J 2024

Metal-organic framework composites for electrochemical CO2 reduction reaction

ADEGOKE, Kayode A., Joshua O. IGHALO, Jeanet CONRADIE, Chinemerem R. OHORO, James F. AMAKU et. al.

Basic information

Original name

Metal-organic framework composites for electrochemical CO2 reduction reaction

Authors

ADEGOKE, Kayode A., Joshua O. IGHALO, Jeanet CONRADIE, Chinemerem R. OHORO, James F. AMAKU, Kabir O. OYEDOTUN, Nobanathi W. MAXAKATO, Kovo G. AKPOMIE, Emmanuel Sunday OKEKE, Chijioke OLISAH (566 Nigeria, guarantor, belonging to the institution) and Alhadji MALLOUM

Edition

Separation and Purification Technology, Elsevier B.V. 2024, 1383-5866

Other information

Language

English

Type of outcome

Článek v odborném periodiku

Field of Study

20400 2.4 Chemical engineering

Country of publisher

Netherlands

Confidentiality degree

není předmětem státního či obchodního tajemství

References:

Impact factor

Impact factor: 8.600 in 2022

Organization unit

Faculty of Science

DOI

UT WoS

001210981100001

Keywords in English

Anthropogenic activities; CO2 reduction reaction; Electrocatalyst; Metal-organic framework composites; Environmental sustainability

Tags

Tags

International impact, Reviewed
Změněno: 14/6/2024 10:43, Mgr. Marie Šípková, DiS.

Abstract

V originále

Carbon dioxide (CO2) levels in the atmosphere are quickly increasing as a consequence of anthropogenic activities, which present grave hazards and dangerous circumstances to not only humanity but also the ecosystem. Currently, electrochemical CO2 conversion to chemical/fuels remains one of the best methods for minimizing CO2 concentrations. Metal-organic frameworks (MOFs) composite materials have been considered as new class of highly-performed electrocatalysts for CO2 reduction reaction (CO2RR) due to their wide surface area, higher porosity, chemical tunability and excellent stability. This article presents major approaches for electrochemical CO2RR to value-added product. These were followed by discussing the recent advancements in MOF composite electrocatalysts for CO2RR including active sites MOF-supported electrocatalysts, metal-nanoparticlessupported MOFs, conductive supported MOFs composites, and polyoxometalate-based MOF composites. Lastly, some challenges currently facing MOF composites for CO2RR as well as anticipated future advances were discussed. Research hotspot lies in the creation of highly effective CO2RR electrocatalyst such as ligand engineering in MOFs. It is believed that the current study will contribute to accelerating the fabrication of efficient MOF composite materials for abating the CO2 emission in the ecosystem and to highlight the necessity for further research to address significant environmental sustainability concerns.