AI Article Synopsis
- Researchers generated spin-squeezed ground states in an atomic spin-1 Bose-Einstein condensate near a quantum-critical point using a new nonadiabatic technique.
- Unlike traditional methods that create squeezed states through rapid changes, these states are stable over time with a consistent squeezing angle.
- The study achieved 6-8 dB of squeezing and observed that even with a significant loss of atomic density, the squeezing gradually decreased without needing extra decoherence models.
Article Abstract
We generate spin squeezed ground states in an atomic spin-1 Bose-Einstein condensate tuned near the quantum-critical point separating the different spin phases of the interacting ensemble using a novel nonadiabatic technique. In contrast to typical nonequilibrium methods for preparing atomic squeezed states by quenching through a quantum phase transition, squeezed ground states are time stationary with a constant quadrature squeezing angle. A squeezed ground state with 6-8 dB of squeezing and a constant squeezing angle is demonstrated. The long-term evolution of the squeezed ground state is measured and shows gradual decrease in the degree of squeezing over 2 s that is well modeled by a slow tuning of the Hamiltonian due to the loss of atomic density. Interestingly, modeling the gradual decrease does not require additional spin decoherence models despite a loss of 75% of the atoms.
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| http://dx.doi.org/10.1103/PhysRevLett.131.133402 | DOI Listing |
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