# From batch to flow plasmon catalysis: revealing mass transport limits in Au@Pd nanocatalysts for Suzuki coupling

**Authors:** Mariia Erzina, Daria Votkina, Elena Miliutina, Oleg Gorin, Malek Y. S. Ibrahim, David M. Köpfler, Tobias Friedl, Christian Koller, Junais Habeeb Mokkath, Mufasila Mumthaz Muhammed, Markus Valtiner, Oleksiy Lyutakov, Olga Guselnikova

PMC · DOI: 10.1039/d5nr03832d · Nanoscale · 2025-12-12

## TL;DR

This paper shows how switching from batch to flow reactors improves plasmonic catalysis for chemical reactions, making the process more efficient and scalable.

## Contribution

The study provides the first framework for translating plasmonic catalysis into flow systems, emphasizing the role of mass transport in enhancing reaction efficiency.

## Key findings

- Flow mode increases reaction rate, time to full conversion, and apparent quantum yield threefold compared to batch mode.
- Fluid dynamics and photocurrent measurements show that mass transport enhances electron transfer efficiency and product yield.
- Efficient carrier transfer to reactants is critical for high turnover numbers and apparent quantum yields in flow systems.

## Abstract

Plasmonic catalysis, as a powerful tool for synthetic transformations, has the potential to impact wide-scale applications by converting solar light into energy for chemical reactions. Current studies are limited to mL-scale batch reactors with mg-level nanocatalysts, lacking feasibility in common laboratory and industrial configurations. To overcome this limitation, transition of plasmonic chemistry from batch to flow mode is foreseen; however, there is a lack of understanding of how plasmon-driven processes couple with mass transport. To address this issue, we designed plasmonic catalysts for a flow system at a tens of mL scale employing gram-scale Au@PdNPs–Al2O3 nanostructures in a flow reactor. Using Suzuki cross-coupling as a model reaction, we showed that the flow mode for Au@PdNPs–Al2O3 increases the reaction rate, the time to full conversion and the apparent quantum yield (AQY) ×3 compared to batch mode and outperforms previously reported examples/cases. Fluid dynamic simulations showed the critical effect of the residence times of nanocatalyst–reactant complexes under illumination on the product yield. This was consistent with photocurrent measurements, revealing that the electron transfer efficiency is enhanced under increased mass transport conditions. Unlike previous studies that primarily emphasized the carrier dynamics within metal–metal/semiconductor heterojunctions (e.g., Au/Pd) in batch mode, our flow system demonstrates that efficient carrier transfer to reactants is critical for achieving high TONs and AQYs. This work provides the first framework for translating plasmonic catalysis into flow, offering design principles for future light-driven chemical processes beyond conventional batch mode.

Transitioning plasmonic chemistry from batch to flow, we show that controlled mass transport in a flow reactor unlocks hot-carrier transfer in gram-scale Au@Pd–Al2O3 catalysts, tripling Suzuki coupling and enabling scalable light-driven synthesis.

## Full-text entities

- **Chemicals:** Pd (MESH:D010165), Al2O3 (MESH:D000537), AQYs (-), Au (MESH:D006046)

## Full text

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## Figures

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## References

66 references — full list in the complete paper: https://tomesphere.com/paper/PMC12856979/full.md

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Source: https://tomesphere.com/paper/PMC12856979