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Robust weak antilocalization due to spin-orbital entanglement in Dirac material Sr3SnO

H. Nakamura, D. Huang, J. Merz, E. Khalaf, P. Ostrovsky, A. Yaresko, D. Samal, H. Takagi

2020Nature Communications43 citationsDOIOpen Access PDF

Abstract

Abstract The presence of both inversion ( P ) and time-reversal ( T ) symmetries in solids leads to a double degeneracy of the electronic bands (Kramers degeneracy). By lifting the degeneracy, spin textures manifest themselves in momentum space, as in topological insulators or in strong Rashba materials. The existence of spin textures with Kramers degeneracy, however, is difficult to observe directly. Here, we use quantum interference measurements to provide evidence for the existence of hidden entanglement between spin and momentum in the antiperovskite-type Dirac material Sr 3 SnO. We find robust weak antilocalization (WAL) independent of the position of E F . The observed WAL is fitted using a single interference channel at low doping, which implies that the different Dirac valleys are mixed by disorder. Notably, this mixing does not suppress WAL, suggesting contrasting interference physics compared to graphene. We identify scattering among axially spin-momentum locked states as a key process that leads to a spin-orbital entanglement.

Topics & Concepts

PhysicsTopological insulatorQuantum entanglementDirac (video compression format)Homogeneous spaceSpin (aerodynamics)Quantum mechanicsInterference (communication)Degeneracy (biology)Dirac fermionScatteringMomentum (technical analysis)Weak localizationCondensed matter physicsQuantumPoint reflectionQuantum interferenceWeak measurementTopology (electrical circuits)Mixing (physics)Inversion (geology)Aharonov–Bohm effectGrapheneZeeman effectSymmetry (geometry)Quantum dotObservableSpin structureAngular momentumSpintronicsTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsRare-earth and actinide compounds