Static lattice distortions from adiabatic electron-phonon coupling act as a tuning knob that alters the magnitude, anisotropy, phase, and chirality of noncollinear RKKY couplings in Rashba d-wave altermagnets.
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A symmetry-based stacking strategy with layer-flip realizes odd-parity altermagnetism from nonrelativistic orbital orders, hosting quantum spin Hall phases with helical edge states.
Layer stacking in tetragonal altermagnetic bilayers imposes symmetry constraints that enable tuning of spin and valley degrees of freedom via interlayer sliding and external electric fields, producing spontaneous valley splitting and enhanced TMR.
citing papers explorer
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RKKY interaction in altermagnets with adiabatic electron-phonon coupling
Static lattice distortions from adiabatic electron-phonon coupling act as a tuning knob that alters the magnitude, anisotropy, phase, and chirality of noncollinear RKKY couplings in Rashba d-wave altermagnets.
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Odd-Parity Altermagnetism Originated from Orbital Orders
A symmetry-based stacking strategy with layer-flip realizes odd-parity altermagnetism from nonrelativistic orbital orders, hosting quantum spin Hall phases with helical edge states.
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Layer-mediated tuning of spin and valley physics in stacked tetragonal altermagnetic bilayers
Layer stacking in tetragonal altermagnetic bilayers imposes symmetry constraints that enable tuning of spin and valley degrees of freedom via interlayer sliding and external electric fields, producing spontaneous valley splitting and enhanced TMR.