Efficient Temperature-Dependent Green’s Function Methods for Realistic Systems: Using Cubic Spline Interpolation to Approximate Matsubara Green’s Functions

Kananenka, Alexei A.; Welden, Alicia Rae; Lan, Tran Nguyen; Gull, Emanuel; Zgid, Dominika

doi:10.1021/acs.jctc.6b00178

Cited by 46 publications

(65 citation statements)

References 76 publications

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“…Self-consistent second order Green's function theory (GF2) is a second order perturbation theory which renormalizes the Green's function [24][25][26][27][28][29][30][31]. Self-consistent GW [15,17,[21][22][23] further renormalizes the interaction.…”

Section: Sparse Sampling Approach To Solving Diagrammatic Equationsmentioning

confidence: 99%

“…Applications to low-energy effective model Hamiltonians include lattice Monte Carlo [5], dynamical mean-field theory [6] with its cluster [7], multi-orbital extensions [8,9], and diagrammatic extensions [10][11][12], and diagrammatic or continuous-time quantum Monte Carlo methods [13,14]. In the context of ab initio calculations of correlated materials, examples include the GW method [15][16][17][18][19][20][21][22][23], the self-consistent second order approximation (GF2) [24][25][26][27][28][29][30][31], variants of the dynamical mean field theory [8,[32][33][34][35][36], and the self-energy embedding theory [37][38][39][40][41][42][43].…”

Section: Introductionmentioning

confidence: 99%

“…Compact representations of Green's functions are crucial to address this problem. Representations based on power meshes [44,45], Legendre polynomials [27,46], Chebyshev polynomials [47,48], intermediate numerical representations (IR) [49][50][51], quadrature rules [52,53], and spline interpolations [28] have been proposed, as well as high frequency tail expansions [54][55][56].…”

Section: Introductionmentioning

confidence: 99%

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Sparse sampling approach to efficient ab initio calculations at finite temperature

Wallerberger

Chikano

et al. 2020

Phys. Rev. B

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Efficient ab initio calculations of correlated materials at finite temperature require compact representations of the Green's functions both in imaginary time and Matsubara frequency. In this paper, we introduce a general procedure which generates sparse sampling points in time and frequency from compact orthogonal basis representations, such as Chebyshev polynomials and intermediate representation (IR) basis functions. These sampling points accurately resolve the information contained in the Green's function, and efficient transforms between different representations are formulated with minimal loss of information. As a demonstration, we apply the sparse sampling scheme to diagrammatic GW and GF2 calculations of a hydrogen chain, of noble gas atoms and of a silicon crystal.arXiv:1908.07575v1 [cond-mat.str-el]

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Section: Sparse Sampling Approach To Solving Diagrammatic Equationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sparse sampling approach to efficient ab initio calculations at finite temperature

Wallerberger

Chikano

et al. 2020

Phys. Rev. B

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“…Amending the representation with a low order high frequency expansion results in polynomial convergence [42][43][44] . In practice, this is problematic, since for systems with a wide range of energy scales, the number of coefficients is controlled by the largest energy scale 14 . Alternatives such as uniform power meshes have had some success 45,46 .…”

Section: Introductionmentioning

confidence: 99%

Legendre-spectral Dyson equation solver with super-exponential convergence

Dong

Zgid

Gull

et al. 2020

The Journal of Chemical Physics

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Quantum many-body systems in thermal equilibrium can be described by the imaginary time Green's function formalism. However, the treatment of large molecular or solid ab inito problems with a fully realistic Hamiltonian in large basis sets is hampered by the storage of the Green's function and the precision of the solution of the Dyson equation. We present a Legendre-spectral algorithm for solving the Dyson equation that addresses both of these issues. By formulating the algorithm in Legendre coefficient space, our method inherits the known faster-than-exponential convergence of the Green's function's Legendre series expansion. In this basis, the fast recursive method for Legendre polynomial convolution, enables us to develop a Dyson equation solver with quadratic scaling. We present benchmarks of the algorithm by computing the dissociation energy of the helium dimer He 2 within dressed second-order perturbation theory. For this system, the application of the Legendre spectral algorithm allows us to achieve an energy accuracy of 10 −9 E h with only a few hundred expansion coefficients. arXiv:2001.11603v2 [cond-mat.str-el] 5 Apr 2020

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“…Here, F weak tot denotes a solution of the entire system using a conserving low-order approximation, for instance self-consistent second order perturbation theory (GF2) [28][29][30][31][32][33] or the GW method [20]. F A denotes all those terms in Φ where all four indices i j k l , , , of v ijkl are contained inside orbital subspace A. F A weak is the approximation to F A within the weak coupling method used for solving the entire system, and F A strong the approximation or exact solution of F A obtained using the higher order method capable of describing 'strong correlation'.…”

Section: System and Formalismmentioning

confidence: 99%

Finite temperature quantum embedding theories for correlated systems

Zgid

Gull

2017

New J. Phys.

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The cost of the exact solution of the many-electron problem is believed to be exponential in the number of degrees of freedom, necessitating approximations that are controlled and accurate but numerically tractable. In this paper, we show that one of these approximations, the self-energy embedding theory (SEET), is derivable from a universal functional and therefore implicitly satisfies conservation laws and thermodynamic consistency. We also show how other approximations, such as the dynamical mean field theory and its combinations with many-body perturbation theory, can be understood as a special case of SEET and discuss how the additional freedom present in SEET can be used to obtain systematic convergence of results.

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Efficient Temperature-Dependent Green’s Function Methods for Realistic Systems: Using Cubic Spline Interpolation to Approximate Matsubara Green’s Functions

Cited by 46 publications

References 76 publications

Sparse sampling approach to efficient ab initio calculations at finite temperature

Sparse sampling approach to efficient ab initio calculations at finite temperature

Legendre-spectral Dyson equation solver with super-exponential convergence

Finite temperature quantum embedding theories for correlated systems

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