High-definition direct-print of metallic microdots with optical vortex induced forward transfer

Wei, Rong; Kawaguchi, Haruki; Sato, Kaito; Kai, Sayaka; Yamane, Keisaku; Morita, Ryuji; Yuyama, Ken-ichi; Kawano, Satoyuki; Miyamoto, Katsuhiko; Aoki, Nobuyuki; Omatsu, Takashige

doi:10.1063/5.0187189

APL Photonics

2024

DOI: 10.1063/5.0187189

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High-definition direct-print of metallic microdots with optical vortex induced forward transfer

Rong Wei,

Haruki Kawaguchi,

Kaito Sato

et al.

Abstract: We demonstrate high-definition, direct-printing of micron-scale metallic dots, comprised of close-packed gold nanoparticles, by utilizing the optical vortex laser-induced forward transfer technique. We observe that the spin angular momentum of the optical vortex, associated with circular polarization, assists in the close-packing of the gold nanoparticles within the printed dots. The printed dots exhibit excellent electrical conductivity without any additional sintering processes. This technique of applying op… Show more

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Cited by 3 publications

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Fabrication of a ferrite microcrystal using optical vortex laser induced forward transfer

Kaneko,

Iwata,

Yuyama

et al. 2024

Appl. Phys. A

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Optical vortex induced forward transfer (OV-LIFT) allows the crystallization of magnetic nanoparticles enabling the fabrication of a 2-dimensional array of monocrystalline structures with a high spatial resolution. We herein investigate the optimum experimental conditions, such as the viscosity range of the donor and the energy range of the optical vortex pulse required for the crystallization of magnetic nanoparticles through a cavitation processes, including the flight dynamics of donor.

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Fabrication of a ferrite microcrystal using optical vortex laser induced forward transfer

Kaneko,

Iwata,

Yuyama

et al. 2024

Appl. Phys. A

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High-order LG vortex Pr:YLF laser emitting in the visible wavelength range for the measurement of angular velocity

Zhang,

Yan,

et al. 2024

Applied Physics Letters

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High-order vortex beams carrying orbital angular momentum in the visible wavelength range are of tremendous interest for a diversity of applications, including super-resolution imaging, microfabrication, and underwater communications. Such beams can be generated directly from compact solid-state lasers; however, they generally have low topological charge number. In this work, we demonstrate the generation of high-order Laguerre–Gaussian (LG) modes from a simple Pr:YLF laser cavity and demonstrate its application in the measurement of angular velocity. We utilize enhanced intracavity spherical aberration to generate LG0,±m modes with m selectable up to 34, directly from a Pr:YLF laser operating at 640 nm. We utilize this laser beam in an off-axis illumination geometry in conjunction with the rotational Doppler effect, to measure the angular velocity of a spinning object. The demonstration highlights a potential application for these types of vortex laser.

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Switching of three-dimensional optical cages using spatial coherence engineering

Xu,

Wu,

Zhao

et al. 2024

APL Photonics

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Precisely capturing and manipulating microparticles is the key to exploring microscopic mysteries. Optical tweezers play a crucial role in facilitating these tasks. However, existing optical tweezers are limited by their dependence on specific beam modes, which restrict their ability to flexibly switch and manipulate optical traps, thereby limiting their application in complex scientific challenges. Here, we propose a new method to achieve type switching and manipulation of optical traps using a single structured beam via optical coherence engineering. A conjugate-model random structured beam with a switch is designed. By altering the state of the switch, we can change the type of optical cage, enabling the capture of different particle types. Furthermore, the range, strength, and position of the optical trap can be controlled by adjusting the initial beam parameters. We hope that optical coherence engineering will extend the capabilities of existing structured optical tweezers, paving the way for advances in future optical tweezers applications.

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High-definition direct-print of metallic microdots with optical vortex induced forward transfer

Cited by 3 publications

References 52 publications

Fabrication of a ferrite microcrystal using optical vortex laser induced forward transfer

Fabrication of a ferrite microcrystal using optical vortex laser induced forward transfer

High-order LG vortex Pr:YLF laser emitting in the visible wavelength range for the measurement of angular velocity

Switching of three-dimensional optical cages using spatial coherence engineering

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