# Highly Dispersed Rhodium on MXenes via Microwave Solvothermal Strategy for High‐Performance Hydrogen Evolution Catalysis

**Authors:** Anton S. Zverev, Christopher Penschke, Leonardo Cancellara, Stefan Reinicke, Christina Günter, Sibylle Rüstig, Namitha Deepak, Sergio Kogikoski Jr, Peter Saalfrank, Ilko Bald

PMC · DOI: 10.1002/smll.202510349 · Small (Weinheim an Der Bergstrasse, Germany) · 2025-12-19

## TL;DR

A new microwave method creates highly efficient rhodium-based catalysts on MXene nanoflakes for hydrogen production in various conditions.

## Contribution

A microwave-assisted solvothermal strategy to create subnanometer Rh sites on MXenes with preserved structure and high HER performance.

## Key findings

- Microwave treatment preserves MXene nanoflake structure while forming subnanometer Rh catalytic sites.
- RhOn structures on oxygen-terminated MXene surfaces explain enhanced electrocatalytic activity.
- Rh-decorated MXenes outperform pure MXenes and match or exceed platinum in HER activity across pH conditions.

## Abstract

This work presents a novel microwave‐assisted solvothermal method for decorating nanoflakes of transition‐metal carbides (MXenes) Ti3C2 and V2C with highly dispersed rhodium catalytic sites, significantly enhancing the electrocatalytic efficiency of the hydrogen evolution reaction (HER). The results indicate that microwave treatment does not significantly alter the nanoflake structure but promotes the formation of subnanometer‐sized Rh catalytic sites. A combined analysis of density functional theory‐calculated core‐level shifts and experimental X‐ray photoelectron (XPS) spectra identifies the most likely structures of the Rh catalytic centers formed through the microwave‐assisted solvothermal process. Rh anchored to the oxygen‐terminated MXene nanoflake surface, bonded to two or three oxygen atoms (RhOn), explains the Rh 3d XPS band with a notable chemical shift. Rh‐decorated nanoflakes display superior catalytic performance in acidic, basic, and neutral media compared to pure MXenes. Turnover frequencies (TOF) suggest that the HER catalytic activity of Rh sites is comparable to or exceeds that of pure platinum surface atoms. Using rhodium catalytic site structures as an example, it is demonstrated that the mutual arrangement of the Gibbs free energy of hydrogen adsorption on the catalytic site, in cases with protonated and non‐protonated terminal groups of the nanoflake, can serve as a criterion for electrocatalytic efficiency.

This study presents a microwave‐assisted method to decorate MXene nanoflakes with rhodium (Rh) subnanometer catalytic sites. The material's structure remains intact, while electrocatalytic activity improves across different pH conditions. Detailed experimental and computational analyses identify the structure of Rh catalytic sites, providing insight into catalyst design and the factors that govern electrocatalytic performance.

## Linked entities

- **Chemicals:** rhodium (PubChem CID 23948), V2C (PubChem CID 60165612), hydrogen (PubChem CID 783), platinum (PubChem CID 23939)

## Full-text entities

- **Chemicals:** MXene (MESH:C000723374), RhOn (-), oxygen (MESH:D010100), Hydrogen (MESH:D006859), platinum (MESH:D010984), Rh (MESH:D012238)

## Full text

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## Figures

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## References

69 references — full list in the complete paper: https://tomesphere.com/paper/PMC12802550/full.md

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Source: https://tomesphere.com/paper/PMC12802550