English

Dynamically decoupled three-body interactions with applications to interaction-based quantum metrology

Quantum Gases 2014-11-06 v1 Quantum Physics

Abstract

We propose a stroboscopic method to dynamically decouple the effects of two-body atom-atom interactions for ultracold atoms, and realize a system dominated by elastic three-body interactions. Using this method, we show that it is possible to achieve the optimal scaling behavior predicted for interaction-based quantum metrology with three-body interactions. Specifically, we show that for ultracold atoms quenched in an optical lattice, we can measure the three-body interaction strength with a precision proportional to nˉ5/2{\bar n}^{-5/2} using homodyne quadrature interferometry, and nˉ7/4{\bar n}^{-7/4} using conventional collapse-and-revival techniques, where nˉ{\bar n} is the mean number of atoms per lattice site. Both precision scalings surpass the nonlinear scaling of nˉ3/2{\bar n}^{-3/2}, the best so far achieved or proposed with a physical system. Our method of achieving a decoupled three-body interacting system may also have applications in the creation of exotic three-body states and phases.

Keywords

Cite

@article{arxiv.1408.2775,
  title  = {Dynamically decoupled three-body interactions with applications to interaction-based quantum metrology},
  author = {K. W. Mahmud and E. Tiesinga and P. R. Johnson},
  journal= {arXiv preprint arXiv:1408.2775},
  year   = {2014}
}

Comments

5 pages, 4 figures

R2 v1 2026-06-22T05:26:48.001Z