Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields
Ultracold atoms have emerged as an indispensable setting to study quantum many-body systems. Recent experimental and theoretical work has explored the curious phases and novel properties of Bose-Einstein Condensate with optical lattices, and Bose-Einstein Condensate with light-induced artificial spi...
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ndltd-LSU-oai-etd.lsu.edu-etd-04142014-1046242014-05-03T03:56:59Z Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields Lu, Qinqin Physics & Astronomy Ultracold atoms have emerged as an indispensable setting to study quantum many-body systems. Recent experimental and theoretical work has explored the curious phases and novel properties of Bose-Einstein Condensate with optical lattices, and Bose-Einstein Condensate with light-induced artificial spin-orbit coupling. In this thesis, we report our research on these two types of boson systems. In the first topic, in contrast with calculations of bosons in optical lattices that focus on the tight-binding regime, we note that the single-particle states of bosons in a periodic potential generally satisfy the Mathieu equation, and have developed a formalism for studying bosons in an optical lattice using the Mathieu equation. Moreover, based on this formalism, we have proposed a self-consistent scheme for describing interacting bosons in an optical lattice using Hartree Fock approximation. We apply this scheme to quantify the effects of inter-atomic interactions on the properties of bosons in an optical lattice, as exhibited in the comparison between observables of non-interacting and interacting systems, such as the superfluid transition temperature and momentum distribution as probed in time-of-flight expansion. In the second topic, the phases of a Bose-Einstein condensate with light-induced spin-orbit coupling are studied within the mean-field approximation. We obtain the phase diagram at fixed chemical potential and at fixed density for bosons with spin-orbit coupling, finding a regime of phase separation and a regime in which the bosons condensed into a mixed phase. We determine how this phase diagram evolves as a function of the atom interaction parameters and as a function of the strength of light-atom coupling. The mixed phase is found to be stable for sufficiently small light-atom coupling. Specifically, we show that the structure of the phase diagram at fixed chemical potential suggests an unusual density dependence for the mixed phase in a harmonic trapping potential, in which the density of one spin increases with increasing radius, suggesting a unique experimental signature of this state. The collective Bogoliubov sound mode is shown to also provide a signature of the mixed phase, vanishing as the boundary to the regime of phase separation is approached. Together, in these two topics we address the need to enhance the understanding of the unconventional physical properties of Bose-Einstein Condensate in a controlled electromagnetic environment (optical lattices, Raman lasers, etc.), and provide predictions for possible experimental findings. Sheehy, Daniel E Schafer, Kenneth J Moreno, Juana Stadler, Shane Hayes, Daniel J LSU 2014-05-02 text application/pdf http://etd.lsu.edu/docs/available/etd-04142014-104624/ http://etd.lsu.edu/docs/available/etd-04142014-104624/ en unrestricted I hereby certify that, if appropriate, I have obtained and attached herein a written permission statement from the owner(s) of each third party copyrighted matter to be included in my thesis, dissertation, or project report, allowing distribution as specified below. I certify that the version I submitted is the same as that approved by my advisory committee. I hereby grant to LSU or its agents the non-exclusive license to archive and make accessible, under the conditions specified below and in appropriate University policies, my thesis, dissertation, or project report in whole or in part in all forms of media, now or hereafter known. I retain all other ownership rights to the copyright of the thesis, dissertation or project report. I also retain the right to use in future works (such as articles or books) all or part of this thesis, dissertation, or project report. |
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Physics & Astronomy Lu, Qinqin Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
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Ultracold atoms have emerged as an indispensable setting to study quantum many-body systems. Recent experimental and theoretical work has explored the curious phases and novel properties of Bose-Einstein Condensate with optical lattices, and Bose-Einstein Condensate with light-induced artificial spin-orbit coupling. In this thesis, we report our research on these two types of boson systems.
In the first topic, in contrast with calculations of bosons in optical lattices that focus on the tight-binding regime, we note that the single-particle states of bosons in a periodic potential generally satisfy the Mathieu equation, and have developed a formalism for studying bosons in an optical lattice using the Mathieu equation. Moreover, based on this formalism, we have proposed a self-consistent scheme for describing interacting bosons in an optical lattice using Hartree Fock approximation. We apply this scheme to quantify the effects of inter-atomic interactions on the properties of bosons in an optical lattice, as exhibited in the comparison between observables of non-interacting and interacting systems, such as the superfluid transition temperature and momentum distribution as probed in time-of-flight expansion.
In the second topic, the phases of a Bose-Einstein condensate with light-induced spin-orbit coupling are studied within the mean-field approximation. We obtain the phase diagram at fixed chemical potential and at
fixed density for bosons with spin-orbit coupling, finding a regime
of phase separation and a regime in which the bosons condensed into
a mixed phase. We determine how this phase
diagram evolves as a function of the atom interaction parameters
and as a function of the strength of light-atom coupling. The mixed phase is found to be stable for sufficiently small
light-atom coupling. Specifically, we show that the structure of the phase
diagram at fixed chemical potential suggests an unusual density
dependence for the mixed phase in a harmonic trapping
potential, in which the density of
one spin increases with increasing radius, suggesting a unique experimental signature of this state. The collective Bogoliubov sound mode is shown to also provide a signature of the mixed phase, vanishing as the boundary to the regime of phase separation is approached.
Together, in these two topics we address the need to enhance the understanding of the unconventional physical properties of Bose-Einstein Condensate in a controlled electromagnetic environment (optical lattices, Raman lasers, etc.), and provide predictions for possible experimental findings. |
author2 |
Sheehy, Daniel E |
author_facet |
Sheehy, Daniel E Lu, Qinqin |
author |
Lu, Qinqin |
author_sort |
Lu, Qinqin |
title |
Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
title_short |
Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
title_full |
Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
title_fullStr |
Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
title_full_unstemmed |
Phases of Bosons in Optical Lattices and Coupled to Artificial Gauge Fields |
title_sort |
phases of bosons in optical lattices and coupled to artificial gauge fields |
publisher |
LSU |
publishDate |
2014 |
url |
http://etd.lsu.edu/docs/available/etd-04142014-104624/ |
work_keys_str_mv |
AT luqinqin phasesofbosonsinopticallatticesandcoupledtoartificialgaugefields |
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1716666307487727616 |