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Main Authors: Hekkelman, Eva-Maria, van Nuland, Teun D. H., Reimann, Jesse
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.14581
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author Hekkelman, Eva-Maria
van Nuland, Teun D. H.
Reimann, Jesse
author_facet Hekkelman, Eva-Maria
van Nuland, Teun D. H.
Reimann, Jesse
contents We derive power counting formulas for ribbon graph amplitudes that were recently independently discovered in two contexts, namely as a generalization of the Kontsevich model, and as corresponding to a matrix model approach to the spectral action. The Feynman rules are based on divided difference functions of eigenvalues of an abstract Dirac operator. We obtain formulas for the order of divergence, depending on the spectral dimension $d$, the order of decay of the test function $f$ of the spectral action, and the graph properties. Several consequences are discussed, such as the fact that all graphs with maximal order of divergence (at a given loop order and number of external vertices) are planar. To derive our main results we establish two-sided bounds for divided differences, and in particular generalize Hunter's positivity theorem to a larger class of functions.
format Preprint
id arxiv_https___arxiv_org_abs_2512_14581
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Power counting in the spectral action matrix model
Hekkelman, Eva-Maria
van Nuland, Teun D. H.
Reimann, Jesse
Mathematical Physics
High Energy Physics - Theory
Quantum Algebra
We derive power counting formulas for ribbon graph amplitudes that were recently independently discovered in two contexts, namely as a generalization of the Kontsevich model, and as corresponding to a matrix model approach to the spectral action. The Feynman rules are based on divided difference functions of eigenvalues of an abstract Dirac operator. We obtain formulas for the order of divergence, depending on the spectral dimension $d$, the order of decay of the test function $f$ of the spectral action, and the graph properties. Several consequences are discussed, such as the fact that all graphs with maximal order of divergence (at a given loop order and number of external vertices) are planar. To derive our main results we establish two-sided bounds for divided differences, and in particular generalize Hunter's positivity theorem to a larger class of functions.
title Power counting in the spectral action matrix model
topic Mathematical Physics
High Energy Physics - Theory
Quantum Algebra
url https://arxiv.org/abs/2512.14581