Enhanced post-combustion CO2 capture and direct air capture by plasma surface functionalization of graphene adsorbent
Rahul Navik, Eryu Wang, Xiao Ding, Huang Yun-yi, Yiyu Liu, Jia Li
Abstract
N 2 /H 2 plasma treatment was applied for fabricating graphene-based adsorbent materials with enhanced post-combustion and direct air capture of CO 2 with a main focus on versatility and sustainability. Graphene has enormous potential to capture CO 2 due to its unique properties and cost-effectiveness. However, graphene-based adsorbents have drawbacks of lower CO 2 adsorption capacity and poor selectivity. This work demonstrates a one-step rapid and sustainable N 2 /H 2 plasma treatment process to prepare graphene-based sorbent material with enhanced CO 2 adsorption performance. Plasma treatment directly enriches amine species, increases surface area, and improves textural properties. The CO 2 adsorption capacity increases from 1.6 to 3.3 mmol/g for capturing flue gas, and from 0.14 to 1.3 mmol/g for direct air capture (DAC). Importantly, the electrothermal property of the plasma-modified aerogels has been significantly improved, resulting in faster heating rates and significantly reducing energy consumption compared to conventional external heating for regeneration of sorbents. Modified aerogels display improved selectivity of 42 and 87 after plasma modification for 5 and 10 min, respectively. The plasma-treated aerogels display minimal loss between 17% and 19% in capacity after 40 adsorption/desorption cycles, rendering excellent stability. The N 2 /H 2 plasma treatment of adsorbent materials would lower energy expenses and prevent negative effects on the global economy caused by climate change.