Partitioned Density Matrices and Entanglement Correlators
Abstract
The density matrix of a non-relativistic quantum system, divided into sub-systems, is rewritten in terms of the set of all partitioned density matrices for the system. For the case where the different sub-systems are distinguishable, we derive a hierarchy of equations of motion linking the dynamics of all the partitioned density matrices, analogous to the "Schwinger-Dyson" hierarchy in quantum field theory. The special case of a set of coupled spin- "qubits" is worked out in detail. The equations are then rewritten in terms of a set of "entanglement correlators", which comprise all the possible correlation functions for the system - this case is worked out for coupled spin systems. The equations of motion for these correlators can be written in terms of a first-order differential equation for an entanglement correlator supervector.
Cite
@article{arxiv.1808.01054,
title = {Partitioned Density Matrices and Entanglement Correlators},
author = {Timothy Cox and Philip C. E. Stamp},
journal= {arXiv preprint arXiv:1808.01054},
year = {2018}
}