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Quantum Algorithms
Information Scrambling in Bosonic Gaussian Dynamics
arXiv
Authors: Ali Mollabashi, Saleh Rahimi-Keshari
Year
2024
Paper ID
63991
Status
Preprint
Abstract Read
~2 min
Abstract Words
128
Citations
N/A
Abstract
We investigate the dynamics of information scrambling in bosonic systems undergoing Gaussian unitary evolution associated with quadratic Hamiltonians. For initial Gaussian states, we observe the disappearance of the memory effect in the entanglement dynamics of disjoint blocks under Gaussian random local dynamics. In addition, we show that randomness in the Hamiltonian causes the tripartite mutual information to saturate at relatively large negative values. Therefore, despite being integrable, these systems exhibit information-scrambling diagnostics that mirror those observed in chaotic systems. We note, however, that random quadratic Hamiltonians can have a component exhibiting Wigner-Dyson energy-level statistics; for non-Gaussian states within the corresponding subspace, these systems can display chaotic behavior. Our results provide insight into the Gaussian dynamics of continuous-variable systems, which are useful and available resources for quantum information processing.
Why This Paper Matters
- It adds a 2024 reference point for readers tracking recent quantum research.
- We investigate the dynamics of information scrambling in bosonic systems undergoing Gaussian unitary evolution associated with quadratic Hamiltonians.
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