Spectral functions and time evolution from the Chebyshev recursion
Abstract
We link linear prediction of Chebyshev and Fourier expansions to analytic continuation. We push the resolution in the Chebyshev-based computation of many-body spectral functions to a much higher precision by deriving a modified Chebyshev series expansion that allows to reduce the expansion order by a factor . We show that in a certain limit the Chebyshev technique becomes equivalent to computing spectral functions via time evolution and subsequent Fourier transform. This introduces a novel recursive time evolution algorithm that instead of the group operator only involves the action of the generator . For quantum impurity problems, we introduce an adapted discretization scheme for the bath spectral function. We discuss the relevance of these results for matrix product state (MPS) based DMRG-type algorithms, and their use within dynamical mean-field theory (DMFT). We present strong evidence that the Chebyshev recursion extracts less spectral information from than time evolution algorithms when fixing a given amount of created entanglement.
Cite
@article{arxiv.1501.07216,
title = {Spectral functions and time evolution from the Chebyshev recursion},
author = {F. Alexander Wolf and Jorge A. Justiniano and Ian P. McCulloch and Ulrich Schollwöck},
journal= {arXiv preprint arXiv:1501.07216},
year = {2015}
}
Comments
12 pages + 6 pages appendix, 11 figures