Flow with nanoparticle clustering controlled by optical forces in quartz glass nanoslits

Tsuji, Tetsuro; Matsumoto, Yuki

doi:10.1007/s10404-019-2287-x

Cited by 4 publications

(3 citation statements)

References 38 publications

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“…For instance, nanofabrication technologies have been mainly developed for silicon substrates, which are not transparent and not suitable for laser irradiation. Transparent glass substrates are also available (e.g., [24]), but the thickness is, usually, not a standard 0.17 mm of coverslips. That is, a high-NA oil immersion lens is not applicable because of its short working distance.…”

Section: Advantages and Challengesmentioning

confidence: 99%

Optical trapping in micro- and nanoconfinement systems: Role of thermo-fluid dynamics and applications

Tsuji

Doi

2022

Journal of Photochemistry and Photobiology C: Photochemistry Re

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Section: Advantages and Challengesmentioning

confidence: 99%

Optical trapping in micro- and nanoconfinement systems: Role of thermo-fluid dynamics and applications

Tsuji

Doi

2022

Journal of Photochemistry and Photobiology C: Photochemistry Re

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“…Tsuji et al ( 2019 ) demonstrate that using optical forces, nanoparticle flow can be controlled in all-quartz glass nanoslit channels. Yin et al ( 2020 ) have also proposed a plasmonic nanoparticle router, which consists of a series of gold nanostrips on top of a continuous gold thin film, to transport trapped nanoparticles along designated routes in a microfluidic channel with a continuous flow under the incident unfocused light.…”

Section: Applications In Biomedical Engineeringmentioning

confidence: 99%

Applications of Optically Controlled Gold Nanostructures in Biomedical Engineering

Phummirat

Mann

Preece

2021

Front. Bioeng. Biotechnol.

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Since their inception, optical tweezers have proven to be a useful tool for improving human understanding of the microscopic world with wide-ranging applications across science. In recent years, they have found many particularly appealing applications in the field of biomedical engineering which harnesses the knowledge and skills in engineering to tackle problems in biology and medicine. Notably, metallic nanostructures like gold nanoparticles have proven to be an excellent tool for OT-based micromanipulation due to their large polarizability and relatively low cytotoxicity. In this article, we review the progress made in the application of optically trapped gold nanomaterials to problems in bioengineering. After an introduction to the basic methods of optical trapping, we give an overview of potential applications to bioengineering specifically: nano/biomaterials, microfluidics, drug delivery, biosensing, biophotonics and imaging, and mechanobiology/single-molecule biophysics. We highlight the recent research progress, discuss challenges, and provide possible future directions in this field.

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“…Moreover, optical trapping of nanoparticles or molecules in highly concentrated solutions induces assembly of them at the focal spot, because the multiple particles are capable of confinement in an optical trap. The phase separation, clustering, and crystallization induced by optical trapping have attracted much attention for spatiotemporal control of the assembling process, which has been reported in various systems such as nanoparticle suspensions, − organic molecules, proteins and amino acids, , and intracellular molecules and vesicles . For realizing effective and selective manipulation, it is essential to understand the optical trapping dynamics interacted with particles, focused laser beams, and the surrounding environment.…”

Section: Introductionmentioning

confidence: 99%

Convection Dynamics Forced by Optical Trapping with a Focused Laser Beam

et al. 2020

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Optical trapping dynamics of colloidal particles in solution is essential for understanding laser-induced assembling of molecules and nanomaterials, which contributes to nanofabrication, bioengineering, and microfluidics. In this paper, the importance of the surrounding fluid motion in optical trapping is investigated; that is, we reveal convection fluid dynamics forced by optical trapping with a focused laser beam. The fluid flow in optical trapping is evaluated by both experiments using the particle-image-velocimetry of fluorescent particles in solutions and theoretical consideration based on numerical analysis. A theoretical model consists of Navier−Stokes equations with the Boussinesq approximation that considers the temperature elevation induced by a photothermal effect. Furthermore, the effect of the particle motion induced by the optical force on fluid flow is also included in the analysis by developing a simple one-way homogeneous-type multiphase flow model. From both experimental and theoretical results, it turns out that the fluid flow in optical trapping is caused not only by thermal convection due to the temperature elevation but also by the collective particle motion induced by optical forces. Therefore, the optical forces can induce the large-scale fluid convection, which supports accumulating the target particles to the focal spot.

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Flow with nanoparticle clustering controlled by optical forces in quartz glass nanoslits

Cited by 4 publications

References 38 publications

Optical trapping in micro- and nanoconfinement systems: Role of thermo-fluid dynamics and applications

Optical trapping in micro- and nanoconfinement systems: Role of thermo-fluid dynamics and applications

Applications of Optically Controlled Gold Nanostructures in Biomedical Engineering

Convection Dynamics Forced by Optical Trapping with a Focused Laser Beam

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