Relaxation in harmonic oscillator systems and wave propagation in negative index materials

This dissertation is divided up into two parts, each examining a distinct theme. The rst part of our work concerns itself with open quantum systems and the relaxation phenomena arising from the repeated application of an interaction Hamiltonian on systems composed of quantum harmonic oscillators. F...

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Main Author: Chimonidou, Antonia
Format: Others
Language:English
Published: 2010
Subjects:
Online Access:http://hdl.handle.net/2152/7574
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spelling ndltd-UTEXAS-oai-repositories.lib.utexas.edu-2152-75742015-09-20T16:53:47ZRelaxation in harmonic oscillator systems and wave propagation in negative index materialsChimonidou, AntoniaOpen quantum systemsRelaxation phenomenaQuantum harmonic oscillatorsWave propagationNegative electric permeabilityMagnetic permeabilityInteraction HamiltonianThis dissertation is divided up into two parts, each examining a distinct theme. The rst part of our work concerns itself with open quantum systems and the relaxation phenomena arising from the repeated application of an interaction Hamiltonian on systems composed of quantum harmonic oscillators. For the second part of our work, we shift gears and investigate the wave propagation in left-handed media, or materials with simultaneously negative electric permeability and magnetic permeability . Each of these two parts is complete within its own context. In the rst part of this dissertation, we introduce a relaxation-generating model which we use to study the process by which quantum correlations are created when an interaction Hamiltonian is repeatedly applied to bipartite harmonic oscillator systems for some characteristic time interval . The two important time scales which enter our results are discussed in detail. We show that the relaxation time obtained by the application of this repeated interaction scheme is proportional to both the strength of interaction and to the characteristic time interval . Through discussing the implications of our model, we show that, for the case where the oscillator frequencies are equal, the initial Maxwell-Boltzmann distributions of the uncoupled parts evolve to a new Maxwell-Boltzmann distribution through a series of transient Maxwell-Boltzmann distributions, or quasi-stationary, non-equilibrium states. We further analyze the case in which the two oscillator frequencies are unequal and show how the application of the same model leads to a non-thermal steady state. The calculations are exact and the results are obtained through an iterative process, without using perturbation theory. In the second part of this dissertation, we examine the response of a plane wave incident on a at surface of a left-handed material, a medium characterized by simultaneously negative electric permittivity and magnetic permeability . We do this by solving Maxwell's equations explicitly. In the literature up to date, it has been assumed that negative refractive materials are necessarily frequency dispersive. We propose an alternative to this assumption by suggesting that the requirement of positive energy density can be relaxed, and discuss the implications of such a proposal. More speci cally, we show that once negative energy solutions are accepted, the requirement for frequency dispersion is no longer needed. We further argue that, for the purposes of discussing left-handed materials, the use of group velocity as the physically signi cant quantity is misleading, and suggest that any discussion involving it should be carefully reconsidered.text2010-06-02T18:28:08Z2010-06-02T18:28:08Z2009-052010-06-02T18:28:08Zelectronichttp://hdl.handle.net/2152/7574engCopyright is held by the author. Presentation of this material on the Libraries' web site by University Libraries, The University of Texas at Austin was made possible under a limited license grant from the author who has retained all copyrights in the works.
collection NDLTD
language English
format Others
sources NDLTD
topic Open quantum systems
Relaxation phenomena
Quantum harmonic oscillators
Wave propagation
Negative electric permeability
Magnetic permeability
Interaction Hamiltonian
spellingShingle Open quantum systems
Relaxation phenomena
Quantum harmonic oscillators
Wave propagation
Negative electric permeability
Magnetic permeability
Interaction Hamiltonian
Chimonidou, Antonia
Relaxation in harmonic oscillator systems and wave propagation in negative index materials
description This dissertation is divided up into two parts, each examining a distinct theme. The rst part of our work concerns itself with open quantum systems and the relaxation phenomena arising from the repeated application of an interaction Hamiltonian on systems composed of quantum harmonic oscillators. For the second part of our work, we shift gears and investigate the wave propagation in left-handed media, or materials with simultaneously negative electric permeability and magnetic permeability . Each of these two parts is complete within its own context. In the rst part of this dissertation, we introduce a relaxation-generating model which we use to study the process by which quantum correlations are created when an interaction Hamiltonian is repeatedly applied to bipartite harmonic oscillator systems for some characteristic time interval . The two important time scales which enter our results are discussed in detail. We show that the relaxation time obtained by the application of this repeated interaction scheme is proportional to both the strength of interaction and to the characteristic time interval . Through discussing the implications of our model, we show that, for the case where the oscillator frequencies are equal, the initial Maxwell-Boltzmann distributions of the uncoupled parts evolve to a new Maxwell-Boltzmann distribution through a series of transient Maxwell-Boltzmann distributions, or quasi-stationary, non-equilibrium states. We further analyze the case in which the two oscillator frequencies are unequal and show how the application of the same model leads to a non-thermal steady state. The calculations are exact and the results are obtained through an iterative process, without using perturbation theory. In the second part of this dissertation, we examine the response of a plane wave incident on a at surface of a left-handed material, a medium characterized by simultaneously negative electric permittivity and magnetic permeability . We do this by solving Maxwell's equations explicitly. In the literature up to date, it has been assumed that negative refractive materials are necessarily frequency dispersive. We propose an alternative to this assumption by suggesting that the requirement of positive energy density can be relaxed, and discuss the implications of such a proposal. More speci cally, we show that once negative energy solutions are accepted, the requirement for frequency dispersion is no longer needed. We further argue that, for the purposes of discussing left-handed materials, the use of group velocity as the physically signi cant quantity is misleading, and suggest that any discussion involving it should be carefully reconsidered. === text
author Chimonidou, Antonia
author_facet Chimonidou, Antonia
author_sort Chimonidou, Antonia
title Relaxation in harmonic oscillator systems and wave propagation in negative index materials
title_short Relaxation in harmonic oscillator systems and wave propagation in negative index materials
title_full Relaxation in harmonic oscillator systems and wave propagation in negative index materials
title_fullStr Relaxation in harmonic oscillator systems and wave propagation in negative index materials
title_full_unstemmed Relaxation in harmonic oscillator systems and wave propagation in negative index materials
title_sort relaxation in harmonic oscillator systems and wave propagation in negative index materials
publishDate 2010
url http://hdl.handle.net/2152/7574
work_keys_str_mv AT chimonidouantonia relaxationinharmonicoscillatorsystemsandwavepropagationinnegativeindexmaterials
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