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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3 Pith papers cite this work. Polarity classification is still indexing.
years
2026 3verdicts
UNVERDICTED 3representative citing papers
Levitated ~200 nm Au particles in a quadrupole ion trap acquire a carbon barrier under repeated 532 nm laser pulsing in vacuum, increasing mass independently of added carbon-gas pressures and consistent with graphene growth from a hypothesized rare surface catalyst.
Experimental methods achieve Q/M measurement precision approaching 10^{-5} for levitated nanoparticles in ultra-high vacuum using ion traps with thermostatic amplitude control.
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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.