QUANTUM MONTE CARLO STUDY OF BOSONIC LATTICE SYSTEMS IN THE PRESENCE OF DISORDER

dc.contributor.advisorBarboza, Bruno
dc.contributor.advisorCapogrosso-Sansone, Barbara
dc.contributor.advisorBlume, Doerte
dc.contributor.advisorSchwettmann, Arne
dc.contributor.advisorNeeman, Henry
dc.contributor.authorZhang, Chao
dc.date.accessioned2018-09-06T15:39:25Z
dc.date.available2018-09-06T15:39:25Z
dc.date.issued2018-08-30
dc.date.manuscript2018-08-30
dc.description.abstractDisorder is ubiquitous in condensed matter systems, but a thorough understanding of these systems is hindered by poor control over the nature of disorder and competing interactions. Ultracold gases trapped in optical lattices, on the other hand, offer an unprecedented level of control over interactions and disorder, and are ideal candidates to test theoretical predictions and study fascinating phenomena resulting from the interplay between disorder, interaction, and quantum degeneracy. In this dissertation, I present my research on strongly correlated many-body lattice bosons in the presence of disordered potentials. My results are based on quantum Monte Carlo simulations by the Worm algorithm. Experimentally, lattice bosons can be realized by ultracold gases in optical lattices. I studied the ground state phase diagram of the above systems in the presence of diagonal (quasi-periodic disordered potential or random disordered potential) and off-diagonal disorder (in the form of site dilution). First, I will discuss the ground state phase diagram of two-dimensional bosons in quasi-periodic lattices. Then, I will discuss the phase diagram as well as finite temperature thermodynamic properties of two-dimensional dipolar lattice bosons in the presence of random diagonal disordered potentials. Finally, I will discuss the phase diagram of two-dimensional hard-core lattice bosons system in the presence of long-range hopping and long-range two-body interactions both in the absence of disorder and in the presence of site dilution (equivalent to off-diagonal disorder). This system is equivalent to the long-range XXZ model as realized by polar molecules trapped in a deep optical lattice. These results provide theoretical guidance for experimentalists to find quantum phase transitions as well as exotic quantum phases in strongly correlated bosonic lattice systems.en_US
dc.identifier.urihttps://hdl.handle.net/11244/301627
dc.languageen_USen_US
dc.subjectMonte Carloen_US
dc.subjectDisorderen_US
dc.subjectMany-body systemen_US
dc.subjectBosonic lattice systemen_US
dc.thesis.degreePh.D.en_US
dc.titleQUANTUM MONTE CARLO STUDY OF BOSONIC LATTICE SYSTEMS IN THE PRESENCE OF DISORDERen_US
ou.groupCollege of Arts and Sciences::Homer L. Dodge Department of Physics and Astronomyen_US
shareok.nativefileaccessrestricteden_US
shareok.orcidhttps://orcid.org/0000-0001-9521-8624en_US

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