Density Matrix Geometry and Sum Rules
Abstract
Geometry plays a fundamental role in a wide range of physical responses, from anomalous transport coefficients to their related sum rules. Notable examples include the quantization of the Hall conductivity and the Souza-Wilkens-Martin (SWM) sum rule -- both valid at zero temperature, independent of interactions and disorder. The finite-temperature generalization of the SWM sum rule has been explored in the literature, revealing deep connections to the geometry of density matrices. Building on recent advances in time-dependent geometric frameworks, we propose a time-dependent quantum geometric tensor for thermal density matrices. This formalism provides a unified interpretation of known sum rules within the framework of the fluctuation-dissipation theorem, further elucidating their fundamental geometric origin. In addition, it provides experimentally accessible methods to probe quantum geometry beyond the zero-temperature regime.
Cite
@article{arxiv.2507.14028,
title = {Density Matrix Geometry and Sum Rules},
author = {Guangyue Ji and David E. Palomino and Nathan Goldman and Tomoki Ozawa and Peter Riseborough and Jie Wang and Bruno Mera},
journal= {arXiv preprint arXiv:2507.14028},
year = {2025}
}
Comments
21 pages