorbent capable of CO2 capture. This adsorbent has a low energy requirement to regenerate the sorbent, while having a higher carbon dioxide capture efficiency than most other solid sorbents available today, and maintains a high adsorption capacity through many adsorption-desorption cycles.
- Coal power plants
- Natural gas power plants
- Fuel oil power plants
- Industrial energy production
- Submarine CO2 remediation
- Spacecraft CO2 remediation
- Lower energy input to regenerate sorbent compared to current amine based solvent absorption techniques
- Exhibits better reliability and CO2 removal efficiency than packed beds of zeolites and silica
- Maintains high adsorbent capacity through many adsorption-desorption cycles