Abstract
Electrical transport property is closely related to the dimensionality of carriers’ distribution. In this work, we succeed in tuning the carriers’ distribution and the Rashba spin–orbit coupling at LaAlO3/SrTiO3 interface by varying the oxygen pressure (c-PO2) adopted in crystalline LaAlO3 growth. Measurements of the in-plane anisotropic magnetoresistance and the conducting-layer thickness indicate that the carriers’ distribution changes from three to two dimensions with c-PO2 increasing, i.e. the electron confinement gets stronger. Importantly, by measuring the low-temperature out-of-plane magnetoresistance and analyzing the weak localization/weak anti-localization, we find that the strength of Rashba spin–orbit coupling can be enhanced by electron confinement. The electron confinement is a manifestation of breaking of spatial inversion symmetry. Therefore, our work reveals the intimate relationship between spatial inversion symmetry breaking and Rashba spin–orbit coupling at the LaAlO3/SrTiO3 interface, and provides a new method to tune the Rashba spin–orbit coupling, which is valuable in the application of oxide-spintronics.
Published Version
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