A piezoelectric-driven glass capillary launcher enables localized, high-efficiency (up to 93%) in-vacuum loading of silica spheres, nanodiamonds, and plate-like particles into single-beam, dual-beam, and standing-wave optical traps.
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Interference of electric and magnetic dipoles produces directional scattering into free-space and SPP channels for a Mie particle near a metal interface, directly linking force direction and magnitude to radiation directivity and enabling nearly 2π force control in cross-beam geometry for optical-sr
This review unifies optical and acoustic radiation forces and torques via local energy, momentum, and spin densities of wave fields and surveys their applications.
citing papers explorer
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Localized efficient in-vacuum loading of $\sim$0.1-10 $\mu$m spherical and plate-like particles into optical traps using a pulled glass capillary
A piezoelectric-driven glass capillary launcher enables localized, high-efficiency (up to 93%) in-vacuum loading of silica spheres, nanodiamonds, and plate-like particles into single-beam, dual-beam, and standing-wave optical traps.
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Directional Scattering-Induced Optical Forces on a Mie Particle near a Metal Interface
Interference of electric and magnetic dipoles produces directional scattering into free-space and SPP channels for a Mie particle near a metal interface, directly linking force direction and magnitude to radiation directivity and enabling nearly 2π force control in cross-beam geometry for optical-sr
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Radiation forces and torques in optics and acoustics
This review unifies optical and acoustic radiation forces and torques via local energy, momentum, and spin densities of wave fields and surveys their applications.