Your search keyword '"Assaad, F. F."' showing total 5 results

1. The ALF (Algorithms for Lattice Fermions) project release 2.0. Documentation for the auxiliary-field quantum Monte Carlo code

Author

ALF Collaboration, Assaad, F. F., Bercx, M., Goth, F., Götz, A., Hofmann, J. S., Huffman, E., Liu, Z., Toldin, F. Parisen, Portela, J. S. E., Schwab, J., ALF Collaboration, Assaad, F. F., Bercx, M., Goth, F., Götz, A., Hofmann, J. S., Huffman, E., Liu, Z., Toldin, F. Parisen, Portela, J. S. E., and Schwab, J.

Abstract

The Algorithms for Lattice Fermions package provides a general code for the finite-temperature and projective auxiliary-field quantum Monte Carlo algorithm. The code is engineered to be able to simulate any model that can be written in terms of sums of single-body operators, of squares of single-body operators and single-body operators coupled to a bosonic field with given dynamics. The package includes five pre-defined model classes: SU(N) Kondo, SU(N) Hubbard, SU(N) t-V and SU(N) models with long range Coulomb repulsion on honeycomb, square and N-leg lattices, as well as $Z_2$ unconstrained lattice gauge theories coupled to fermionic and $Z_2$ matter. An implementation of the stochastic Maximum Entropy method is also provided. One can download the code from our Git instance at https://git.physik.uni-wuerzburg.de/ALF/ALF/-/tree/ALF-2.0 and sign in to file issues., Comment: 121 pages, 11 figures. v3: quick tutorial section added, typos corrected, etc. Submission to SciPost. arXiv admin note: text overlap with arXiv:1704.00131

Published

2020

2. The ALF (Algorithms for Lattice Fermions) project release 2.4. Documentation for the auxiliary-field quantum Monte Carlo code

Author

ALF Collaboration, Assaad, F. F., Bercx, M., Goth, F., Götz, A., Hofmann, J. S., Huffman, E., Liu, Z., Toldin, F. Parisen, Portela, J. S. E., Schwab, J., ALF Collaboration, Assaad, F. F., Bercx, M., Goth, F., Götz, A., Hofmann, J. S., Huffman, E., Liu, Z., Toldin, F. Parisen, Portela, J. S. E., and Schwab, J.

Abstract

The Algorithms for Lattice Fermions package provides a general code for the finite-temperature and projective auxiliary-field quantum Monte Carlo algorithm. The code is engineered to be able to simulate any model that can be written in terms of sums of single-body operators, of squares of single-body operators and single-body operators coupled to a bosonic field with given dynamics. The package includes five pre-defined model classes: SU(N) Kondo, SU(N) Hubbard, SU(N) t-V and SU(N) models with long range Coulomb repulsion on honeycomb, square and N-leg lattices, as well as $Z_2$ unconstrained lattice gauge theories coupled to fermionic and $Z_2$ matter. An implementation of the stochastic Maximum Entropy method is also provided. One can download the code from our Git instance at https://git.physik.uni-wuerzburg.de/ALF/ALF/-/tree/ALF-2.4 and sign in to file issues., Comment: 126 pages, 12 figures. v7: update do ALF 2.4. Submission to SciPost. This article supersedes arXiv:1704.00131

Published

2020

3. Phase diagram of the Kane-Mele-Coulomb model

Author

Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., Assaad, F. F., Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., and Assaad, F. F.

Abstract

We determine the phase diagram of the Kane-Mele model with a long-range Coulomb interaction using an exact quantum Monte Carlo method. Long-range interactions are expected to play a role in honeycomb materials because the vanishing density of states in the semimetallic weak-coupling phase suppresses screening. According to our results, the Kane-Mele-Coulomb model supports the same phases as the Kane-Mele-Hubbard model. The nonlocal part of the interaction promotes short-range sublattice charge fluctuations, which compete with antiferromagnetic order driven by the onsite repulsion. Consequently, the critical interaction for the magnetic transition is significantly larger than for the purely local Hubbard repulsion. Our numerical data are consistent with $SU(2)$ Gross-Neveu universality for the semimetal to antiferromagnet transition, and with 3D XY universality for the quantum spin Hall to antiferromagnet transition., Comment: 9 pages, 7 figures

Published

2014

4. Phase diagram of the Kane-Mele-Coulomb model

Author

Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., Assaad, F. F., Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., and Assaad, F. F.

Abstract

We determine the phase diagram of the Kane-Mele model with a long-range Coulomb interaction using an exact quantum Monte Carlo method. Long-range interactions are expected to play a role in honeycomb materials because the vanishing density of states in the semimetallic weak-coupling phase suppresses screening. According to our results, the Kane-Mele-Coulomb model supports the same phases as the Kane-Mele-Hubbard model. The nonlocal part of the interaction promotes short-range sublattice charge fluctuations, which compete with antiferromagnetic order driven by the onsite repulsion. Consequently, the critical interaction for the magnetic transition is significantly larger than for the purely local Hubbard repulsion. Our numerical data are consistent with $SU(2)$ Gross-Neveu universality for the semimetal to antiferromagnet transition, and with 3D XY universality for the quantum spin Hall to antiferromagnet transition., Comment: 9 pages, 7 figures

Published

2014

5. Phase diagram of the Kane-Mele-Coulomb model

Author

Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., Assaad, F. F., Hohenadler, M., Toldin, F. Parisen, Herbut, I. F., and Assaad, F. F.

Abstract

We determine the phase diagram of the Kane-Mele model with a long-range Coulomb interaction using an exact quantum Monte Carlo method. Long-range interactions are expected to play a role in honeycomb materials because the vanishing density of states in the semimetallic weak-coupling phase suppresses screening. According to our results, the Kane-Mele-Coulomb model supports the same phases as the Kane-Mele-Hubbard model. The nonlocal part of the interaction promotes short-range sublattice charge fluctuations, which compete with antiferromagnetic order driven by the onsite repulsion. Consequently, the critical interaction for the magnetic transition is significantly larger than for the purely local Hubbard repulsion. Our numerical data are consistent with $SU(2)$ Gross-Neveu universality for the semimetal to antiferromagnet transition, and with 3D XY universality for the quantum spin Hall to antiferromagnet transition., Comment: 9 pages, 7 figures

Published

2014