English

Self-Organization in Cold Atoms Mediated by Diffractive Coupling

Pattern Formation and Solitons 2021-05-19 v1 Atomic Physics Optics Quantum Physics

Abstract

This article discusses self-organization in cold atoms via light-mediated interactions induced by feedback from a single retro-reflecting mirror. Diffractive dephasing between the pump beam and the spontaneous sidebands selects the lattice period. Spontaneous breaking of the rotational and translational symmetry occur in the 2D plane transverse to the pump. We elucidate how diffractive ripples couple sites on the self-induced atomic lattice. The nonlinear phase shift of the atomic cloud imprinted onto the optical beam is the parameter determining coupling strength. The interaction can be tailored to operate either on external degrees of freedom leading to atomic crystallization for thermal atoms and supersolids for a quantum degenerate gas, or on internal degrees of freedom like populations of the excited state or Zeeman sublevels. Using the light polarization degrees of freedom on the Poincar{\'e} sphere (helicity and polarization direction), specific irreducible tensor components of the atomic Zeeman states can be coupled leading to spontaneous magnetic ordering of states of dipolar and quadrupolar nature. The requirements for critical interaction strength are compared for the different situations. Connections and extensions to longitudinally pumped cavities, counterpropagating beam schemes and the CARL instability are discussed.

Keywords

Cite

@article{arxiv.2105.08340,
  title  = {Self-Organization in Cold Atoms Mediated by Diffractive Coupling},
  author = {Thorsten Ackemann and Guillaume Labeyrie and Giuseppe Baio and Ivor Krešić and Josh G. M. Walker and Adrian Costa Boquete and Paul Griffin and William J. Firth and Robin Kaiser and Gian-Luca Oppo and Gordon R. M. Robb},
  journal= {arXiv preprint arXiv:2105.08340},
  year   = {2021}
}
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