Optimization of highly excited matrix product states with an application to vibrational spectroscopy

TL;DR

This paper introduces two variants of the density matrix renormalization group algorithm to efficiently target and compute highly excited states in quantum systems, overcoming limitations of traditional methods especially in high-density energy regions.

Contribution

The authors develop and compare two new DMRG-based algorithms for directly targeting specific energy regions, improving the calculation of highly excited states in complex quantum systems.

Findings

Efficient algorithms for high-energy state targeting are demonstrated.

Accurate spectral features of large molecules are computed.

The methods are applicable to various Hamiltonians, including electronic and nuclear.

Abstract

Configuration-interaction-type calculations on electronic and vibrational structure are often the method of choice for the reliable approximation of many-particle wave functions and energies. The exponential scaling, however, limits their application range. An efficient approximation to the full configuration interaction solution can be obtained with the density matrix renormalization group (DMRG) algorithm without a restriction to a predefined excitation level. In a standard DMRG implementation, however, excited states are calculated with a ground-state optimization in the space orthogonal to all lower lying wave function solutions. A trivial parallelization is therefore not possible and the calculation of highly excited states becomes prohibitively expensive, especially in regions with a high density of states. Here, we introduce two variants of the density matrix renormalization group algorithm that allow us to target directly specific energy regions and therefore highly excited states. The first one, based on shift-and-invert techniques, is particularly efficient for low-lying states, but is not stable in regions with a high density of states. The second one, based on the folded auxiliary operator, is less efficient, but more accurate in targeting high-energy states. We apply the algorithm to the solution of the nuclear Schroedinger equation, but emphasize that it can be applied to the diagonalization of general Hamiltonians as well, such as the electronic Coulomb Hamiltonian to address X-ray spectra. In combination with several root-homing algorithms and a stochastic sampling of the determinant space, excited states of interest can be adequately tracked and analyzed during the optimization. We demonstrate that we can accurately calculate prominent spectral features of large molecules such as the sarcosyn-glycine dipeptide.