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Light-triggered CO2 binding enables CO production in a cerium MOF

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Research area:ChemistryInorganic ChemistryCarbon dioxide utilization in catalysis

What the study found

The study found that a cerium-based metal–organic framework, Ce-UiO-66-NH2, can reversibly bind carbon dioxide after light exposure and then reduce it to carbon monoxide in water without sacrificial agents. The authors report that this happens through transient open Ce(III) sites, which are cerium sites in a +3 oxidation state that appear briefly after photoexcitation.

Why the authors say this matters

The authors say this work will promote the design of photocatalysts, which are light-driven catalysts, capable of synthesizing fuels from carbon dioxide. The study suggests that understanding how CO2 is bound and activated in the framework may help guide future catalyst design.

What the researchers tested

The researchers studied a cerium-based metal–organic framework called Ce-UiO-66-NH2, which includes an amino-functionalized linker. They used in situ infrared spectroscopy, X-ray absorption spectroscopy, electron paramagnetic resonance, and transient absorption spectroscopy to examine what happens after light exposure.

What worked and what didn't

Photoexcitation was reported to induce a ligand-to-metal charge transfer, creating transient open Ce(III) sites that bind CO2 in a μ-(η1-O)(η1-C) mode. This binding was reversible and was linked to photoreduction of CO2 to CO, with a reported CO production rate of 126 μmol·g–1·h–1 and 100% selectivity. The amine-containing framework outperformed the non-amine analogue, Ce-UiO-66, and benchmark catalysts reported to date.

What to keep in mind

The summary does not provide detailed experimental conditions beyond the use of water and light, or discuss limitations of the study. It also does not give a complete comparison set for the benchmark catalysts mentioned.

Key points

Ce-UiO-66-NH2 showed light-induced, reversible CO2 binding.
The framework converted CO2 to CO in water without sacrificial agents.
The reported CO production rate was 126 μmol·g–1·h–1 with 100% selectivity.
Spectroscopy showed transient open Ce(III) sites formed after photoexcitation.
The amine-functionalized MOF outperformed the non-amine analogue, Ce-UiO-66.

Disclosure

Research title:: Light-triggered CO2 binding enables CO production in a cerium MOF
Authors:: Shan Dai, Xiangdi Zeng, Moore, Benjamin, 1748-1816, Yuxiang Zhu, Yuhang Yang, Zi Wang, Lei Li, Te Wang, Ivan da Silva, Luke L. Keenan, Floriana Tuna, Daniel Lee, Sarah J. Day, Lucy K. Saunders, Martin Schröder, Sihai Yang
Institutions:: Beijing National Laboratory for Molecular Sciences, Diamond Light Source, Diamond Light Source, Diamond Light Source, Peking University, Rutherford Appleton Laboratory, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester, University of Manchester
Publication date:: 2026-03-10
DOI:: 10.1021/jacs.5c20721
OpenAlex record:: View

AI provenance: This post was generated by gpt-5.4-mini (OpenAI). The original authors did not write or review this post.