Linearly polarized light breaks spin-sector symmetry in d-wave altermagnets, inducing transitions from quantum spin Hall to spin-polarized Chern insulator to trivial states, with all anomalous transport coefficients showing d-wave angular dependence and some becoming quantized.
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Nonlinear thermal and thermoelectric responses are shown to encode quantum geometry and satisfy relations parallel to the Wiedemann-Franz and Mott laws in systems with broken symmetries.
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Light-Induced Topological Phase Transitions and Anomalous Thermal Transport in d-Wave Altermagnets
Linearly polarized light breaks spin-sector symmetry in d-wave altermagnets, inducing transitions from quantum spin Hall to spin-polarized Chern insulator to trivial states, with all anomalous transport coefficients showing d-wave angular dependence and some becoming quantized.
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Nonlinear thermal and thermoelectric transport from quantum geometry
Nonlinear thermal and thermoelectric responses are shown to encode quantum geometry and satisfy relations parallel to the Wiedemann-Franz and Mott laws in systems with broken symmetries.