Browsing by Author "Meng, Zi Yang"

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    Quantum Monte Carlo studies of novel phases in strongly correlated systems
    (2011) Meng, Zi Yang; Weßel, Stefan (Prof. Dr.)
    Three models of strongly correlated electron systems have been studied in this thesis: the Shastry-Sutherland quantum antiferromagnet, the quantum spin liquid emerging out of correlated Dirac fermions on the honeycomb lattice, and the edge-state magnetism in the graphene nanoribbons. The methods applied are quantum Monte Carlo simulations, namely, stochastic series expansion quantum Monte Carlo for bosonic (spin) systems and projector auxiliary field quantum Monte Carlo for fermionic systems. The stochastic series expansion quantum Monte Carlo method is applied to study the ground state properties as well as the magnetization process of the spin-1/2 easy-axis Heisenberg model on the Shastry-Sutherland lattice. The quantum phase transitions between a N\'eel state, a dimer triplet state and a ferromagnetic XY phase have been characterized by finite size scaling analysis. The crystalline structures of the triplon magnetic excitations in the magnetic plateaus have been identified. The projector auxiliary field quantum Monte Carlo is applied to explore the ground state phase diagram of the SU(2) Hubbard model on the honeycomb lattice. The interplay between the relativistic Dirac dispersion, the vanishing density of states at half-filling and the strong quantum fluctuations, drives the system from a semimetal at weak coupling to an antiferromagnetic Mott insulator in the strong coupling regime. In between these phases there emerges an unexpected quantum spin liquid with no symmetry breaking in any channel. After careful finite size scaling analysis of various correlation functions, the quantum spin liquid phase is characterized as a short-range resonating valence bond state with a finite spin gap to all magnetic excitations. The study of edge-state magnetism in graphene nanoribbons is more experimentally motivated. The projector auxiliary field quantum Monte Carlo method is used to measure the static spin-spin correlation function, the single-particle spectral function, as well as the dynamic spin structure factor along the zigzag edge of graphene nanoribbons. A dominant low energy peak generated by the Coulomb interaction in the single-particle spectral function is identified as the dynamical signature of edge-state magnetism. The magnetic excitations along the zigzag edge show a linear dispersion at low energies due to the effective antiferromagnetic coupling of the edges across the ribbon. The magnetic excitations are damped by scattering processes into the particle-hole continuum at high energies.