# Dynamic Interfacial Modulation in Pt@Ga Liquid Metal Systems

**Authors:** Zanyu Chen, Yixiao Zou, Wenda Chen, Chen Zhang, Jinfeng Zhang, Jia Ding, Xiaopeng Han, Wenbin Hu

PMC · DOI: 10.1002/advs.202516511 · Advanced Science · 2026-01-04

## TL;DR

Researchers developed a new type of liquid metal catalyst using gallium and platinum to improve hydrogen production efficiency through dynamic interface control.

## Contribution

A novel dissolution-reconstruction method for Pt@Ga liquid metal catalysts is introduced, enabling dynamic interfacial modulation and enhanced performance in hydrogen evolution.

## Key findings

- Pt@Ga catalysts enable in situ formation of Pt wires with high (200) crystal facets through controlled oxide layers.
- Dynamic interface evolution improves electronic coupling and accelerates charge and mass transport.
- The method offers a new design strategy for self-adaptive liquid metal catalysts in renewable energy systems.

## Abstract

Catalysts are essential in the transformation of chemical value chains, and traditional solid catalysts encounter challenges in structural flexibility, interfacial mass transport, and long‐term stability, especially in heterogeneous and electrochemical systems. Liquid metal‐based catalysts, particularly gallium (Ga), provide a dynamic platform with tunable physicochemical properties and favorable interfacial responsiveness. However, the electrochemical interfacial behavior and oxide regulation of Ga‐based liquid metal catalysts in alkaline electrolytes are still largely unexplored. In this work, Pt@Ga is selected as a model system and focused on the alkaline hydrogen evolution reaction (HER) to explore the potential of liquid metal‐based catalysts in the renewable hydrogen energy field. By precisely controlling the Ga surface oxide layer, the in situ formation of Pt wires is enabled with a high proportion of (200) crystal facets. This strategy overcomes the structural constraints of solid supports and enhances the electronic coupling between Pt and Ga. Experimental results from in situ analysis visualize Pt growth dynamics and reveal the synergistic interactions that accelerate charge and mass transport at the catalyst/electrolyte interface. This study presents a novel design for liquid metal‐based catalysts, where oxide‐regulated metal growth and dynamic interface evolution synergistically boost catalyst performance, offering a paradigm for next‐generation self‐adaptive systems.

This work introduces a facile dissolution‐reconstruction approach to prepare the Pt@Ga liquid catalyst by dissolving Pt in molten Ga and then using electrochemical treatment to reconstruct Pt on the Ga support, which provides a new design strategy for liquid‐metal catalysts and enhances the understanding of oxide‐modulated segregation, offering new ideas for future research on multi‐functional supported catalyst systems.

## Full-text entities

- **Chemicals:** oxide (MESH:D010087), Pt (MESH:D010984), Metal (MESH:D008670), Ga (MESH:D005708), hydrogen (MESH:D006859), Pt@Ga (-)

## Full text

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## Figures

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## References

70 references — full list in the complete paper: https://tomesphere.com/paper/PMC12948278/full.md

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Source: https://tomesphere.com/paper/PMC12948278