Quantum Spin Dynamics in a Normal Bose Gas with Spin-Orbit Coupling

Realization of the quantum spin Hall effect in graphene devices has remained an outstanding challenge dating back to the inception of the field of topological insulators. Graphene’s exceptionally weak spin-orbit coupling—stemming from carbon’s low mass—poses the primary obstacle. We experimentally and theoretically study artificially enhanced spin-orbit coupling in graphene via random decoration with dilute Bi2Te3 nanoparticles. Multiterminal resistance measurements suggest the presence of helical edge states characteristic of a quantum spin Hall phase; the magnetic field and temperature dependence of the resistance peaks, x-ray photoelectron spectra, scanning tunneling spectroscopy, and first-principles calculations further support this scenario. These observations highlight a pathway to spintronics and quantum information applications in graphene-based quantum spin Hall platforms.

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Critical temperature of pair condensation in a dilute Bose gas with spin–orbit coupling

International Journal of Modern Physics B ◽

10.1142/s0217979217450126 ◽

2017 ◽

Vol 31 (25) ◽

pp. 1745012 ◽

Cited By ~ 1

Author(s):

Dekun Luo ◽

Lan Yin

Keyword(s):

Critical Temperature ◽

Bose Gas ◽

Orbit Coupling ◽

Einstein Condensation ◽

Spin Orbit Coupling ◽

Spin Orbit ◽

Pairing State ◽

Dilute Gas ◽

Pair Condensation ◽

Dilute Limit

We study the Bardeen–Cooper–Shrieffer (BCS) pairing state of a two-component Bose gas with a symmetric spin–orbit coupling (SOC). In the dilute limit at low temperature, this system is essentially a dilute gas of diatomic molecules. We compute the effective mass of the molecule and find that it is anisotropic in momentum space. The critical temperature of the pairing state is about eight times smaller than the Bose–Einstein condensation (BEC) transition temperature of an ideal Bose gas with the same density.

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Electronic theory for the normal-state spin dynamics inSr2RuO4:Anisotropy due to spin-orbit coupling

Physical Review B ◽

10.1103/physrevb.65.220502 ◽

2002 ◽

Vol 65 (22) ◽

Cited By ~ 40

Author(s):

I. Eremin ◽

D. Manske ◽

K. H. Bennemann

Keyword(s):

Normal State ◽

Spin Dynamics ◽

Orbit Coupling ◽

Spin Orbit Coupling ◽

Spin Orbit ◽

Electronic Theory ◽

State Spin

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Direct observation of topological edge states in silicon photonic crystals: Spin, dispersion, and chiral routing

Science Advances ◽

10.1126/sciadv.aaw4137 ◽

2020 ◽

Vol 6 (10) ◽

pp. eaaw4137 ◽

Cited By ~ 14

Author(s):

Nikhil Parappurath ◽

Filippo Alpeggiani ◽

L. Kuipers ◽

Ewold Verhagen

Keyword(s):

Photonic Crystals ◽

Quantum Spin ◽

Orbit Coupling ◽

Far Field ◽

Spin Orbit Coupling ◽

Topological Order ◽

Spin Orbit ◽

Edge States ◽

Linear Dispersion ◽

Silicon Photonic

Topological protection in photonics offers new prospects for guiding and manipulating classical and quantum information. The mechanism of spin-orbit coupling promises the emergence of edge states that are helical, exhibiting unidirectional propagation that is topologically protected against back scattering. We directly observe the topological states of a photonic analog of electronic materials exhibiting the quantum spin Hall effect, living at the interface between two silicon photonic crystals with different topological order. Through the far-field radiation that is inherent to the states’ existence, we characterize their properties, including linear dispersion and low loss. We find that the edge state pseudospin is encoded in unique circular far-field polarization and linked to unidirectional propagation, thus revealing a signature of the underlying photonic spin-orbit coupling. We use this connection to selectively excite different edge states with polarized light and directly visualize their routing along sharp chiral waveguide junctions.

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