Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels

Pin Hsun Huang; Mu En Li; Chi Shan Lu; Chih Hao Huang; Hsin Ni Wu; Peng Chin Tsai; Jim Jui Kai Chen; Boris Lous; Roger Bresoli-Obach; Suzana Rocha; Johan Hofkens; Henryk Witek; Ming Chia Li; Hiroshi Masuhara

doi:10.1007/s43630-025-00723-w

Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels

Pin Hsun Huang, Mu En Li, Chi Shan Lu, Chih Hao Huang, Hsin Ni Wu, Peng Chin Tsai, Jim Jui Kai Chen, Boris Lous, Roger Bresoli-Obach, Suzana Rocha, Johan Hofkens, Henryk Witek^*, Ming Chia Li^*, Hiroshi Masuhara^*

^*Autor corresponent d’aquest treball

Producció científica: Article en revista indexada › Article › Avaluat per experts

Resum

Optical trapping at interfaces has emerged as a valuable research topic in the study of colloidal particles and soft matter. Objects are drawn from the irradiated cone-like region toward the laser focus, generating flow patterns beyond the focal area. Localized heating at the focus induces coupled effects on surface tension, capillary forces, and Marangoni convection. Furthermore, optical propagation and scattering of the trapping laser beyond the focus can lead to the formation of large assemblies along the interface, extending well beyond the laser beam itself. For gold nanoparticles, a single large swarming assembly forms, with individual nanoparticles exhibiting vivid fluctuations. In this study, we investigate the swarming assembly as a non-linearly evolving optical matter using a plastic microchannel. The original structure undergoes transformations into pressed, square, unidirectional, triangular, elongated rectangular, or even twisted assemblies. In addition, the photothermal effects of the optical matter are analyzed in the context of a local anisotropic heater. This phenomenon not only suggests potential applications but also offers valuable insights for advancing new technologies.

Idioma original	Anglès
Número d’article	092003
Pàgines (de-a)	751–764
Nombre de pàgines	14
Revista	Photochemical and Photobiological Sciences
Volum	24
Número	5
Data online anticipada	7 de maig 2025
DOIs	https://doi.org/10.1007/s43630-025-00723-w
Estat de la publicació	Publicada - de maig 2025

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10.1007/s43630-025-00723-wLlicència: CC BY

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Huang, P. H., Li, M. E., Lu, C. S., Huang, C. H., Wu, H. N., Tsai, P. C., Chen, J. J. K., Lous, B., Bresoli-Obach, R., Rocha, S., Hofkens, J., Witek, H., Li, M. C., & Masuhara, H. (2025). Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels. Photochemical and Photobiological Sciences, 24(5), 751–764. Article 092003. https://doi.org/10.1007/s43630-025-00723-w

@article{bdfb2b7afb5a4800b8bb502d6f022c12,

title = "Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels",

abstract = "Optical trapping at interfaces has emerged as a valuable research topic in the study of colloidal particles and soft matter. Objects are drawn from the irradiated cone-like region toward the laser focus, generating flow patterns beyond the focal area. Localized heating at the focus induces coupled effects on surface tension, capillary forces, and Marangoni convection. Furthermore, optical propagation and scattering of the trapping laser beyond the focus can lead to the formation of large assemblies along the interface, extending well beyond the laser beam itself. For gold nanoparticles, a single large swarming assembly forms, with individual nanoparticles exhibiting vivid fluctuations. In this study, we investigate the swarming assembly as a non-linearly evolving optical matter using a plastic microchannel. The original structure undergoes transformations into pressed, square, unidirectional, triangular, elongated rectangular, or even twisted assemblies. In addition, the photothermal effects of the optical matter are analyzed in the context of a local anisotropic heater. This phenomenon not only suggests potential applications but also offers valuable insights for advancing new technologies.",

keywords = "Gold nanoparticle, Microchannel, Optical binding, Optical matter, Optical swarming, Optical trapping",

