Refine
Has Fulltext
- yes (2)
Is part of the Bibliography
- yes (2)
Document Type
- Doctoral Thesis (2) (remove)
Language
- English (2) (remove)
Keywords
- QMC (2) (remove)
Institute
This thesis presents results covering several topics in correlated many fermion systems. A Monte Carlo technique (CT-INT) that has been implemented, used and extended by the author is discussed in great detail in chapter 3. The following chapter discusses how CT-INT can be used to calculate the two particle Green’s function and explains how exact frequency summations can be obtained. A benchmark against exact diagonalization is presented. The link to the dynamical cluster approximation is made in the end of chapter 4, where these techniques are of immense importance. In chapter 5 an extensive CT-INT study of a strongly correlated Josephson junction is shown. In particular, the signature of the first order quantum phase transition between a Kondo and a local moment regime in the Josephson current is discussed. The connection to an experimental system is made with great care by developing a parameter extraction strategy. As a final result, we show that it is possible to reproduce experimental data from a numerically exact CT-INT model-calculation. The last topic is a study of graphene edge magnetism. We introduce a general effective model for the edge states, incorporating a complicated interaction Hamiltonian and perform an exact diagonalization study for different parameter regimes. This yields a strong argument for the importance of forbidden umklapp processes and of the strongly momentum dependent interaction vertex for the formation of edge magnetism. Additional fragments concerning the use of a Legendre polynomial basis for the representation of the two particle Green’s function, the analytic continuation of the self energy for the Anderson Kane Mele Model, as well as the generation of test data with a given covariance matrix are documented in the appendix. A final appendix provides some very important matrix identities that are used for the discussion of technical details of CT-INT.
In a first part the bilayer Heisenberg Model and the 2D Kondo necklace model are studied. Both models exhibit a quantum phase transition between an ordered and disordered phase. The question is addressed to the coupling of a single doped hole to the critical fluctuations. A self-consistent Born approximation predicts that the doped hole couples to the magnons such that the quasiparticle residue vanishes at the quantum critical point. In this work the delicate question about the fate of the quasiparticle residue across the quantum phase transition is also tackled by means of large scale quantum Monte Carlo simulations. Furthermore the dynamics of a single hole doped in the magnetic background is investigated. In the second part an analysis of the spiral staircase Heisenberg ladder is presented. The ladder consists of two ferromagnetic coupled spin-1/2 chains, where the coupling within the second chain can be tuned by twisting the ladder. Within this model the crossover between an ungapped spin-1/2 system and a gapped spin-1 system can be studied. In this work the emphasis is on the opening of the spin gap with respect to the ferromagnetic rung coupling. It is shown that there are essential differences in the scaling behavior of the spin gap depending on the twist of the model. Moreover, by means of the string order parameter it is shown, that the system remains in the Haldane phase within the whole parameter range although the spin gap scales differently. The tools which are used for the analyses are mainly large scale quantum Monte Carlo methods, but also exact diagonalization techniques as well as mean field approaches.