Embedded Mo/Mn Atomic Regulation for Durable Acidity-Reinforced HZSM-5 Catalyst toward Energy-Efficient Amine Regeneration
Mingyue Li, Lei Xing, Zhongfei Xu, Zhengwei Liang, Tieyue Qi, Yuchen Li, Shihan Zhang, Lidong Wang
Abstract
Metal–molecular sieve composites with high acidity are promising solid acid catalysts (SACs) for accelerating sluggish CO 2 desorption processes and reducing the energy consumption of CO 2 chemisorption systems. However, the production of such SACs through conventional approaches such as loading or ion-exchange methods often leads to uncontrolled and unstable metal distribution on the catalysts, which limits their pore structure regulation and catalytic performance. In this study, we demonstrated a feasible strategy for improving the durability, surface chemical activity, and pore structure of metal-doped HZSM-5 through bimetallic Mo/Mn modification. This strategy involves the immobilization of Mo–O–Mn species confined in an MFI structure by regulating MoO 4 2– anions and Mn 2+ cations. The embedded Mn/Mo species of low valence can strongly induce electron transfer and increase the density of compensatory H + on the MoMn@H catalyst, thereby reducing the CO 2 desorption temperature by 8.27 °C and energy consumption by 37% in comparison to a blank. The durability enhancement and activity regulation method used in this study is expected to advance the rational synthesis of metal–molecular sieve composites for energy-efficient CO 2 capture using amine regeneration technology.