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Quantum Algorithms
Optical protection of alkali-metal atoms from spin relaxation
arXiv
Authors: Avraham Berrebi, Mark Dikopoltsev, Ori Katz, Or Katz
Year
2022
Paper ID
58971
Status
Preprint
Abstract Read
~2 min
Abstract Words
114
Citations
N/A
Abstract
We present an optical technique for suppressing relaxation in alkali-metal spins using a single off-resonant laser beam. The method harnesses a physical mechanism that synchronizes Larmor precession in the two hyperfine manifolds, protecting magnetic coherence from relaxation caused by spin-exchange and other hyperfine-changing collisions. We experimentally demonstrate up to a ninefold reduction in decoherence of warm cesium vapor, achieving simultaneous protection from both spin-exchange relaxation and partial depolarization from coated cell walls. The technique substantially enhances the spin precession quality factor and maintains a stable gyromagnetic ratio independent of spin polarization, even under frequent collisions. These findings offer a pathway for mitigating dominant relaxation channels in alkali-metal-based applications and experiments, particularly in anti-relaxation-coated cells.
Why This Paper Matters
- It adds a 2022 reference point for readers tracking recent quantum research.
- We present an optical technique for suppressing relaxation in alkali-metal spins using a single off-resonant laser beam.
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