# Optical spectroscopic determination of photoexcited small-polaron hopping in transition metal oxide photocatalysts

**Authors:** Lei Tian, Michael Sachs, Lucas G. Verga, Viktoria F. Kunzelmann, Andreas Kafizas, Ian D. Sharp, Scott K. Cushing, Aron Walsh, James R. Durrant

PMC · DOI: 10.1039/d5sc08101g · Chemical Science · 2026-01-05

## TL;DR

This paper uses optical spectroscopy to study how photoexcited small polarons hop in transition metal oxides, revealing insights into their electronic behavior and energy loss.

## Contribution

The first optical spectroscopic observation of photoexcited small-polaron hopping in transition metal oxides is presented.

## Key findings

- Polaronic features appear within 500 fs as Drude-type absorption converts to localized absorption.
- Polaron relaxation energies are 400–650 meV, indicating significant energy loss during self-trapping.
- Oxides with open d-shells localize charge more readily, with low polaron formation barriers (0–10 meV) and higher hopping barriers (200–350 meV).

## Abstract

Ultrafast small-polaron formation profoundly shapes the electronic and catalytic behaviour of transition metal oxides (TMOs). Despite its significance, spectroscopic investigations of photoexcited polaron hopping in TMOs have been scarcely explored. Here, we present the first optical spectroscopic observation of photoexcited small-polaron hopping across the first-row TMOs, using femtosecond transient absorption spectroscopy. This polaronic feature rises within 500 fs as Drude-type absorption converts to localized, polaronic absorption. Fitting with a small-polaron optical conductivity model yields polaron relaxation energies of 400–650 meV, evidencing substantial energy loss upon self-trapping. Kinetic analysis shows that oxides with open d-shells localize charge most readily: polaron formation activation barriers are low in all TMOs (0–10 meV), whereas hopping barriers remain much higher (200–350 meV). This work establishes key spectroscopic and kinetic insights, highlighting the trade-off between charge localization and mobility, as well as the critical role of polaron formation in TMOs photocatalysts.

Ultrafast small-polaron formation profoundly shapes the electronic and catalytic behaviour of transition metal oxides (TMOs).

## Full-text entities

- **Chemicals:** oxide (MESH:D010087), TMOs (-)

## Full text

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## Figures

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## References

71 references — full list in the complete paper: https://tomesphere.com/paper/PMC12784217/full.md

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Source: https://tomesphere.com/paper/PMC12784217