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Complexity in Tame Quantum Theories

High Energy Physics - Theory 2024-05-06 v2 High Energy Physics - Phenomenology Algebraic Geometry Logic Quantum Physics

Abstract

Inspired by the notion that physical systems can contain only a finite amount of information or complexity, we introduce a framework that allows for quantifying the amount of logical information needed to specify a function or set. We then apply this methodology to a variety of physical systems and derive the complexity of parameter-dependent physical observables and coupling functions appearing in effective Lagrangians. In order to implement these ideas, it is essential to consider physical theories that can be defined in an o-minimal structure. O-minimality, a concept from mathematical logic, encapsulates a tameness principle. It was recently argued that this property is inherent to many known quantum field theories and is linked to the UV completion of the theory. To assign a complexity to each statement in these theories one has to further constrain the allowed o-minimal structures. To exemplify this, we show that many physical systems can be formulated using Pfaffian o-minimal structures, which have a well-established notion of complexity. More generally, we propose adopting sharply o-minimal structures, recently introduced by Binyamini and Novikov, as an overarching framework to measure complexity in quantum theories.

Keywords

Cite

@article{arxiv.2310.01484,
  title  = {Complexity in Tame Quantum Theories},
  author = {Thomas W. Grimm and Lorenz Schlechter and Mick van Vliet},
  journal= {arXiv preprint arXiv:2310.01484},
  year   = {2024}
}

Comments

48 pages, 2 figures

R2 v1 2026-06-28T12:38:41.090Z