工作(物理)
工艺工程
环境科学
湿度
相对湿度
吸附
焦耳(编程语言)
焦耳加热
材料科学
降级(电信)
电加热
大气压力
还原(数学)
废物管理
理论(学习稳定性)
化学工程
大气模式
计算机科学
大气(单位)
再生(生物学)
自行车
制浆造纸工业
环境工程
作者
Kepler Petzall,Benjamin J. Rhodes,Yongqiang Wang,Teedhat Trisukhon,Hari Kukreja,S. Alexandra Lim,Phillip J. Milner,Alexander C. Forse
标识
DOI:10.1016/j.cej.2025.169247
摘要
As anthropogenic CO 2 emissions responsible for our changing climate continue to rise, new technologies are needed to reduce their impact. Direct Air Capture (DAC) is a developing technological solution whereby CO 2 is captured directly from ambient air and later released in a controlled manner for further use or storage. This work details the development of a new, simple methodology that allows DAC candidate materials to be tested quickly and reliably in real atmospheric conditions at lab-scale. Targeting facile and efficient initial materials screening the methodology presented uses Joule heating for material regeneration, a rapid heating technique we find can raise the temperature of activated carbon-based sorbents to over 100 °C in 10 s. Focussing on a KOH-impregnated activated‑carbon cloth (i-ACC-KOH) sorbent, we find a linear relationship between regeneration temperature and reversible CO 2 capacity, with a peak capacity of 100 ± 20 mmol kg −1 in low-humidity atmospheric conditions. Performance under high-humidity and long cycling experiments were also assessed, highlighting key inputs in providing a well-rounded picture of material capability. We employ our methodology to demonstrate: (i), the rapid kinetics of our Joule heating methodology with only 20–25 min per cycle (5–10 min desorption, 15 min adsorption); (ii), the impact of ambient humidity on the performance of i-ACC-KOH, identifying only a limited reduction in capacity (≈ 8 %) with relative humidity up to 60 %; and (iii), high material stability with respect to cycling, retaining 80 % of capacity across 847 capture/release cycles. Overall, our work establishes a facile, lab-scale methodology for testing DAC sorbents in a Joule heating regeneration cycle, probing basic kinetics, competitive adsorption and cycling stability, and can facilitate the initial development of improved sorbents for DAC. • New, simple Joule-heating analysis setup for Direct Air Capture materials screening • KOH-functionalised porous carbon provides rapid cycling, heating to 100 °C in 10 s • Low- and high-humidity effectively controlled and material assessment executed • Long timescale cycling experiment of over 800 cycles effectively probes degradation
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