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Main Author: Glaviano, Emiliano Maria
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.29159
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author Glaviano, Emiliano Maria
author_facet Glaviano, Emiliano Maria
contents We study the renormalization group flow of non-local form factors in four-dimensional quantum gravity within the proper-time formalism at quadratic order in the curvature expansion. We show that the flow equations can be integrated down to $k=0$, allowing the reconstruction of the full momentum dependence of the form factors. Within this framework, we construct asymptotically safe solutions at this order. We find that asymptotic safety of the flow does not automatically ensure a finite cutoff-independent $Λ\to\infty$ limit for the integrated solutions, which in general develop a logarithmic divergence $\ln(q^2/Λ^2)$, so that a renormalization condition is still required. A finite $Λ\to\infty$ limit compatible with asymptotic safety is obtained only when the ultraviolet boundary condition selects the non-Gaussian fixed point. This yields finite dimensionful form factors, removes UV logarithmic contributions, and ensures independence from the renormalization scale $μ$. The resulting renormalized asymptotically safe form factors display a power-law decay $\sim1/q^2$ in the ultraviolet and reproduce the expected logarithmic structure in the infrared, with the Planck scale replacing the renormalization scale.
format Preprint
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institution arXiv
publishDate 2026
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spellingShingle Asymptotically Safe Gravitational Form Factors from the Proper-Time Flow Equation
Glaviano, Emiliano Maria
High Energy Physics - Theory
We study the renormalization group flow of non-local form factors in four-dimensional quantum gravity within the proper-time formalism at quadratic order in the curvature expansion. We show that the flow equations can be integrated down to $k=0$, allowing the reconstruction of the full momentum dependence of the form factors. Within this framework, we construct asymptotically safe solutions at this order. We find that asymptotic safety of the flow does not automatically ensure a finite cutoff-independent $Λ\to\infty$ limit for the integrated solutions, which in general develop a logarithmic divergence $\ln(q^2/Λ^2)$, so that a renormalization condition is still required. A finite $Λ\to\infty$ limit compatible with asymptotic safety is obtained only when the ultraviolet boundary condition selects the non-Gaussian fixed point. This yields finite dimensionful form factors, removes UV logarithmic contributions, and ensures independence from the renormalization scale $μ$. The resulting renormalized asymptotically safe form factors display a power-law decay $\sim1/q^2$ in the ultraviolet and reproduce the expected logarithmic structure in the infrared, with the Planck scale replacing the renormalization scale.
title Asymptotically Safe Gravitational Form Factors from the Proper-Time Flow Equation
topic High Energy Physics - Theory
url https://arxiv.org/abs/2605.29159