Alterelectricity is introduced as switchable states with alternating band structures arising from sublattice-selective structural changes related by non-inversion symmetry, with realizations in bilayer sliding and ferroelectric materials plus a proposed tunnel junction application.
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3 Pith papers cite this work. Polarity classification is still indexing.
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cond-mat.mtrl-sci 3years
2026 3verdicts
UNVERDICTED 3representative citing papers
Cobalt doping converts FeSb2 into a metallic altermagnet with infrared-visible spin-split bands persisting to room temperature.
Graphene antidot superlattices develop interaction-induced i-wave altermagnetic spin splitting from their intrinsic magnetic instability.
citing papers explorer
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Alterelectricity: Electrical Analogue of Altermagnetism
Alterelectricity is introduced as switchable states with alternating band structures arising from sublattice-selective structural changes related by non-inversion symmetry, with realizations in bilayer sliding and ferroelectric materials plus a proposed tunnel junction application.
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From Narrow-gap Semiconductor to Metallic Altermagnet: Optical Fingerprints of Co-Doped FeSb2
Cobalt doping converts FeSb2 into a metallic altermagnet with infrared-visible spin-split bands persisting to room temperature.
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Intrinsic i-wave altermagnetism in 2D graphene superlattices
Graphene antidot superlattices develop interaction-induced i-wave altermagnetic spin splitting from their intrinsic magnetic instability.