On the dynamics of initially correlated open quantum systems: theory and applications

TL;DR

This paper develops a framework for describing the dynamics of initially correlated open quantum systems using a set of completely positive maps, enabling the application of existing tools and experimental characterization methods to complex quantum states.

Contribution

It introduces a set of completely positive maps to describe initially correlated quantum system dynamics, extending analysis and control techniques to more general initial states.

Findings

The dynamics can be described by a reduced set of CP maps.

Experimental characterization of these maps is feasible via local operations.

Protocols for retrodicting and tomography of correlated states are proposed and simulated.

Abstract

We show that the dynamics of any open quantum system that is initially correlated with its environment can be described by a set of (or less) completely positive maps, where d is the dimension of the system. Only one such map is required for the special case of no initial correlations. The same maps describe the dynamics of any system-environment state obtained from the initial state by a local operation on the system. The reduction of the system dynamics to a set of completely positive maps allows known numerical and analytic tools for uncorrelated initial states to be applied to the general case of initially correlated states, which we exemplify by solving the qubit dephasing model for such states, and provides a natural approach to quantum Markovianity for this case. We show that this set of completely positive maps can be experimentally characterised using only local operations on the system, via a generalisation of noise spectroscopy protocols. As further applications, we first consider the problem of retrodicting the dynamics of an open quantum system which is in an arbitrary state when it becomes accessible to the experimenter, and explore the conditions under which retrodiction is possible. We also introduce a related one-sided or limited-access tomography protocol for determining an arbitrary bipartite state, evolving under a sufficiently rich Hamiltonian, via local operations and measurements on just one component. We simulate this protocol for a physical model of particular relevance to nitrogen-vacancy centres, and in particular show how to reconstruct the density matrix of a set of three qubits, interacting via dipolar coupling and in the presence of local magnetic fields, by measuring and controlling only one of them.