Abstract
AbstractWe consider the numerical solution of the real-time equilibrium Dyson equation, which is used in calculations of the dynamical properties of quantum many-body systems. We show that this equation can be written as a system of coupled, nonlinear, convolutional Volterra integro-differential equations, for which the kernel depends self-consistently on the solution. As is typical in the numerical solution of Volterra-type equations, the computational bottleneck is the quadratic-scaling cost of history integration. However, the structure of the nonlinear Volterra integral operator precludes the use of standard fast algorithms. We propose a quasilinear-scaling FFT-based algorithm which respects the structure of the nonlinear integral operator. The resulting method can reach large propagation times and is thus well-suited to explore quantum many-body phenomena at low energy scales. We demonstrate the solver with two standard model systems: the Bethe graph and the Sachdev-Ye-Kitaev model.
Publisher
Springer Science and Business Media LLC
Subject
Applied Mathematics,Computational Mathematics
Reference69 articles.
1. Abrikosov, A.A., Gorkov, L.P., Dzyaloshinski, I.E.: Methods of quantum field theory in statistical physics. Dover Publications (1965)
2. Fetter, A.L., Walecka, J. D.: Quantum theory of many-particle systems. Dover Publications (2003)
3. Negele, J.W., Orland, H.: Quantum many-particle systems. Westview Press (1998)
4. Stefanucci, G., van Leeuwen, R.: Nonequilibrium many-body theory of quantum systems: a modern introduction. Cambridge University Press (2013)
5. Dahlen, N.-E., van Leeuwen, R.: Self-consistent solution of the Dyson equation for atoms and molecules within a conserving approximation. J. Chem. Phys. 122(16), 164102 (2005)
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