author = "Huang, \{Pin Hsun\} and Li, \{Mu En\} and Lu, \{Chi Shan\} and Huang, \{Chih Hao\} and Wu, \{Hsin Ni\} and Tsai, \{Peng Chin\} and Chen, \{Jim Jui Kai\} and Boris Lous and Roger Bresoli-Obach and Suzana Rocha and Johan Hofkens and Henryk Witek and Li, \{Ming Chia\} and Hiroshi Masuhara",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = may,

doi = "10.1007/s43630-025-00723-w",

language = "English",

volume = "24",

pages = "751–764",

journal = "Photochemical and Photobiological Sciences",

issn = "1474-905X",

publisher = "Springer Nature",

number = "5",

}

Huang, PH, Li, ME, Lu, CS, Huang, CH, Wu, HN, Tsai, PC, Chen, JJK, Lous, B, Bresoli-Obach, R, Rocha, S, Hofkens, J, Witek, H, Li, MC & Masuhara, H 2025, 'Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels', Photochemical and Photobiological Sciences, vol. 24, núm. 5, 092003, pàg. 751–764. https://doi.org/10.1007/s43630-025-00723-w

TY - JOUR

T1 - Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels

AU - Huang, Pin Hsun

AU - Li, Mu En

AU - Lu, Chi Shan

AU - Huang, Chih Hao

AU - Wu, Hsin Ni

AU - Tsai, Peng Chin

AU - Chen, Jim Jui Kai

AU - Lous, Boris

AU - Bresoli-Obach, Roger

AU - Rocha, Suzana

AU - Hofkens, Johan

AU - Witek, Henryk

AU - Li, Ming Chia

AU - Masuhara, Hiroshi

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/5

Y1 - 2025/5

N2 - Optical trapping at interfaces has emerged as a valuable research topic in the study of colloidal particles and soft matter. Objects are drawn from the irradiated cone-like region toward the laser focus, generating flow patterns beyond the focal area. Localized heating at the focus induces coupled effects on surface tension, capillary forces, and Marangoni convection. Furthermore, optical propagation and scattering of the trapping laser beyond the focus can lead to the formation of large assemblies along the interface, extending well beyond the laser beam itself. For gold nanoparticles, a single large swarming assembly forms, with individual nanoparticles exhibiting vivid fluctuations. In this study, we investigate the swarming assembly as a non-linearly evolving optical matter using a plastic microchannel. The original structure undergoes transformations into pressed, square, unidirectional, triangular, elongated rectangular, or even twisted assemblies. In addition, the photothermal effects of the optical matter are analyzed in the context of a local anisotropic heater. This phenomenon not only suggests potential applications but also offers valuable insights for advancing new technologies.

AB - Optical trapping at interfaces has emerged as a valuable research topic in the study of colloidal particles and soft matter. Objects are drawn from the irradiated cone-like region toward the laser focus, generating flow patterns beyond the focal area. Localized heating at the focus induces coupled effects on surface tension, capillary forces, and Marangoni convection. Furthermore, optical propagation and scattering of the trapping laser beyond the focus can lead to the formation of large assemblies along the interface, extending well beyond the laser beam itself. For gold nanoparticles, a single large swarming assembly forms, with individual nanoparticles exhibiting vivid fluctuations. In this study, we investigate the swarming assembly as a non-linearly evolving optical matter using a plastic microchannel. The original structure undergoes transformations into pressed, square, unidirectional, triangular, elongated rectangular, or even twisted assemblies. In addition, the photothermal effects of the optical matter are analyzed in the context of a local anisotropic heater. This phenomenon not only suggests potential applications but also offers valuable insights for advancing new technologies.

KW - Gold nanoparticle

KW - Microchannel

KW - Optical binding

KW - Optical matter

KW - Optical swarming

KW - Optical trapping

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UR - http://hdl.handle.net/20.500.14342/5289

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DO - 10.1007/s43630-025-00723-w

M3 - Article

C2 - 40332734

AN - SCOPUS:105004444519

SN - 1474-905X

VL - 24

SP - 751

EP - 764

JO - Photochemical and Photobiological Sciences

JF - Photochemical and Photobiological Sciences

IS - 5

M1 - 092003

ER -

Morphology control of dynamic optical matter of gold nanoparticles fabricated by optical trapping in printed microchannels

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