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and control mechanical motion in new and powerful ways. We seek to challenge the limits of mechanical precision measurements, and devise new ways to manipulate the quantum states of macroscopic objects
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spectrum of the electrons in the SEM. This interaction dresses the electrons into a quantum superposition state which creates a way to tailor the spatial and temporal distribution of electron wavepackets
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spectrum of the electrons in the SEM. This interaction dresses the electrons into a quantum superposition state which creates a way to tailor the spatial and temporal distribution of electron wavepackets
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well as the applications they allow. Specific topics of interest include topological photonics, non-Hermitian dynamics, and quantum measurement in nano-optomechanical systems. The group combines theory and experiment
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data both at the level of signaling mechanisms, and the resource fluxes they control for symbiotic trade. The project builds on our prior work to characterize resource fluxes using quantum-dot labelled