4.8 Article

The Weyl Semimetals MIrTe4 (M = Nb, Ta) as Efficient Catalysts for Dye-Sensitized Hydrogen Evolution

Journal

ADVANCED ENERGY MATERIALS
Volume 13, Issue 24, Pages -

Publisher

WILEY-V C H VERLAG GMBH
DOI: 10.1002/aenm.202300503

Keywords

dye-sensitized photocatalysis; hydrogen evolution; metal chalcogenides; metal d-band density; Weyl semimetals

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The global energy crisis has prompted the search for viable pathways to generate green hydrogen as an alternative energy resource. Dye-sensitized photocatalytic water splitting is a feasible solution for producing green hydrogen. This study reports a new class of electrocatalysts based on layered Weyl semimetals MIrTe4, which demonstrate high catalytic activity for the hydrogen evolution reaction using Eosin Y as a photosensitizer.
The prevalent global energy crisis calls for searching viable pathways for generating green hydrogen as an alternative energy resource. Dye-sensitized photocatalytic water splitting is a feasible solution to produce green hydrogen. However, identifying suitable catalysts has been one of the bottlenecks in driving dye-sensitized photocatalysis efficiently. In this work, a new class of electrocatalysts is reported based on the layered Weyl semimetals MIrTe4 (M = Nb, Ta) for the Eosin Y (EY)-sensitized hydrogen evolution reaction (HER). NbIrTe4 and TaIrTe4 exhibit HER activities of approximate to 18 000 and 14 000 mu mol g(-1) respectively, after 10 h of irradiation with visible light. Time-dependent UV-Vis spectroscopy and high-pressure liquid chromatography coupled with mass spectrometry analysis shed light on the reaction dynamics and enable a deeper understanding of the observed trend in hydrogen evolution rates for MIrTe4. MIrTe4 semimetals outperform transition metal-based Weyl semimetals in terms of catalytic HER activity using EY as photosensitizer and triethanolamine as the sacrificial agent. It is hypothesized that the topology-related band inversion in MIrTe4 Weyl semimetals promotes a high density of M d-states near the Fermi level, driving their high catalytic performance. This study introduces a new class of layered Weyl semimetals as efficient catalysts, and provides perspectives for designing topology-enhanced catalysts.

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