Time discretization of functional integrals

Abstract

Numerical evaluation of functional integrals usually involves a finite (L-slice) discretization of the imaginary-time axis. In the auxiliary-field method, the L-slice approximant to the density matrix can be evaluated as a function of inverse temperature at any finite L as L(β)=[1(β/L)]L, if the density matrix 1(β) in the static approximation is known. We investigate the convergence of the partition function ZL(β)=TrL(β), the internal energy and the density of states gL(E) (the inverse Laplace transform of ZL), as L∞. For the simple harmonic oscillator, gL(E) is a normalized truncated Fourier series for the exact density of states. When the auxiliary-field approach is applied to spin systems, approximants to the density of states and heat capacity can be negative. Approximants to the density matrix for a spin-1/2 dimer are found in closed form for all L by appending a self-interaction to the divergent Gaussian integral and analytically continuing to zero self-interaction. Because of this continuation, the coefficient of the singlet projector in the approximate density matrix can be negative. For a spin dimer, ZL is an even function of the coupling constant for L<3: ferromagnetic and antiferromagnetic coupling can be distinguished only for L 3, where a Berry phase appears in the functional integral. At any non-zero temperature, the exact partition function is recovered as L∞.

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