Investigations of transport phenomena and dynamical relaxation in closed quantum systems

Khodja, Abdellah

17 March 2015

The first part of the present Phd thesis is devoted to transport investigations in disordered quantum systems. We aim at quantitatively determining transport parameters like conductivity, mean free path, etc., for simple models of spatially disordered and/or percolated quantum systems in the limit of high temperatures and low fillings using linear response theory. We find the transport behavior for some models to be in accord with a Boltzmann equation, i.e., long mean free paths, exponentially decaying currents although there are no band-structures to start from, while this does not apply to other models even though they are also almost completely delocalized. The second part of the present PhD thesis addresses the issue of initial state independence (ISI) in closed quantum system. The relevance of the eigenstate thermalization hypothesis (ETH) for the emergence of ISI equilibration is to some extent addressed. To this end, we investigate the Heisenberg spin-ladder and check the validity of the ETH for the energy difference operator by examining the scaling behavior of the corresponding ETH-fluctuations, which we compute using an innovative numerical method based on typicality related arguments. While, the ETH turns out to hold for the generic non-integrable models and may therefore serve as the key mechanism for ISI for this cases, it does not hold for the integrable Heisenberg-chain. However, close analysis on the dynamic of substantially out-of-equilibrium initial states indicates the occurrence of ISI equillibration in the thermodynamic limit regardless of whether the ETH is violated. Thus, we introduce a new parameter $v$, which we propose as an alternative of the ETH to indicate ISI equillibration in cases, in which the ETH does not strictly apply.

transport coefficients

Boltzmann equation

eigenstate thermalization hypothesis

33.23 - Quantenphysik

33.10 - Theoretische Physik: Allgemeines

33.66 - Amorpher Zustand, Gläser

ddc:530

Aspects of Non-Equilibrium Behavior in Isolated Quantum Systems

Heveling, Robin

06 September 2022

Based on the publications [P1–P6], the cumulative dissertation at hand addresses quite diverse aspects of non-equilibrium behavior in isolated quantum systems. The works presented in publications [P1, P2] concern the issue of finding generally valid upper bounds on equilibration times, which ensure the eventual occurrence of equilibration in isolated quantum systems. Recently, a particularly compelling bound for physically relevant observables has been proposed. Said bound is examined analytically as well as numerically. It is found that the bound fails to give meaningful results in a number of standard physical scenarios. Continuing, publication [P4] examines a particular integral fluctuation theorem (IFT) for the total entropy production of a small system coupled to a substantially larger but finite bath. While said IFT is known to hold for canonical states, it is shown to be valid for microcanonical and even pure energy eigenstates as well by invoking the physically natural conditions of “stiffness” and “smoothness” of transition probabilities. The validity of the IFT and the existence of stiffness and smoothness are numerically investigated for various lattice models. Furthermore, this dissertation puts emphasis on the issue of the route to equilibrium, i.e., to explain the omnipresence of certain relaxation dynamics in nature, while other, more exotic relaxation patterns are practically never observed, even though they are a priori not disfavored by the microscopic laws of motion. Regarding this question, the existence of stability in a larger class of dynamics consisting of exponentially damped oscillations is corroborated in publication [P6]. In the same vein, existing theories on the ubiquity of certain dynamics are numerically scrutinized in publication [P3]. Finally, in publication [P5], the recently proposed “universal operator growth hypothesis”, which characterizes the complexity growth of operators during unitary time evolution, is numerically probed for various spin-based systems in the thermodynamic limit. The hypothesis is found to be valid within the limits of the numerical approach.

Non-Equilibrium Physics

Statistical Physics

Quantum Mechanics

33.23 - Quantenphysik

ddc:530

Atomic Scale Images of Acceptors in III-V Semiconductors / Band Bending, Tunneling Paths and Wave Functions

Loth, Sebastian

26 October 2007

No description available.

530 Physik

Mathematics and Computer Science

scanning tunneling microscopy

semiconductors

surfaces

defects

acceptors

electronic band structure

GaAs

InAs

Rastertunnelmikroskopie

Halbleiter

Oberflächen

Defekte

Akzeptoren

Elektronische Bandstruktur

GaAs

InAs

33.72

33.23

33.68

magnetische und optische Eigenschaften}

Thermodynamic and spectral properties of quantum many-particle systems / Thermodynamische und spektrale Eigenschaften quantenmechanischer Vielteilchensysteme

Fuchs, Sebastian

21 January 2011

No description available.

530 Physik

Physics

Hubbard-Modell

Maximum-Entropie

Quanten-Monte-Carlo

kalte Atome

korrelierte Elektronen

Hubbard model

maximum entropy

quantum Monte Carlo

quantum cluster theories

dynamical cluster appoximation

cold atoms

correlated electrons

33.61

33.10

33.06

33.23

33.25

RDI 700: Statistische Physik

Quantenstatistik

RLA 000: Tieftemperaturphysik