Return to search

Emergent Low Temperature Phases in Strongly Correlated Multi-orbital and Cold Atom Systems

This thesis considers various strongly correlated quantum phases in solid state and cold atom spin systems.
In the first part we focus on phases emerging in multi-orbital materials.
We study even-parity spin-triplet superconductivity originating from Hund's coupling between t2g orbitals and investigate the effect of spin-orbit interaction on spin-triplet and spin-singlet pairing.
Various aspects of the pairing state are discussed against the backdrop of the spin-triplet superconductor Sr2RuO4.

Motivated by the remarkable phenomena observed in the bilayer compound Sr3Ru2O7, which point to the formation of an electronic nematic phase in the presence of critical fluctuations, we investigate how such a broken symmetry state emerges from electronic interactions.
Since the broken x-y symmetry is revealed experimentally by applying a small in-plane
magnetic field component, we examine nematic phases in a bilayer system and the role of the in-plane magnetic field using a phenomenological approach.
In addition, we propose a microscopic mechanism for nematic phase formation
specific to Sr3Ru2O7.
The model is based on a realistic multi-orbital band structure and local and nearest neighbour interactions.
Considering all t2g-orbital derived bands on an equal footing, we find a nematic quantum critical point and a nearby meta-nematic transition in the phase diagram.
This finding harbours important implications for the phenomena observed in Sr3Ru2O7.

The second part is devoted to the study of the anisotropic bilinear biquadratic spin-1 Heisenberg model, where the existence of an unusual direct phase transition between a spin-nematic phase and a dimerized valence bond solid phase in the quasi-1D limit was conjectured based on Quantum Monte Carlo simulations.
We establish the quasi-1D phase diagram using a large-N Schwinger boson approach and show that the phase transition is largely conventional except possibly at two particular points.
We further discuss how to realize and to detect such phases in an optical lattice.

Identiferoai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/32317
Date26 March 2012
CreatorsPuetter, Christoph Minol
ContributorsKee, Hae-Young
Source SetsUniversity of Toronto
LanguageEnglish
Detected LanguageEnglish
TypeThesis

Page generated in 0.0092 seconds