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Project

Dynamics of Quantum Correlations

The main aim of this thesis is to study quantum dynamics, with a focus on irreversible, dissipative dynamics, by collecting repeated observations and arranging them to form a process. This leads to quantum states of extended models with some simplifying features. The models explored here are quantum spins on Fermionic lattices and chains of quantum spins. We focus in particular on the randomising properties of the dynamics.

The thesis begins by exploring the relation between the average von Neumann and Rényi entropies of integer orders for shift-invariant quasi-free Fermionic lattice systems. This then leads to an investigation into approximating the von Neumann entropy in terms of a combination of integer-order Rényi entropies and an estimate for the quality of such an approximation is given.

Later, a rather general technique is introduced to model a quantum system’s dynamics on a semi-infinite half-chain of quantum spins. Here, bounds are given for the average entropy of the model system as well as a general scheme for computing the average Rényi entropy of integer order of such models.

Finally, the half-chain model is made explicit with the example of a simple qubit evolving under a thermalising dissipative dynamics. With this example, the integer-order Rényi entropies are explicitly calculated. By optimising over all possible choices of models, a model-independent expression for the average Rényi entropies is derived.

Date:1 Oct 2008 →  24 Sep 2015
Keywords:Quantum correlations
Disciplines:Applied mathematics in specific fields, Elementary particle and high energy physics, Quantum physics, Astronomy and space sciences, Classical physics, Materials physics, Mathematical physics, Algebra, Atomic and molecular physics
Project type:PhD project