NV spin defects enable in-situ temperature imaging in diamond nanostructures, revealing width-dependent reduction in thermal conductivity consistent with non-diffusive phonon transport modeled by Boltzmann and viscous heat equations.
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The Wigner Transport Equation predicts coherence-dominated nondiffusive thermal transport causing significant deviations from bulk conductivity in CsPbBr3 and La2Zr2O7 at length scales of hundreds of nanometers to microns at room temperature.
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Imaging heat transport in suspended diamond nanostructures with integrated spin defect thermometers
NV spin defects enable in-situ temperature imaging in diamond nanostructures, revealing width-dependent reduction in thermal conductivity consistent with non-diffusive phonon transport modeled by Boltzmann and viscous heat equations.
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Transition from population- to coherence-dominated nondiffusive thermal transport
The Wigner Transport Equation predicts coherence-dominated nondiffusive thermal transport causing significant deviations from bulk conductivity in CsPbBr3 and La2Zr2O7 at length scales of hundreds of nanometers to microns at room temperature.