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Legendre-spectral Dyson equation solver with super-exponential convergence

Xinyang Dong, Dominika Zgid, Emanuel Gull, Hugo U. R. Strand

2020The Journal of Chemical Physics32 citationsDOIOpen Access PDF

Abstract

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 initio 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 He2 within dressed second-order perturbation theory. For this system, the application of the Legendre spectral algorithm allows us to achieve an energy accuracy of 10−9Eh with only a few hundred expansion coefficients.

Topics & Concepts

Legendre polynomialsSolverMathematicsApplied mathematicsQuadratic equationBasis functionConvergence (economics)Hamiltonian (control theory)Polynomial expansionLegendre's equationPolynomialAssociated Legendre polynomialsDifferential equationLegendre functionMathematical analysisPartial differential equationSpherical harmonicsTaylor seriesSeries expansionPolytropeFunction (biology)Adiabatic processPerturbation (astronomy)Potential energyInterpolation (computer graphics)Quadratic functionHamiltonian systemQuantum, superfluid, helium dynamicsQuantum Mechanics and Non-Hermitian PhysicsQuantum many-body systems
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