Can a quantum nondemolition measurement improve the sensitivity of an atomic magnetometer?

Abstract

Noise properties of an idealized atomic magnetometer that utilizes spin squeezing induced by a continuous quantum nondemolition measurement are considered. Such a magnetometer measures spin precession of N atomic spins by detecting optical rotation of far-detuned light. Fundamental noise sources include the quantum projection noise and the photon shot-noise. For measurement times much shorter than the spin-relaxation time observed in the absence of light (τ rel) divided by N, the optimal sensitivity of the magnetometer scales as N-3/4, so an advantage over the usual sensitivity scaling as N-1/2 can be achieved. However, at longer measurement times, the optimized sensitivity scales as N-1/2, as for a usual shot-noise limited magnetometer. If strongly squeezed probe light is used, the Heisenberg uncertainty limit may, in principle, be reached for very short measurement times. However, if the measurement time exceeds τ rel/N, the N-1/2 scaling is again restored.

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