通过金属有机框架/金属有机框架异质结增强可见光驱动制氢

Enhanced Visible-Light-Driven Hydrogen Production through MOF/MOF Heterojunctions.

作者信息

Kampouri Stavroula, Ebrahim Fatmah M, Fumanal Maria, Nord Makenzie, Schouwink Pascal A, Elzein Radwan, Addou Rafik, Herman Gregory S, Smit Berend, Ireland Christopher P, Stylianou Kyriakos C

机构信息

Laboratory for Molecular Simulations, Institute of Chemical Sciences and Engineering, École Polytechnique Fedérale de Lausanne (EPFL Valais), Rue de l'Industrie 17, Sion 1951, Switzerland.

Department of Chemistry, Oregon State University, Gilbert Hall 153, Corvallis, Oregon 97331-4003, United States.

出版信息

ACS Appl Mater Interfaces. 2021 Mar 31;13(12):14239-14247. doi: 10.1021/acsami.0c23163. Epub 2021 Mar 22.

DOI:10.1021/acsami.0c23163

PMID:33749235

Abstract

A strategy for enhancing the photocatalytic performance of MOF-based systems (MOF: metal-organic framework) is developed through the construction of MOF/MOF heterojunctions. The combination of MIL-167 with MIL-125-NH leads to the formation of MIL-167/MIL-125-NH heterojunctions with improved optoelectronic properties and efficient charge separation. MIL-167/MIL-125-NH outperforms its single components MIL-167 and MIL-125-NH, in terms of photocatalytic H production (455 versus 0.8 and 51.2 μmol h g, respectively), under visible-light irradiation, without the use of any cocatalysts. This is attributed to the appropriate band alignment of these MOFs, the enhanced visible-light absorption, and long charge separation within MIL-167/MIL-125-NH. Our findings contribute to the discovery of novel MOF-based photocatalytic systems that can harvest solar energy and exhibit high catalytic activities in the absence of cocatalysts.

摘要

通过构建金属有机框架（MOF）/MOF异质结，开发了一种增强基于MOF的体系光催化性能的策略。MIL-167与MIL-125-NH的结合导致形成具有改善的光电性能和有效电荷分离的MIL-167/MIL-125-NH异质结。在可见光照射下，无需使用任何助催化剂，MIL-167/MIL-125-NH在光催化产氢方面（分别为455 μmol h g与0.8 μmol h g和51.2 μmol h g）优于其单一组分MIL-167和MIL-125-NH。这归因于这些MOF适当的能带排列、增强的可见光吸收以及MIL-167/MIL-125-NH内的长程电荷分离。我们的发现有助于发现新型的基于MOF的光催化体系，这些体系可以收集太阳能并在没有助催化剂的情况下表现出高催化活性。

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通过金属有机框架/金属有机框架异质结增强可见光驱动制氢

Enhanced Visible-Light-Driven Hydrogen Production through MOF/MOF Heterojunctions.

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