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- Temperature dependance of Intrinsic Spin Orbit Coupling Gap in Graphene probed by Terahertz photoconductivity doi link

Auteur(s): Maussang Kenneth, Dinar K., Bray C., Consejo C., Delgado-Notario J., Krishtopenko S., Yahniuk Ivan, Gerbert S., Ruffenach S., Moench E., Indykiewicz Kornelia, Benhamou-Bui Benjamin, Jouault B., Torres Jérémie, Meziani Y, Knap W., Yurgens A., Ganichev S., Teppe F.

Conference: 2023 48th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz) (Montréal, CA, 2023-09-17)


Ref HAL: hal-04304454_v1
DOI: 10.1109/irmmw-thz57677.2023.10299006
Exporter : BibTex | endNote
Résumé:

Graphene is a quantum spin Hall insulator, with a nontrivial topological gap induced by the spin-orbit coupling. Such splitting is weak (~45µeV) in the absence of external magnetic field. However, due to rather long spin-relaxation time, graphene is an attractive candidate for applications in quantum technologies. When it is encapsulated in hexagonal boron nitride, the coupling between graphene and the substrate compensates intrinsic spin-orbit coupling and decreases the nontrivial topological gap, which may lead to phase transition into a trivial band insulator state. In this work, we have measured experimentally the zero-field splittings in monolayer and bilayer graphene by the means of subterahertz photoconductivity-based electron spin resonance technique. The dependance in temperature of such splittings have been also studied in the 2-12K range. We observed a decrease of the spin splittings with increasing temperature. Such behavior might be understood from several physical mechanisms that could induce a temperature dependence of the spin-orbit coupling. These includes the difference in the expansion coefficients between the graphene and the boron nitride substrate or the metal contacts, the electronphonon interactions, and the presence of a magnetic order at low temperature.