Neural quantum states simulate dissipative many-body emission dynamics for approximately 40 atoms in dense 1D and 2D arrays, revealing prominent subradiant behavior at late times.
Rubies-Bigorda, S
3 Pith papers cite this work. Polarity classification is still indexing.
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quant-ph 3years
2026 3representative citing papers
The maximum photon emission rate in atomic ensembles scales universally as atom number times optical depth at fixed density, unifying ordered and disordered systems from independent emission to the Dicke limit.
Spectral design via biorthogonal modes and a surrogate objective enables inverse design of atomic positions that concentrate initial excitation on a single subradiant mode for enhanced local-excitation retention.
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Neural network modeling of many-body super- and sub-radiant dynamics
Neural quantum states simulate dissipative many-body emission dynamics for approximately 40 atoms in dense 1D and 2D arrays, revealing prominent subradiant behavior at late times.
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Optical depth dictates universal bounds on many-body decay in atomic ensembles
The maximum photon emission rate in atomic ensembles scales universally as atom number times optical depth at fixed density, unifying ordered and disordered systems from independent emission to the Dicke limit.
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Spectral design principles for local-excitation retention in impurity-assisted atomic arrays
Spectral design via biorthogonal modes and a surrogate objective enables inverse design of atomic positions that concentrate initial excitation on a single subradiant mode for enhanced local-excitation retention.