Atomically Precise Nanoclusters as Co-Catalysts for Light-Activated Microswimmer Motility

John Castañeda; Blake Rogers; Ysaris Sosa; Jorge A. Muñoz; Badri Bhattarai; Ashley M. Martinez; M. Lisa Phipps; Demosthenes P. Morales; Matthew N. Montoya Rush; Miguel José Yacaman; Gabriel A. Montaño; John G. Gibbs; Jennifer S. Martinez

doi:10.1002/smll.202411517

Atomically Precise Nanoclusters as Co-Catalysts for Light-Activated Microswimmer Motility

John Castañeda, Blake Rogers, Ysaris Sosa, Jorge A. Muñoz, Badri Bhattarai, Ashley M. Martinez, M. Lisa Phipps, Demosthenes P. Morales, Matthew N. Montoya Rush, Miguel José Yacaman, Gabriel A. Montaño, John G. Gibbs, Jennifer S. Martinez

Applied Physics and Materials Science

Research output: Contribution to journal › Article › peer-review

Abstract

Microswimmers are self-propelled particles that navigate fluid environments, offering significant potential for applications in environmental pollutant decomposition, biosensing, and targeted drug delivery. Their performance relies on engineered catalytic surfaces. Gold nanoclusters (AuNCs), with atomically precise structures, tunable optical properties, and high surface area-to-volume ratio, provide a new optimal catalyst for enhancing microswimmer propulsion. Unlike bulk gold or nanoparticles, AuNCs may deliver tunable photocatalytic activity and increased catalytic specificity, making them ideal co-catalysts for hybrid microswimmers. For the first time, this study combines AuNCs with TiO₂/Cr₂O₃ Janus microswimmers, combining the unique properties of both materials. This hybrid system capitalizes on the tuned optical properties of AuNCs and their role as co-catalysts with TiO₂, driving enhanced photocatalytic performance under ultraviolet (UV) excitation. Using motion analysis, it is shown that the AuNC-microswimmers exhibit significantly greater propulsion and mean squared displacement (MSD) as compared to controls. These findings suggest that the integration of nanoclusters with semiconductor materials enables state of the art, light-switchable microswimmers. These AuNC-microswimmer systems may thus offer new opportunities for environmental catalysis and other applications, providing precise control over catalytic and motile behaviors at the microscale.

Original language	English (US)
Article number	2411517
Journal	Small
Volume	21
Issue number	25
DOIs	https://doi.org/10.1002/smll.202411517
State	Published - Jun 26 2025

Keywords

atomically precise nanocluster
hybrid microswimmers
light-activated microswimmers
photocatalytic active matter

ASJC Scopus subject areas

Biotechnology
General Chemistry
Biomaterials
General Materials Science

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10.1002/smll.202411517

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Castañeda, J., Rogers, B., Sosa, Y., Muñoz, J. A., Bhattarai, B., Martinez, A. M., Phipps, M. L., Morales, D. P., Montoya Rush, M. N., Yacaman, M. J., Montaño, G. A., Gibbs, J. G., & Martinez, J. S. (2025). Atomically Precise Nanoclusters as Co-Catalysts for Light-Activated Microswimmer Motility. Small, 21(25), Article 2411517. https://doi.org/10.1002/smll.202411517

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title = "Atomically Precise Nanoclusters as Co-Catalysts for Light-Activated Microswimmer Motility",

abstract = "Microswimmers are self-propelled particles that navigate fluid environments, offering significant potential for applications in environmental pollutant decomposition, biosensing, and targeted drug delivery. Their performance relies on engineered catalytic surfaces. Gold nanoclusters (AuNCs), with atomically precise structures, tunable optical properties, and high surface area-to-volume ratio, provide a new optimal catalyst for enhancing microswimmer propulsion. Unlike bulk gold or nanoparticles, AuNCs may deliver tunable photocatalytic activity and increased catalytic specificity, making them ideal co-catalysts for hybrid microswimmers. For the first time, this study combines AuNCs with TiO2/Cr2O3 Janus microswimmers, combining the unique properties of both materials. This hybrid system capitalizes on the tuned optical properties of AuNCs and their role as co-catalysts with TiO2, driving enhanced photocatalytic performance under ultraviolet (UV) excitation. Using motion analysis, it is shown that the AuNC-microswimmers exhibit significantly greater propulsion and mean squared displacement (MSD) as compared to controls. These findings suggest that the integration of nanoclusters with semiconductor materials enables state of the art, light-switchable microswimmers. These AuNC-microswimmer systems may thus offer new opportunities for environmental catalysis and other applications, providing precise control over catalytic and motile behaviors at the microscale.",

