In d-wave altermagnets the leading intrinsic anomalous thermal Hall effect appears at third order in temperature gradient and is governed by a nonlinear thermal Berry-connection polarizability that encodes the quantum metric.
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Magnons in triangular-lattice Heisenberg antiferromagnets carry perpendicular magnetic moments, realizing f-wave antialtermagnets whose nonlinear thermal transport effects provide detectable signatures.
Correlated dephasing of two spin qubits near materials isolates rotational symmetry in nonlocal noise correlations, enabling discrimination of s-, d-, and g-wave superconducting gaps and altermagnet types at nanoscale and low frequencies.
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Intrinsic anomalous thermal hall effect as a signature of quantum metric in d-wave altermagnets
In d-wave altermagnets the leading intrinsic anomalous thermal Hall effect appears at third order in temperature gradient and is governed by a nonlinear thermal Berry-connection polarizability that encodes the quantum metric.
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Nonlinear Magnon Magnetic Moment Transport in Triangular-Lattice f-Wave Antialtermagnets
Magnons in triangular-lattice Heisenberg antiferromagnets carry perpendicular magnetic moments, realizing f-wave antialtermagnets whose nonlinear thermal transport effects provide detectable signatures.
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Correlated Quantum Dephasometry: Symmetry-Resolved Noise Spectroscopy of Two-Dimensional Superconductors and Altermagnets
Correlated dephasing of two spin qubits near materials isolates rotational symmetry in nonlocal noise correlations, enabling discrimination of s-, d-, and g-wave superconducting gaps and altermagnet types at nanoscale and low frequencies.