# Analogue of Hamilton-Jacobi theory for the time-evolution operator

**Authors:** Michael Vogl, Pontus Laurell, Aaron D. Barr, Gregory A. Fiete

arXiv: 1902.07237 · 2019-08-07

## TL;DR

This paper develops a Hamilton-Jacobi analogue for quantum many-particle systems' time-evolution operator, offering a unified framework for approximations and new insights into Floquet systems, validated through numerical tests.

## Contribution

It introduces a Hamilton-Jacobi-like theory for quantum evolution operators, connecting various approximations and proposing new methods for periodically driven systems.

## Key findings

- Unified framework for time-evolution approximations
- New approximation complementary to rotating frame methods
- Validated methods on the 1D Ising model

## Abstract

In this paper we develop an analogue of Hamilton-Jacobi theory for the time-evolution operator of a quantum many-particle system. The theory offers a useful approach to develop approximations to the time-evolution operator, and also provides a unified framework and starting point for many well-known approximations to the time-evolution operator. In the important special case of periodically driven systems at stroboscopic times, we find relatively simple equations for the coupling constants of the Floquet Hamiltonian, where a straightforward truncation of the couplings leads to a powerful class of approximations. Using our theory, we construct a flow chart that illustrates the connection between various common approximations, which also highlights some missing connections and associated approximation schemes. These missing connections turn out to imply an analytically accessible approximation that is the "inverse" of a rotating frame approximation and thus has a range of validity complementary to it. We numerically test the various methods on the one-dimensional Ising model to confirm the ranges of validity that one would expect from the approximations used. The theory provides a map of the relations between the growing number of approximations for the time-evolution operator. We describe these relations in a table showing the limitations and advantages of many common approximations, as well as the new approximations introduced in this paper.

## Full text

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## Figures

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## References

69 references — full list in the complete paper: https://tomesphere.com/paper/1902.07237/full.md

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Source: https://tomesphere.com/paper/1902.07237