Related papers: An efficient quantum algorithm for generation of ab initio n-th order susceptibilities for non-linear spectroscpies

An efficient quantum algorithm for generation of ab initio n-th order susceptibilities for non-linear spectroscpies

URL: http://arxiv.org/abs/2404.01454v1
Date: Mon, 1 Apr 2024 20:04:49 GMT
Title: An efficient quantum algorithm for generation of ab initio n-th order susceptibilities for non-linear spectroscpies
Authors: Tyler Kharazi, Torin F. Stetina, Liwen Ko, Guang Hao Low, K. Birgitta Whaley,
Abstract summary: We develop and analyze a fault-tolerant quantum algorithm for computing $n$-th order response properties. We use a semi-classical description in which the electronic degrees of freedom are treated quantum mechanically and the light is treated as a classical field.
Score: 0.13980986259786224
License: http://creativecommons.org/licenses/by-sa/4.0/
Abstract: We develop and analyze a fault-tolerant quantum algorithm for computing $n$-th order response properties necessary for analysis of non-linear spectroscopies of molecular and condensed phase systems. We use a semi-classical description in which the electronic degrees of freedom are treated quantum mechanically and the light is treated as a classical field. The algorithm we present can be viewed as an implementation of standard perturbation theory techniques, focused on {\it ab initio} calculation of $n$-th order response functions. We provide cost estimates in terms of the number of queries to the block encoding of the unperturbed Hamiltonian, as well as the block encodings of the perturbing dipole operators. Using the technique of eigenstate filtering, we provide an algorithm to extract excitation energies to resolution $\gamma$, and the corresponding linear response amplitude to accuracy $\epsilon$ using ${O}\left(N^{6}\eta^2{{\gamma^{-1}}\epsilon^{-1}}\log(1/\epsilon)\right)$ queries to the block encoding of the unperturbed Hamiltonian $H_0$, in double factorized representation. Thus, our approach saturates the Heisenberg $O(\gamma^{-1})$ limit for energy estimation and allows for the approximation of relevant transition dipole moments. These quantities, combined with sum-over-states formulation of polarizabilities, can be used to compute the $n$-th order susceptibilities and response functions for non-linear spectroscopies under limited assumptions using $\widetilde{O}\left({N^{5n+1}\eta^{n+1}}/{\gamma^n\epsilon}\right)$ queries to the block encoding of $H_0$.

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