Circularly polarized light induces an octupolar inverse Faraday effect and anisotropic multipolar exchange in 4d2/5d2 Mott insulators, opening a nonequilibrium phase space with tunable antiferro-octupolar, ferro-octupolar, and multipolar liquid states.
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Two-photon parametric amplification in a superconducting circuit exponentially strengthens cavity-qubit coupling, enabling faster charging and decoherence-resistant energy storage in a quantum battery.
Nonlinear electron-phonon interactions drive light-induced symmetry switching in charge-density waves, as captured by a new first-principles simulation framework that reproduces key experimental features in TiSe2.
citing papers explorer
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Light-driven octupolar inverse Faraday effect and multipolar order in Mott insulators
Circularly polarized light induces an octupolar inverse Faraday effect and anisotropic multipolar exchange in 4d2/5d2 Mott insulators, opening a nonequilibrium phase space with tunable antiferro-octupolar, ferro-octupolar, and multipolar liquid states.
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Quantum battery optimized by parametric amplification
Two-photon parametric amplification in a superconducting circuit exponentially strengthens cavity-qubit coupling, enabling faster charging and decoherence-resistant energy storage in a quantum battery.
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Nonlinear electron-phonon coupling drives light-induced symmetry switching in charge-density waves
Nonlinear electron-phonon interactions drive light-induced symmetry switching in charge-density waves, as captured by a new first-principles simulation framework that reproduces key experimental features in TiSe2.