Litcius/Paper detail

Acoustic spin-Chern insulator induced by synthetic spin–orbit coupling with spin conservation breaking

Weiyin Deng, Xueqin Huang, Jiuyang Lu, Valerio Peri, Feng Li, Sebastian D. Huber, Zhengyou Liu

2020Nature Communications87 citationsDOIOpen Access PDF

Abstract

Topologically protected surface modes of classical waves hold the promise to enable a variety of applications ranging from robust transport of energy to reliable information processing networks. However, both the route of implementing an analogue of the quantum Hall effect as well as the quantum spin Hall effect are obstructed for acoustics by the requirement of a magnetic field, or the presence of fermionic quantum statistics, respectively. Here, we construct a two-dimensional topological acoustic crystal induced by the synthetic spin-orbit coupling, a crucial ingredient of topological insulators, with spin non-conservation. Our setup allows us to free ourselves of symmetry constraints as we rely on the concept of a non-vanishing "spin" Chern number. We experimentally characterize the emerging boundary states which we show to be gapless and helical. More importantly, we observe the spin flipping transport in an H-shaped device, demonstrating evidently the spin non-conservation of the boundary states.

Topics & Concepts

Topological insulatorPhysicsGapless playbackSpin (aerodynamics)Quantum spin Hall effectCoupling (piping)Condensed matter physicsBoundary (topology)Spin Hall effectQuantumSpin engineeringQuantum Hall effectMagnetic fieldQuantum mechanicsSpin polarizationElectronMaterials scienceMathematical analysisThermodynamicsMetallurgyMathematicsTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsQuantum many-body systems