Neutron powder diffraction shows Rb1-xV2Te2O orders in a G-type antiferromagnetic structure below 337 K, contrary to prior theoretical predictions for its altermagnetic properties.
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Symmetry matching between altermagnets and unconventional superconductors generates bulk zero-energy flat bands as Bogoliubov Fermi surfaces and distinct curved or flat surface states detectable by tunneling.
NV-center quantum relaxometry encodes momentum-space anisotropy of altermagnetic spin diffusion, enabling local distinction from antiferromagnets.
citing papers explorer
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G-type antiferromagnetic structure in Rb1-xV2Te2O
Neutron powder diffraction shows Rb1-xV2Te2O orders in a G-type antiferromagnetic structure below 337 K, contrary to prior theoretical predictions for its altermagnetic properties.
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Engineering subgap states in superconductors by the symmetry of altermagnetism
Symmetry matching between altermagnets and unconventional superconductors generates bulk zero-energy flat bands as Bogoliubov Fermi surfaces and distinct curved or flat surface states detectable by tunneling.
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Quantum-impurity sensing of altermagnetic order
NV-center quantum relaxometry encodes momentum-space anisotropy of altermagnetic spin diffusion, enabling local distinction from antiferromagnets.