Role of a hydrophobic microenvironment in catalytic C1 transformations

Abstract

Catalytic conversion of C1 molecules, such as CO, CO2 and CH4, into fuels and chemicals is a pivotal area in sustainable energy technologies. This process is crucial for mitigating environmental concerns and closing the carbon cycle loop. Water is a ubiquitous by-product and plays a vital role in these transformations. The presence of water can thermodynamically shift reaction equilibria and poison catalysts, leading to decreased selectivity and efficiency. Gas permeation in multi-phase reaction systems is another challenge in efficient catalyst design. Recent advancements have shown that hydrophobic microenvironments can enhance catalytic performance in C1 transformations by water removal or enhanced gas permeation. This review explores the role of hydrophobic catalysts in key energy-related C1 transformations, focusing on syngas conversion, methane oxidation, and electrocatalytic and photocatalytic reduction of CO2. By examining catalyst modifications, physical mixing with hydrophobic promoters, and other innovative catalyst designs, we highlight significant breakthroughs in improving product selectivity, yield, and catalyst longevity, emphasizing its potential to revolutionize sustainable fuel and chemical production from abundant C1 feedstocks.

Graphical abstract: Role of a hydrophobic microenvironment in catalytic C1 transformations

Article information

Article type
Tutorial Review
Submitted
21 aug 2024
Accepted
26 nov 2024
First published
03 dec 2024

Green Chem., 2025, Advance Article

Role of a hydrophobic microenvironment in catalytic C1 transformations

S. P. Teong, S. P. Chan, X. Li, J. Wang and Y. Zhang, Green Chem., 2025, Advance Article , DOI: 10.1039/D4GC04181J

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