Programmable assemblies of photothermal anisotropic micromotors for multimodal motion

Wenchang Zhao; Shiyu Wang; Ying Zhou; Yanhong Li; Shuxian Tang; Yutong Zheng; Pingan Zhu

doi:10.1039/d4mh01346h

Programmable assemblies of photothermal anisotropic micromotors for multimodal motion

Wenchang Zhao, Shiyu Wang, Ying Zhou, Yanhong Li, Shuxian Tang, Yutong Zheng, Pingan Zhu^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

2 Citations (Scopus)

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Abstract

Light-driven micromotors with multiple motion modes offer significantly greater application potential than single-mode micromotors. However, achieving such versatility often requires complex structural designs and precise light focusing on specific micromotor regions, presenting challenges for dynamic operations and microscale precisions. This study introduces programmable assemblies of anisotropic micromotors driven by the photothermal Marangoni effect, produced in bulk via microfluidic technology. Under full-area near-infrared (NIR) irradiation, the micromotor exhibits multiple motion modes, including translation and revolution, while micromotor assemblies display additional rotational motion. Self-assembly of these micromotors is highly controllable and programmable, enabling easy customization of assembled structures to achieve desired motion modes. These features are expected to advance the development of various intelligent self-propelling systems, using multimodal individual micromotors as foundational building blocks. © The Royal Society of Chemistry 2025.

Original language	English
Pages (from-to)	1168-1178
Journal	Materials Horizons
Volume	12
Issue number	4
Online published	2 Jan 2025
DOIs	https://doi.org/10.1039/d4mh01346h
Publication status	Published - 21 Feb 2025

Funding

The financial support from National Natural Science Foundation of China (52303046), the Research Grants Council of Hong Kong (21213621), Shenzhen Science and Technology Program (JCYJ20220530140812028), and the City University of Hong Kong (7005936 and 7006097) is gratefully acknowledged.

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This full text is made available under CC-BY-NC 3.0. https://creativecommons.org/licenses/by-nc/3.0/

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title = "Programmable assemblies of photothermal anisotropic micromotors for multimodal motion",

abstract = "Light-driven micromotors with multiple motion modes offer significantly greater application potential than single-mode micromotors. However, achieving such versatility often requires complex structural designs and precise light focusing on specific micromotor regions, presenting challenges for dynamic operations and microscale precisions. This study introduces programmable assemblies of anisotropic micromotors driven by the photothermal Marangoni effect, produced in bulk via microfluidic technology. Under full-area near-infrared (NIR) irradiation, the micromotor exhibits multiple motion modes, including translation and revolution, while micromotor assemblies display additional rotational motion. Self-assembly of these micromotors is highly controllable and programmable, enabling easy customization of assembled structures to achieve desired motion modes. These features are expected to advance the development of various intelligent self-propelling systems, using multimodal individual micromotors as foundational building blocks. {\textcopyright} The Royal Society of Chemistry 2025.",

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AU - Zhao, Wenchang

AU - Wang, Shiyu

AU - Zhou, Ying

AU - Li, Yanhong

AU - Tang, Shuxian

AU - Zheng, Yutong

AU - Zhu, Pingan

PY - 2025/2/21

Y1 - 2025/2/21

N2 - Light-driven micromotors with multiple motion modes offer significantly greater application potential than single-mode micromotors. However, achieving such versatility often requires complex structural designs and precise light focusing on specific micromotor regions, presenting challenges for dynamic operations and microscale precisions. This study introduces programmable assemblies of anisotropic micromotors driven by the photothermal Marangoni effect, produced in bulk via microfluidic technology. Under full-area near-infrared (NIR) irradiation, the micromotor exhibits multiple motion modes, including translation and revolution, while micromotor assemblies display additional rotational motion. Self-assembly of these micromotors is highly controllable and programmable, enabling easy customization of assembled structures to achieve desired motion modes. These features are expected to advance the development of various intelligent self-propelling systems, using multimodal individual micromotors as foundational building blocks. © The Royal Society of Chemistry 2025.

AB - Light-driven micromotors with multiple motion modes offer significantly greater application potential than single-mode micromotors. However, achieving such versatility often requires complex structural designs and precise light focusing on specific micromotor regions, presenting challenges for dynamic operations and microscale precisions. This study introduces programmable assemblies of anisotropic micromotors driven by the photothermal Marangoni effect, produced in bulk via microfluidic technology. Under full-area near-infrared (NIR) irradiation, the micromotor exhibits multiple motion modes, including translation and revolution, while micromotor assemblies display additional rotational motion. Self-assembly of these micromotors is highly controllable and programmable, enabling easy customization of assembled structures to achieve desired motion modes. These features are expected to advance the development of various intelligent self-propelling systems, using multimodal individual micromotors as foundational building blocks. © The Royal Society of Chemistry 2025.

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U2 - 10.1039/d4mh01346h

DO - 10.1039/d4mh01346h

M3 - RGC 21 - Publication in refereed journal

SN - 2051-6347

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EP - 1178

JO - Materials Horizons

JF - Materials Horizons

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Programmable assemblies of photothermal anisotropic micromotors for multimodal motion

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Programmable assemblies of photothermal anisotropic micromotors for multimodal motion

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