Research output: Contribution to journal › Article

**Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support.** / Booth, George.

Research output: Contribution to journal › Article

Booth, G 2020, 'Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support', *Physical Review B*.

Booth, G. (Accepted/In press). Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support. *Physical Review B*.

Booth G. Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support. Physical Review B. 2020 Jan 10.

@article{1d5deb1de50246949803ce36d417d3bd,

title = "Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support",

abstract = "We demonstrate an algebraic construction of frequency-dependent bath orbitalswhich can be used in a robust and rigorously self-consistent DMFT-like embedding method, here called wdmft, suitable for use with Hamiltonian-based impurity solvers. These bath orbitals are designed to exactly reproduce the hybridization of the impurity to its environment, while allowing for a systematic expansion of this bath space as impurity interactions couple frequency points. In this way, the difficult non-linear fit of bath parameters necessary for many Hamiltonian-formulation impurity solvers in DMFT is avoided, while the introduction of frequency dependence in this bath space is shown to allow for more compact bath sizes. This has significant potential use with a number of new, emerging Hamiltonian solvers which allow for the embedding of large impurity spaces within a DMFT framework. We present results of the wdmft approach for the Hubbard model on the Bethe lattice, a 1D chain, and the 2D square lattice, which show excellent agreement with standard DMFT results, with fewer bath orbitals and more compact support for the hybridization representation in the key impurity model of the method.",

author = "George Booth",

year = "2020",

month = jan,

day = "10",

language = "English",

journal = "Physical Review B (Condensed Matter and Materials Physics)",

issn = "1098-0121",

publisher = "American Physical Society",

}

TY - JOUR

T1 - Frequency-dependent and algebraic bath states for a Dynamical Mean-Field Theory with compact support

AU - Booth, George

PY - 2020/1/10

Y1 - 2020/1/10

N2 - We demonstrate an algebraic construction of frequency-dependent bath orbitalswhich can be used in a robust and rigorously self-consistent DMFT-like embedding method, here called wdmft, suitable for use with Hamiltonian-based impurity solvers. These bath orbitals are designed to exactly reproduce the hybridization of the impurity to its environment, while allowing for a systematic expansion of this bath space as impurity interactions couple frequency points. In this way, the difficult non-linear fit of bath parameters necessary for many Hamiltonian-formulation impurity solvers in DMFT is avoided, while the introduction of frequency dependence in this bath space is shown to allow for more compact bath sizes. This has significant potential use with a number of new, emerging Hamiltonian solvers which allow for the embedding of large impurity spaces within a DMFT framework. We present results of the wdmft approach for the Hubbard model on the Bethe lattice, a 1D chain, and the 2D square lattice, which show excellent agreement with standard DMFT results, with fewer bath orbitals and more compact support for the hybridization representation in the key impurity model of the method.

AB - We demonstrate an algebraic construction of frequency-dependent bath orbitalswhich can be used in a robust and rigorously self-consistent DMFT-like embedding method, here called wdmft, suitable for use with Hamiltonian-based impurity solvers. These bath orbitals are designed to exactly reproduce the hybridization of the impurity to its environment, while allowing for a systematic expansion of this bath space as impurity interactions couple frequency points. In this way, the difficult non-linear fit of bath parameters necessary for many Hamiltonian-formulation impurity solvers in DMFT is avoided, while the introduction of frequency dependence in this bath space is shown to allow for more compact bath sizes. This has significant potential use with a number of new, emerging Hamiltonian solvers which allow for the embedding of large impurity spaces within a DMFT framework. We present results of the wdmft approach for the Hubbard model on the Bethe lattice, a 1D chain, and the 2D square lattice, which show excellent agreement with standard DMFT results, with fewer bath orbitals and more compact support for the hybridization representation in the key impurity model of the method.

M3 - Article

JO - Physical Review B (Condensed Matter and Materials Physics)

JF - Physical Review B (Condensed Matter and Materials Physics)

SN - 1098-0121

ER -

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