Recent advances in CO2 capture and mineralization using layered double hydroxide-based materials: A review.

Abstract

The continuous release of substantial amounts of carbon dioxide (CO₂) to the atmosphere has resulted in numerous severe adverse effects. Several materials have been synthesized and utilized for CO₂ capture. One class of such materials is layered double hydroxides (LDHs), which have emerged as promising materials for CO₂ capture due to their tunable properties, high surface area, and excellent CO₂ adsorption capabilities. Although there are some review articles on CO₂ capture and conversion using various materials, there is still a notable lack of thorough reviews focusing on the utilization of LDH-based materials for CO₂ capture. Additionally, the field of CO₂ capture and mineralization using LDH-based materials is rapidly evolving, necessitating up-to-date comprehensive reviews to analyze, evaluate, and condense the dispersed information found in recently published research articles. Accordingly, this review article provides a comprehensive overview of recent advancements in CO₂ capture using LDH-based materials. After briefly introducing the topic, different synthesis protocols of LDH-based materials are briefly reviewed. Then, CO₂ capture using LDHs, calcined LDHs, impregnated LDHs, composites containing LDHs, amine functionalized LDHs, and during steam methane reforming, are thoroughly analyzed and discussed. Additionally, the effects of synthesis method and post treatment of LDH-based materials on CO₂ capture, effect of modification and functionalization on LDHs, and the effects of various process conditions including temperature, pressure, water vapor, and gas composition on the performance of CO₂ capture by LDH-based materials are reviewed. Limitations, challenges, obstacles, and remaining knowledge gaps are highlighted, and future research works to address them are proposed.