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Designing spin and orbital sources of Berry curvature at oxide interfaces

Edouard Lesne, Yildiz G. Saǧlam, Raffaele Battilomo, Maria Teresa Mercaldo, Thierry C. van Thiel, Ulderico Filippozzi, Canio Noce, Mario Cuoco, Gary A. Steele, Carmine Ortix, Andrea D. Caviglia

2023Nature Materials67 citationsDOIOpen Access PDF

Abstract

Abstract Quantum materials can display physical phenomena rooted in the geometry of electronic wavefunctions. The corresponding geometric tensor is characterized by an emergent field known as the Berry curvature (BC). Large BCs typically arise when electronic states with different spin, orbital or sublattice quantum numbers hybridize at finite crystal momentum. In all the materials known to date, the BC is triggered by the hybridization of a single type of quantum number. Here we report the discovery of the first material system having both spin- and orbital-sourced BC: LaAlO 3 /SrTiO 3 interfaces grown along the [111] direction. We independently detect these two sources and probe the BC associated to the spin quantum number through the measurements of an anomalous planar Hall effect. The observation of a nonlinear Hall effect with time-reversal symmetry signals large orbital-mediated BC dipoles. The coexistence of different forms of BC enables the combination of spintronic and optoelectronic functionalities in a single material.

Topics & Concepts

Berry connection and curvaturePhysicsCondensed matter physicsWave functionSpintronicsSpin (aerodynamics)DipoleSymmetry (geometry)QuantumQuantum Hall effectCurvatureQuantum numberQuantum mechanicsFerromagnetismGeometryMagnetic fieldMathematicsThermodynamicsElectronic and Structural Properties of OxidesAdvanced Condensed Matter PhysicsAtomic and Subatomic Physics Research
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