High Capacity Noisy Unruh--DeWitt Quantum Channels with Bosonic
Dephasing
- URL: http://arxiv.org/abs/2309.07218v1
- Date: Wed, 13 Sep 2023 18:00:01 GMT
- Title: High Capacity Noisy Unruh--DeWitt Quantum Channels with Bosonic
Dephasing
- Authors: Eric Aspling and Michael Lawler
- Abstract summary: UDW quantum gates provide a framework for evaluating quantum Shannon theory properties of qubit-field systems.
UDW quantum channels consist of qubits encoding/decoding quantum information onto/off of quantum fields.
We show that UDW quantum channels have an unexpected representation as certain bosonic dephasing channels with dephasing parameters.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Unruh--DeWitt (UDW) detectors implemented as UDW quantum gates provide a
framework for evaluating quantum Shannon theory properties of qubit-field
systems. UDW quantum channels consist of qubits encoding/decoding quantum
information onto/off of quantum fields. With the controlled unitary structure
of UDW gates, the encoding/decoding process happens on the diagonals of the
coherent state density matrix describing the field. However, given the
non-orthogonality of coherent states the output of UDW channels consists of
unwanted states and unwanted mixing of states that lower the channel capacity.
In idealized models, these appear in the off-diagonals and diagonals of the
field's density matrix in the coherent state basis. For this reason, we show
that UDW quantum channels have an unexpected representation as certain bosonic
dephasing channels with dephasing parameters captured by a combination of the
coupling, smearing, and switching functions of the UDW detector model. We
demonstrate the unexpected consequence that a larger dephasing parameter
results in higher channel capacity and helps alleviate unwanted state mixing.
We illustrate these properties through two examples: inserting an additional
ideal dephasing channel into the quantum channel and inserting cross-talk noise
via a third UDW gate. Remarkably, the cross-talk noise channel qualitatively
improves a lower bound on the quantum capacity suggesting UDW gates will have
unexpected performance improvements if realized in condensed matter
experiments.
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