Nuclear spin squeezing by continuous quantum non-demolition measurement: a theoretical study

We propose to take advantage of the weak coupling of ground-state helium-3 nuclear spin to its environment to produce long-lived macroscopic quantum states, nuclear spin squeezed states, in a gas cell at room temperature. To perform a quantum non-demolition measurement of a transverse component of the polarized collective nuclear spin, we maintain a population in helium-3 metastable state with a discharge. The collective spin associated to F=1/2 metastable level hybridizes with the ground state one by metastability exchange collisions. To access nuclear spin fluctuations, one continuously measures the light leaking out of an optical cavity, where it has interacted dispersively with the metastable state collective spin. In a three coupled collective spin model (nuclear, metastable and Stokes), we calculate moments of the nuclear spin squeezed component I_z conditioned on the time averaged optical signal. In the photon counting scheme, the squeezed observable is I_z² rather than I_z. In the homodyne detection scheme, we solve the stochastic equation for the system state conditioned on the measurement; the conditional expectation value of I_z depends linearly on the signal and the conditional variance of I_z does not depend on it. The conditional variance decreases as \(Γ_{rm sq}t\)^-1, where the squeezing rate Γ_{rm sq} depends linearly on the light intensity in the cavity at weak atom-field coupling and saturates at strong coupling to the ground state metastability exchange effective rate, proportional to the metastable atom density. Including de-excitation of metastable atoms at the walls, which induces nuclear spin decoherence with an effective rate γ_α, we find a limit propto\(γ_α/Γ_{rm sq}\)^1/2 on the conditional variance reached in a time propto\(γ_αΓ_{rm sq}\)^-1/2.