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note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Small published by Wiley-VCH GmbH.",

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AU - Castañeda, John

AU - Rogers, Blake

AU - Sosa, Ysaris

AU - Muñoz, Jorge A.

AU - Bhattarai, Badri

AU - Martinez, Ashley M.

AU - Phipps, M. Lisa

AU - Morales, Demosthenes P.

AU - Montoya Rush, Matthew N.

AU - Yacaman, Miguel José

AU - Montaño, Gabriel A.

AU - Gibbs, John G.

AU - Martinez, Jennifer S.

PY - 2025/6/26

Y1 - 2025/6/26

N2 - Microswimmers are self-propelled particles that navigate fluid environments, offering significant potential for applications in environmental pollutant decomposition, biosensing, and targeted drug delivery. Their performance relies on engineered catalytic surfaces. Gold nanoclusters (AuNCs), with atomically precise structures, tunable optical properties, and high surface area-to-volume ratio, provide a new optimal catalyst for enhancing microswimmer propulsion. Unlike bulk gold or nanoparticles, AuNCs may deliver tunable photocatalytic activity and increased catalytic specificity, making them ideal co-catalysts for hybrid microswimmers. For the first time, this study combines AuNCs with TiO2/Cr2O3 Janus microswimmers, combining the unique properties of both materials. This hybrid system capitalizes on the tuned optical properties of AuNCs and their role as co-catalysts with TiO2, driving enhanced photocatalytic performance under ultraviolet (UV) excitation. Using motion analysis, it is shown that the AuNC-microswimmers exhibit significantly greater propulsion and mean squared displacement (MSD) as compared to controls. These findings suggest that the integration of nanoclusters with semiconductor materials enables state of the art, light-switchable microswimmers. These AuNC-microswimmer systems may thus offer new opportunities for environmental catalysis and other applications, providing precise control over catalytic and motile behaviors at the microscale.

AB - Microswimmers are self-propelled particles that navigate fluid environments, offering significant potential for applications in environmental pollutant decomposition, biosensing, and targeted drug delivery. Their performance relies on engineered catalytic surfaces. Gold nanoclusters (AuNCs), with atomically precise structures, tunable optical properties, and high surface area-to-volume ratio, provide a new optimal catalyst for enhancing microswimmer propulsion. Unlike bulk gold or nanoparticles, AuNCs may deliver tunable photocatalytic activity and increased catalytic specificity, making them ideal co-catalysts for hybrid microswimmers. For the first time, this study combines AuNCs with TiO2/Cr2O3 Janus microswimmers, combining the unique properties of both materials. This hybrid system capitalizes on the tuned optical properties of AuNCs and their role as co-catalysts with TiO2, driving enhanced photocatalytic performance under ultraviolet (UV) excitation. Using motion analysis, it is shown that the AuNC-microswimmers exhibit significantly greater propulsion and mean squared displacement (MSD) as compared to controls. These findings suggest that the integration of nanoclusters with semiconductor materials enables state of the art, light-switchable microswimmers. These AuNC-microswimmer systems may thus offer new opportunities for environmental catalysis and other applications, providing precise control over catalytic and motile behaviors at the microscale.

KW - atomically precise nanocluster

KW - hybrid microswimmers

KW - light-activated microswimmers

KW - photocatalytic active matter

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Atomically Precise Nanoclusters as Co-Catalysts for Light-Activated Microswimmer Motility

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Keywords

ASJC Scopus subject areas

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