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Layered High‐Entropy Metallic Glasses for Photothermal CO<sub>2</sub> Methanation

Xiwen Yu, Xue Ding, Yingfang Yao, Wanguo Gao, Cheng Wang, Chengyang Wu, Congping Wu, Bing Wang, Lu Wang, Zhigang Zou

2024Advanced Materials32 citationsDOI

Abstract

Abstract High entropy alloys and metallic glasses, as two typical metastable nanomaterials, have attracted tremendous interest in energy conversion catalysis due to their high reactivity in nonequilibrium states. Herein, a novel nanomaterial, layered high entropy metallic glass (HEMG), in a higher energy state than low‐entropy alloys and its crystalline counterpart due to both the disordered elemental and structural arrangements, is synthesized. Specifically, the MnNiZrRuCe HEMG exhibits highly enhanced photothermal catalytic activity and long‐term stability. An unprecedented CO 2 methanation rate of 489 mmol g −1 h −1 at 330 °C is achieved, which is, to the authors’ knowledge, the highest photothermal CO 2 methanation rate in flow reactors. The remarkable activity originates from the abundant free volume and high internal energy state of HEMG, which lead to the extraordinary heterolytic H 2 dissociation capacity. The high‐entropy effect also ensures the excellent stability of HEMG for up to 450 h. This work not only provides a new perspective on the catalytic mechanism of HEMG, but also sheds light on the great catalytic potential in future carbon‐negative industry.

Topics & Concepts

MethanationMaterials scienceCatalysisNanomaterialsPhotothermal therapyMetastabilityNon-equilibrium thermodynamicsDissociation (chemistry)Chemical physicsThermodynamicsNanotechnologyChemical engineeringPhysical chemistryChemistryOrganic chemistryPhysicsEngineeringCatalytic Processes in Materials ScienceHigh Entropy Alloys StudiesElectrocatalysts for Energy Conversion
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