Molecular many-body interactions resurrect polaritonic double-quantum coherences in strong coupling via the resonance condition Δ_B + 4J = Ω_R that exploits spatial mismatch to break harmonic cancellation.
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Mapping cavity-mediated collective electron correlations in molecular ensembles to the spherical Sherrington-Kirkpatrick model predicts paracorrelated and spin-glass phases with an entropy-driven localization mechanism.
Magnetic cavity coupling renders H2 ground states metastable, inverts singlet-triplet gaps, and stabilizes exotic antiaromatic states in rings like H4 and C4H4 by preventing Jahn-Teller distortions.
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Universal Scaling and Many-Body Resurrection of Polaritonic Double-Quantum Coherences
Molecular many-body interactions resurrect polaritonic double-quantum coherences in strong coupling via the resonance condition Δ_B + 4J = Ω_R that exploits spatial mismatch to break harmonic cancellation.
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Cavity-mediated localization and collective electron correlation phases
Mapping cavity-mediated collective electron correlations in molecular ensembles to the spherical Sherrington-Kirkpatrick model predicts paracorrelated and spin-glass phases with an entropy-driven localization mechanism.
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Engineering molecular potential energy surfaces using magnetic cavity quantum electrodynamics
Magnetic cavity coupling renders H2 ground states metastable, inverts singlet-triplet gaps, and stabilizes exotic antiaromatic states in rings like H4 and C4H4 by preventing Jahn-Teller distortions.