A stable covalent organic framework for photocatalytic carbon dioxide reduction

Zhiwei Fu; Xiaoyan Wang; Adrian M Gardner; Xue Wang; Samantha Y Chong; Gaia Neri; Alexander J Cowan; Lunjie Liu; Xiaobo Li; Anastasia Vogel; Rob Clowes; Matthew Bilton; Linjiang Chen; Reiner Sebastian Sprick; Andrew I Cooper

doi:10.1039/c9sc03800k

A stable covalent organic framework for photocatalytic carbon dioxide reduction

Chem Sci. 2019 Nov 21;11(2):543-550. doi: 10.1039/c9sc03800k. eCollection 2020 Jan 14.

Authors

Zhiwei Fu¹, Xiaoyan Wang¹, Adrian M Gardner², Xue Wang^{1

3}, Samantha Y Chong¹, Gaia Neri², Alexander J Cowan², Lunjie Liu¹, Xiaobo Li¹, Anastasia Vogel¹, Rob Clowes¹, Matthew Bilton⁴, Linjiang Chen^{1

3}, Reiner Sebastian Sprick¹, Andrew I Cooper^{1

3}

Affiliations

¹ Department of Chemistry and Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool L7 3NY , UK . Email: ssprick@liverpool.ac.uk ; Email: aicooper@liverpool.ac.uk ; Email: lchen@liverpool.ac.uk.
² Stephenson Institute for Renewable Energy , University of Liverpool , Chadwick Building, Peach Street , Liverpool L69 7ZF , UK.
³ Leverhulme Research Centre for Functional Materials Design , Materials Innovation Factory and Department of Chemistry , University of Liverpool , Oxford Street , Liverpool L7 3NY , UK.
⁴ Imaging Centre at Liverpool , University of Liverpool , Liverpool L69 3GL , UK.

Abstract

Photocatalytic conversion of CO₂ into fuels is an important challenge for clean energy research and has attracted considerable interest. Here we show that tethering molecular catalysts-a rhenium complex, [Re(bpy)(CO)₃Cl]-together in the form of a crystalline covalent organic framework (COF) affords a heterogeneous photocatalyst with a strong visible light absorption, a high CO₂ binding affinity, and ultimately an improved catalytic performance over its homogeneous Re counterpart. The COF incorporates bipyridine sites, allowing for ligation of the Re complex, into a fully π-conjugated backbone that is chemically robust and promotes light-harvesting. A maximum rate of 1040 μmol g^-1 h^-1 for CO production with 81% selectivity was measured. CO production rates were further increased up to 1400 μmol g^-1 h^-1, with an improved selectivity of 86%, when a photosensitizer was added. Addition of platinum resulted in production of syngas, hence, the co-formation of H₂ and CO, the chemical composition of which could be adjusted by varying the ratio of COF to platinum. An amorphous analog of the COF showed significantly lower CO production rates, suggesting that crystallinity of the COF is beneficial to its photocatalytic performance in CO₂ reduction.