Abstract
Global warming, driven significantly by carbon dioxide (CO(2)) emissions, necessitates immediate climate action. Consequently, CO(2) capture is essential for mitigating carbon output from industrial and power generation processes. This study investigates the effect of absorbent temperature on CO(2) separation performance using gas-liquid polymeric hollow fiber membrane (HFM) contactors. It summarizes the relationship between liquid-phase temperature and CO(2) capture efficiency across various physical and chemical absorption processes. Twelve relevant studies (nine experimental, three mathematical), providing a comprehensive database of 104 individual measurements, were rigorously analyzed. Liquid-phase temperature significantly influences CO(2) separation performance in HFM contactors. In particular, the present analysis reveals that, overall, for every 10 °C temperature increase, physical absorption performance decreases by approximately 3%, while chemical absorption performance improves by 3%, regardless of other parameters. This empirical law was confirmed by direct comparisons with additional experimental results. Strategies for further development of these processes are also proposed.