Hang Xiao scite author profile

The urgency to address global climate change induced by greenhouse gas emissions is increasing. In particular, the rise in atmospheric CO2 levels is generating alarm. Technologies to remove CO2 from ambient air, or “direct air capture” (DAC), have recently demonstrated that they can contribute to “negative carbon emission.” Recent advances in surface chemistry and material synthesis have resulted in new generations of CO2 sorbents, which may drive the future of DAC and its large‐scale deployment. This Review describes major types of sorbents designed to capture CO2 from ambient air and they are categorized by the sorption mechanism: physisorption, chemisorption, and moisture‐swing sorption.

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Capture CO₂ from Ambient Air Using Nanoconfined Ion Hydration

Shi

et al. 2016

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Water confined in nanoscopic pores is essential in determining the energetics of many physical and chemical systems. Herein, we report a recently discovered unconventional, reversible chemical reaction driven by water quantities in nanopores. The reduction of the number of water molecules present in the pore space promotes the hydrolysis of CO3(2-) to HCO3(-) and OH(-). This phenomenon led to a nano-structured CO2 sorbent that binds CO2 spontaneously in ambient air when the surrounding is dry, while releasing it when exposed to moisture. The underlying mechanism is elucidated theoretically by computational modeling and verified by experiments. The free energy of CO3 (2-) hydrolysis in nanopores reduces with a decrease of water availability. This promotes the formation of OH(-), which has a high affinity to CO2 . The effect is not limited to carbonate/bicarbonate, but is extendable to a series of ions. Humidity-driven sorption opens a new approach to gas separation technology.

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Moisture-Driven CO2 Sorbents

Shi

Xiao

Kanamori

et al. 2020

Joule

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An energy-saving sorbent is proposed to capture CO 2 from ambient air simply by controlling the amount of water (moisture) in contact with it. The system binds CO 2 from the air when the surrounding is dry, whereas it desorbs CO 2 when it is wet. Various microporous and ion-exchange materials can be employed in subsequent studies. The study sheds light on ways to optimize an efficient direct air capture system and therefore contributes to the development of ''negative emission technologies.''

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Hang Xiao

Sorbents for the Direct Capture of CO₂ from Ambient Air

Capture CO₂ from Ambient Air Using Nanoconfined Ion Hydration

Moisture-Driven CO2 Sorbents

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About

Hang Xiao

Sorbents for the Direct Capture of CO2 from Ambient Air

Capture CO2 from Ambient Air Using Nanoconfined Ion Hydration

Moisture-Driven CO2 Sorbents

Contact Info

Product

Resources

About

Sorbents for the Direct Capture of CO₂ from Ambient Air

Capture CO₂ from Ambient Air Using Nanoconfined Ion Hydration