Experimental demonstration of trapping and cooling 170 nm silica nanospheres in tunable off-axis standing-wave optical traps at 0.55 or 1.61 micrometers from a mirror using interference from a single-beam tweezer with a tilted mirror.
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Spatial mode decomposition of back-scattered light from a levitated nanoparticle yields 3D displacement sensitivities below zero-point motion with estimated total efficiencies above 1/9.
Coupling Yb3+:YLiF4 nanocrystals to a cavity is predicted to achieve ~38 K internal temperature by Purcell-enhanced anti-Stokes fluorescence from lower ground-state levels.
citing papers explorer
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A method for optically trapping nanospheres at micron range from a tilted mirror
Experimental demonstration of trapping and cooling 170 nm silica nanospheres in tunable off-axis standing-wave optical traps at 0.55 or 1.61 micrometers from a mirror using interference from a single-beam tweezer with a tilted mirror.
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Three-Dimensional and Selective Displacement Sensing of a Levitated Nanoparticle via Spatial Mode Decomposition
Spatial mode decomposition of back-scattered light from a levitated nanoparticle yields 3D displacement sensitivities below zero-point motion with estimated total efficiencies above 1/9.
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Purcell-enhanced optical refrigeration
Coupling Yb3+:YLiF4 nanocrystals to a cavity is predicted to achieve ~38 K internal temperature by Purcell-enhanced anti-Stokes fluorescence from lower ground-state levels.