Light fields can induce controllable time-dependent temperatures in electrodes to generate and detect charge-neutral heat pulses in mesoscopic conductors.
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3 Pith papers cite this work. Polarity classification is still indexing.
years
2026 3verdicts
UNVERDICTED 3representative citing papers
A new protocol for layer-resolved transport measurements that extracts anyon statistics from charge distribution across layers in multi-component topological states.
Numerical tests confirm that modular Hamiltonian methods extract expected topological numbers from FQHE wavefunctions but converge reliably only on large lattices.
citing papers explorer
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Generation of heat pulses in mesoscopic conductors using light fields
Light fields can induce controllable time-dependent temperatures in electrodes to generate and detect charge-neutral heat pulses in mesoscopic conductors.
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Probing bilayer topological order with layer-resolved transport
A new protocol for layer-resolved transport measurements that extracts anyon statistics from charge distribution across layers in multi-component topological states.
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Testing the robustness of topological quantities evaluated from the modular Hamiltonian for a given wavefunction
Numerical tests confirm that modular Hamiltonian methods extract expected topological numbers from FQHE wavefunctions but converge reliably only on large lattices.