Zero Fourier modes in circular photonic waveguide networks create a protected subspace that enables perfect state transfer to the diametrically opposite site when the number of sites N equals 4n.
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Numerical simulation of spontaneous symmetry breaking in a modified Dicke superradiance model where symmetry selection rules suppress single-photon emission, resulting in a quantum sensor that records the phase of light fluctuations.
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Perfect state transfer in quantum photonic networks based on Fourier modes
Zero Fourier modes in circular photonic waveguide networks create a protected subspace that enables perfect state transfer to the diametrically opposite site when the number of sites N equals 4n.
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Spontaneous symmetry breaking in nonlinear superradiance
Numerical simulation of spontaneous symmetry breaking in a modified Dicke superradiance model where symmetry selection rules suppress single-photon emission, resulting in a quantum sensor that records the phase of light fluctuations.