Liouville-Fock-State Lattices and the Limits of Spectral Chaos Diagnostics in Open Quantum Systems
by
A4:3001
AlbaNova Main Building
In this licenciate thesis, based on two articles, we discuss the properties of open quantum systems and investigate how their dynamics can be used to design a synthetic lattice framework and how their spectra behave based on two. The first article presents an extension of the Fock state lattice (FSL) framework to open quantum systems. Using the Liouville space representation, density matrices can be vectorized and the dynamics are generated by a linear operator, the Liouvillian, allowing for the introduction of Liouville-Fock state lattices (LFSLs). This framework provides an intuitive and visual understanding of the dynamics of open quantum systems and shows how environmental effects can give rise to phenomena such as directional transport, sources and sinks, typical phenomena occurring in classical processes. As an example, we show how frustration in LFSL can be induced by the environment. The second article in the work focuses on non-normality of Liouvillians and spectral diagnostics of chaos. Non-normal operators are characterized by the fact that their eigenvectors are not orthogonal, which leads to the spectrum exhibiting strong sensitivity to perturbations. We show that strong non-normality can give rise to random matrix-like spectral statistics without the system dynamics exhibiting chaotic signatures. Therefore, we conclude that this violates established assumptions and points to the need for alternative methods to characterize chaotic dynamics in open quantum systems.