Xing K, Creedon DL, Yianni SA, Akhgar G, Zhang L, Ley L, McCallum JC, Qi DC, Pakes CI (2020)
Publication Type: Journal article
Publication year: 2020
Book Volume: 164
Pages Range: 244-250
DOI: 10.1016/j.carbon.2020.03.047
Hydrogen-terminated diamond possesses an intriguing p-type surface conductivity which is induced via thermodynamically driven electron transfer from the diamond surface into surface acceptors such as atmospheric adsorbates, a process called surface transfer doping. High electron affinity transition metal oxides (TMOs) including MoO3 and V2O5 have been shown to be highly effective solid-state surface acceptors for diamond, giving rise to a sub-surface two-dimensional (2D) hole layer with metallic conduction. In this work, low temperature magnetotransport is used as a tool to show the presence of a Rashba-type spin-orbit interaction with a high spin-orbit coupling of 19.9 meV for MoO3 doping and 22.9 meV for V2O5 doping, respectively, through the observation of a transition in the phase-coherent backscattering transport from weak localization to weak antilocalization at low temperature. Surface transfer doping of diamond with TMOs provides a 2D hole system with spin-orbit coupling that is over two times larger than that reported for diamond surfaces with atmospheric acceptors, opening up possibilities to study and engineer spin transport in a carbon material system.
APA:
Xing, K., Creedon, D.L., Yianni, S.A., Akhgar, G., Zhang, L., Ley, L.,... Pakes, C.I. (2020). Strong spin-orbit interaction induced by transition metal oxides at the surface of hydrogen-terminated diamond. Carbon, 164, 244-250. https://doi.org/10.1016/j.carbon.2020.03.047
MLA:
Xing, Kaijian, et al. "Strong spin-orbit interaction induced by transition metal oxides at the surface of hydrogen-terminated diamond." Carbon 164 (2020): 244-250.
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