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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Proposes and simulates the use of space-based atomic clock networks for one-way Doppler tracking of gravitational waves in concert with LISA, including noise analysis and preliminary parameter estimation on binary sources.
Proposes that excess photon luminosity from hydrogen atoms absorbing stellar gravitons could serve as a detection signal.
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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Gravitational-wave astronomy with a space-based optical clock network
Proposes and simulates the use of space-based atomic clock networks for one-way Doppler tracking of gravitational waves in concert with LISA, including noise analysis and preliminary parameter estimation on binary sources.
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Detection of Gravitons by Measuring Excess of Photon Luminosities from Interstellar and Intergalactic Hydrogen
Proposes that excess photon luminosity from hydrogen atoms absorbing stellar gravitons could serve as a detection signal.
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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.