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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Surface altermagnetism with d-wave spin splitting occurs in centrosymmetric collinear antiferromagnets only when no sublattice-exchanging antiunitary symmetry survives at the surface, as shown by symmetry analysis and first-principles calculations on V3Al and BaMn2Sb2 versus MnPt.
Magnons in triangular-lattice Heisenberg antiferromagnets carry perpendicular magnetic moments, realizing f-wave antialtermagnets whose nonlinear thermal transport effects provide detectable signatures.
EuAgAs exhibits a near-degenerate magnetic ground state with an observed antiferromagnetic order that DFT predicts can be tuned to altermagnetism under hydrostatic pressure of approximately 14 GPa.
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.
A repulsive Hubbard term selects topologically nontrivial pairing over the trivial one in singular-interaction superconductors, with the transition passing through a topology-induced time-reversal symmetry breaking phase.
citing papers explorer
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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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$d$-wave Surface Altermagnetism in Centrosymmetric Collinear Antiferromagnets
Surface altermagnetism with d-wave spin splitting occurs in centrosymmetric collinear antiferromagnets only when no sublattice-exchanging antiunitary symmetry survives at the surface, as shown by symmetry analysis and first-principles calculations on V3Al and BaMn2Sb2 versus MnPt.
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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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Near-degenerate competing magnetic orders in EuAgAs: a tunable route to altermagnetism
EuAgAs exhibits a near-degenerate magnetic ground state with an observed antiferromagnetic order that DFT predicts can be tuned to altermagnetism under hydrostatic pressure of approximately 14 GPa.
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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.
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Topologically non-trivial gap function and topology-induced time-reversal symmetry breaking in a superconductor with singular dynamical interaction
A repulsive Hubbard term selects topologically nontrivial pairing over the trivial one in singular-interaction superconductors, with the transition passing through a topology-induced time-reversal symmetry breaking phase.