Litcius/Paper detail

Quasiparticle interference and quantum confinement in a correlated Rashba spin-split 2D electron liquid

Chi Ming Yim, Dibyashree Chakraborti, Luke C. Rhodes, Seunghyun Khim, Andrew P. Mackenzie, Peter Wahl

2021Science Advances20 citationsDOIOpen Access PDF

Abstract

Exploiting inversion symmetry breaking (ISB) in systems with strong spin-orbit coupling promises control of spin through electric fields-crucial to achieve miniaturization in spintronic devices. Delivering on this promise requires a two-dimensional electron gas with a spin precession length shorter than the spin coherence length and a large spin splitting so that spin manipulation can be achieved over length scales of nanometers. Recently, the transition metal oxide terminations of delafossite oxides were found to exhibit a large Rashba spin splitting dominated by ISB. In this limit, the Fermi surface exhibits the same spin texture as for weak ISB, but the orbital texture is completely different, raising questions about the effect on quasiparticle scattering. We demonstrate that the spin-orbital selection rules relevant for conventional Rashba system are obeyed as true spin selection rules in this correlated electron liquid and determine its spin coherence length from quasiparticle interference imaging.

Topics & Concepts

Condensed matter physicsSpintronicsQuasiparticlePhysicsSpin (aerodynamics)Coherence (philosophical gambling strategy)SpinplasmonicsSpin wavePoint reflectionSpin crossoverSpin polarizationElectronFerromagnetismSpin engineeringT-symmetryCoherence lengthRashba effectMiniaturizationFermi gasMagnonicsSpin Hall effectQuantum dotInterference (communication)Coherence timeQuantum spin liquidSpin diffusionFermi surfaceCoupling (piping)Fermi Gamma-ray Space TelescopeQuantumWeak localizationCoherent controlMaterials scienceFermi levelStrongly correlated materialQuantum and electron transport phenomenaSurface and Thin Film PhenomenaCopper-based nanomaterials and applications