Complexity Bounds for Hamiltonian Simulation in Unitary Representations
Abstract
For any unitary representation on a finite-dimensional Hilbert space with differential for the Lie algebra , we consider the Hamiltonian evolution For any complexification associated with the root system , we introduce the numerical invariants %\emph{root activity} and \emph{root curvature} functionals \begin{align*} \mathcal{A}_p(X) &\coloneqq \Bigl(\sum_{\alpha\in\Delta} |x_\alpha|^p \,\|d\rho(E_\alpha)\|_{\mathrm{op}}^p\Bigr)^{1/p}, \quad 1\le p<\infty\\ \mathcal{C}(X) &\coloneqq \Bigl(\sum_{\alpha\in\Delta} |\alpha(X_0)|^2\,|x_\alpha|^2 \,\|d\rho(E_\alpha)\|_{\mathrm{op}}^2\Bigr)^{1/2}, \end{align*} where is the operator norm on . We first describe how the Hamiltonian is distributed along the directions of root spaces . Our main result shows that for each fixed there exists a constant such that for all sufficiently small . We also introduce a root-gate circuit model and test this on spinchain Hamiltonians on , where root spaces are spanned by matrix units, , and , which gives sharper complexity bounds and dimensionfree representationtheoretic invariants.
Keywords
Cite
@article{arxiv.2603.07231,
title = {Complexity Bounds for Hamiltonian Simulation in Unitary Representations},
author = {Naihuan Jing and Molena Nguyen},
journal= {arXiv preprint arXiv:2603.07231},
year = {2026}
}
Comments
34pp