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Optimized Double-well quantum interferometry with Gaussian squeezed-states

Quantum Physics 2009-11-13 v2

Abstract

A Mach-Zender interferometer with a gaussian number-difference squeezed input state can exhibit sub-shot-noise phase resolution over a large phase-interval. We obtain the optimal level of squeezing for a given phase-interval Δθ0\Delta\theta_0 and particle number NN, with the resulting phase-estimation uncertainty smoothly approaching 3.5/N3.5/N as Δθ0\Delta\theta_0 approaches 10/N, achieved with highly squeezed states near the Fock regime. We then analyze an adaptive measurement scheme which allows any phase on (π/2,π/2)(-\pi/2,\pi/2) to be measured with a precision of 3.5/N3.5/N requiring only a few measurements, even for very large NN. We obtain an asymptotic scaling law of Δθ(2.1+3.2ln(ln(NtottanΔθ0)))/Ntot\Delta\theta\approx (2.1+3.2\ln(\ln(N_{tot}\tan\Delta\theta_0)))/N_{tot}, resulting in a final precision of 10/Ntot\approx 10/N_{tot}. This scheme can be readily implemented in a double-well Bose-Einstein condensate system, as the optimal input states can be obtained by adiabatic manipulation of the double-well ground state.

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Cite

@article{arxiv.0709.2143,
  title  = {Optimized Double-well quantum interferometry with Gaussian squeezed-states},
  author = {Y. P. Huang and M. G. Moore},
  journal= {arXiv preprint arXiv:0709.2143},
  year   = {2009}
}

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updated version

R2 v1 2026-06-21T09:17:19.747Z