Moisture- driven carbonation kinetics for ultrafast CO2 mineralization
成果类型:
Article
署名作者:
Gao, Yining; Tao, Yong; Li, Gen; Shen, Peiliang; Pellenq, Roland J. M.; Poon, Chi Sun
署名单位:
Hong Kong Polytechnic University; Hong Kong Polytechnic University; Ecole nationale superieure de chimie de Montpellier; Centre National de la Recherche Scientifique (CNRS); Universite de Montpellier; Universite de Montpellier
刊物名称:
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
ISSN/ISSBN:
0027-9693
DOI:
10.1073/pnas.2418239121
发表日期:
2025-01-07
关键词:
dioxide
storage
accurate
DYNAMICS
capture
water
摘要:
CO2 mineralization, a process where CO2 reacts with minerals to form stable carbonates, presents a sustainable approach for CO2 sequestration and mitigation of global warming. While the crucial role of water in regulating CO2 mineralization efficiency is widely acknowledged, a comprehensive understanding of the underlying mechanisms remains elusive. This study employs a combined experimental and atomistic simulation approach to elucidate the intricate mechanisms governing moisture- driven carbonation kinetics of calcium- bearing minerals. A self- designed carbonation reactor equipped with an ultrasonic atomizer is used to meticulously control the water content during carbonation experiments. Grand Canonical Monte Carlo simulations reveal that maximum CO2 uptake occurs at a critical water content where the initiation of capillary condensation significantly enhanced liquid-gas interactions. This phenomenon leads to CO2 adsorption-driven ultrafast carbonation at an optimal moisture content (0.1 to 0.2 g/g, water mass ratio to total wet mass of the mineral). A higher moisture content decimates the carbonation rate by crippling CO2 intake within mineral pores. However, at exceptionally high moisture levels, the carbonation reaction sites shift from internal mesopores to the grain surface. This results in surface dissolution-driven ultrafast carbonation, attributed to the monotonically decreasing free energy of dissolution with increasing surface water thickness, as revealed by metadynamics simulations. This study provides a fundamental and unified understanding of the multifaceted role of water in mineral carbonation, paving the way for optimizing ultrafast CO2 mineralization strategies for global decarbonization efforts.