Spin-orbit interaction and topological phases at correlated oxide interfaces
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2024
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30/01/2024
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Universidad Complutense de Madrid
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Abstract
Recientemente los materiales cuánticos han ganado relevancia en la física del estado sólido debido a su capacidad para mostrar fenómenos cuánticos emergentes. Muchos de estos fenómenos provienen del acoplamiento espín-órbita, una interacción cuántica relativista que vincula el movimiento orbital de los electrones con su espín, generando fases electrónicas inusuales y comportamientos magnéticos poco convencionales...
Recently, quantum materiales have gained relevance in solid-state physics because of their ability to manifest emergent quantum phenomena. Many of these phenomena arise from split-orbit coupling, a relativistic quantum interaction that links the orbital motion of electrons to their spin, generating unusual electronic phases and unconventional magetic behaviour...
Recently, quantum materiales have gained relevance in solid-state physics because of their ability to manifest emergent quantum phenomena. Many of these phenomena arise from split-orbit coupling, a relativistic quantum interaction that links the orbital motion of electrons to their spin, generating unusual electronic phases and unconventional magetic behaviour...
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Tesis inédita de la Universidad Complutense de Madrid, Facultad de Ciencias Físicas, leída el 30-01-2024