Even more efficient quantum computations of chemistry through tensor hypercontraction

TL;DR

This paper introduces a highly efficient quantum algorithm for simulating quantum chemistry Hamiltonians in arbitrary bases, significantly reducing complexity and resource requirements compared to previous methods.

Contribution

The authors develop a novel tensor hypercontraction-based quantum simulation method that achieves the lowest known complexity for chemistry calculations in arbitrary bases, with practical resource estimates.

Findings

Achieves $ ilde{O}(N)$ Toffoli complexity for block encoding spectra.

Requires about four million physical qubits for simulating FeMoCo.

Reduces resource estimates compared to prior algorithms.

Abstract

We describe quantum circuits with only $\widetilde{\cal O}(N)$ Toffoli complexity that block encode the spectra of quantum chemistry Hamiltonians in a basis of $N$ arbitrary (e.g., molecular) orbitals. With ${\cal O}(\lambda / \epsilon)$ repetitions of these circuits one can use phase estimation to sample in the molecular eigenbasis, where $\lambda$ is the 1-norm of Hamiltonian coefficients and $\epsilon$ is the target precision. This is the lowest complexity that has been shown for quantum computations of chemistry within an arbitrary basis. Furthermore, up to logarithmic factors, this matches the scaling of the most efficient prior block encodings that can only work with orthogonal basis functions diagonalizing the Coloumb operator (e.g., the plane wave dual basis). Our key insight is to factorize the Hamiltonian using a method known as tensor hypercontraction (THC) and then to transform the Coulomb operator into an isospectral diagonal form with a non-orthogonal basis defined by the THC factors. We then use qubitization to simulate the non-orthogonal THC Hamiltonian, in a fashion that avoids most complications of the non-orthogonal basis. We also reanalyze and reduce the cost of several of the best prior algorithms for these simulations in order to facilitate a clear comparison to the present work. In addition to having lower asymptotic scaling spacetime volume, compilation of our algorithm for challenging finite-sized molecules such as FeMoCo reveals that our method requires the least fault-tolerant resources of any known approach. By laying out and optimizing the surface code resources required of our approach we show that FeMoCo can be simulated using about four million physical qubits and under four days of runtime, assuming $1\,\mu$s cycle times and physical gate error rates no worse than $0.1\%$.