Enhanced photothermal conversion in 3D stacked metal–organic framework nanosheets
Shan Zhu,
Chuanhui Huang,
Xiao Li,
Xiangyu Chen,
Haochen Ye,
Zhenjie Xue,
Wenping Hu,
Tie Wang
Affiliations
Shan Zhu
Tianjin Key Laboratory of Molecular Optoelectronic ScienceDepartment of ChemistrySchool of ScienceTianjin UniversityTianjin People's Republic of China
Chuanhui Huang
Center for Advancing Electronics Dresden (Cfaed) and Faculty of Chemistry and Food ChemistryTechnische Universität DresdenDresdenGermany
Xiao Li
Tianjin Key Laboratory of Life and Health DetectionLife and Health Intelligent Research InstituteTianjin University of TechnologyTianjin People's Republic of China
Xiangyu Chen
Tianjin Key Laboratory of Life and Health DetectionLife and Health Intelligent Research InstituteTianjin University of TechnologyTianjin People's Republic of China
Haochen Ye
Tianjin Key Laboratory of Life and Health DetectionLife and Health Intelligent Research InstituteTianjin University of TechnologyTianjin People's Republic of China
Zhenjie Xue
Tianjin Key Laboratory of Life and Health DetectionLife and Health Intelligent Research InstituteTianjin University of TechnologyTianjin People's Republic of China
Wenping Hu
Tianjin Key Laboratory of Molecular Optoelectronic ScienceDepartment of ChemistrySchool of ScienceTianjin UniversityTianjin People's Republic of China
Tie Wang
Tianjin Key Laboratory of Life and Health DetectionLife and Health Intelligent Research InstituteTianjin University of TechnologyTianjin People's Republic of China
Abstract Incorporating metal nanoparticles (MNPs) in metal–organic frameworks (MOFs) demonstrated great potential in the field of photo‐/photothermal‐catalysis. However, the oriented design and optimization of the 3D nano‐architectures of MOF substrates to achieve high‐efficiency light harvesting remains a challenge. Herein, guided on theoretical simulation, a facile etching strategy was employed to fabricate a 3D orderly‐stacked‐MOF‐nanosheet‐structure (CASFZU‐1) with a high electric field energy‐density‐distribution; well‐dispersed MNPs were afterwards encapsulated onto the MOF support. The unique nanosheet structure improved the light absorbance over the broadband spectrum, thereby enhancing the plasmonic photothermal effects of the MNPs@CASFZU‐1 composites. Based on the plasmon‐driven photothermal conversion, the MNPs@CASFZU‐1 composites exhibited approximately twofold catalytic efficiency in the hydrogenation reaction and a lower temperature for the full conversion of carbon monoxide, compared to their bulk‐type composites. The surface‐plasmon‐driven photothermal effects can be exploited in innovative MNPs@MOF platforms for various applications.
