Substantially improved efficiency and selectivity of carbon dioxide reduction by superior hydrated electron in microdroplet.

Authors

Qiuyue Ge, Yangyang Liu, Wenbo You, Yumo Li, Wei Wang, Le Yang, Lifang Xie, Kejian Li, Licheng Wang, Minglu Ma, Runbo Wang, Jilun Wang, Tingting Huang, Tao Wang, Xuejun Ruan, Minbiao Ji, Liwu Zhang

Published in

Science advances. Volume 11. Issue 41. Pages eadx5714. Oct 10, 2025. Epub Oct 08, 2025.

Abstract

The photochemical conversion of CO₂ into valuable fuels faces challenges of low efficiency and poor selectivity. Hydrated electrons (e_aq^-), with their extremely negative reduction potential, are promising CO₂-reducing agents, yet their short lifetime limits selectivity and high-energy-density product formation. Herein, we show that microdroplet interfaces with strong electric fields (10⁹ volts per meter) substantially extend the lifespan of e_aq^- generated from industrial sulfite pollutants (SO₃^2-), lowering energy barriers in the CO₂ reduction reaction and enabling targeted product formation. The machine learning strategy identified microdroplet size as the key parameter controlling electric field strength, product yield, and selectivity. In our lab-based scaled-up system, microdroplets <10 micrometers improved performance by four to seven orders of magnitude over bulk-phase systems, achieving ~99% methanol selectivity. Strong interfacial electric fields stabilize intermediates and modulate carbon-oxygen bond lengths, directing pathways to high-value products. This approach enables sustainable CO₂ utilization via microdroplets, potentially producing fuels from waste.

PMID:
41061076
Bibliographic data and abstract were imported from PubMed on 09 Oct 2025.

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