The geometric decoherence time marks the earliest breakdown of the monotone relation between logarithmic negativity and Rényi-1/2 entropy under Lindbladian evolution, serving as a dynamical scale for the onset of decoherence.
Lindblad Equation for the Inelastic Loss of Ultracold Atoms
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abstract
The loss of ultracold trapped atoms due to deeply inelastic reactions has previously been taken into account in effective field theories for low-energy atoms by adding local anti-Hermitian terms to the effective Hamiltonian. Here we show that when multi-atom systems are considered, an additional modification is required in the equation governing the density matrix. We define an effective density matrix by tracing over the states containing high-momentum atoms produced by deeply inelastic reactions. We show that it satisfies a Lindblad equation, with local Lindblad operators determined by the local anti-Hermitian terms in the effective Hamiltonian. We use the Lindblad equation to derive the universal relation for the two-atom inelastic loss rate for fermions with two spin states and the universal relation for the three-atom inelastic loss rate for identical bosons.
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Geometric Decoherence Time in Lindbladian Dynamics
The geometric decoherence time marks the earliest breakdown of the monotone relation between logarithmic negativity and Rényi-1/2 entropy under Lindbladian evolution, serving as a dynamical scale for the onset of decoherence.