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Bibliographic Details
Main Authors: Agarwal, Naman, Frey, Andrew R., Underwood, Bret
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.18419
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author Agarwal, Naman
Frey, Andrew R.
Underwood, Bret
author_facet Agarwal, Naman
Frey, Andrew R.
Underwood, Bret
contents We investigate the 4-dimensional effective theory of the warped volume modulus in the presence of stabilizing effects from gaugino condensation by analyzing the linearized 10-dimensional supergravity equations of motion. Warping is generally expected to scale down the masses of bulk modes to the IR scale at the tip of a throat. We find that the mass of the warped volume modulus evades expectations and is largely insensitive to the effects of warping, even in strongly warped backgrounds. Instead, the mass is parametrically tied to the 4-dimensional AdS curvature scale $m^2 \sim {\mathcal O}(1) |\hat R_{\rm AdS}|$, presenting a challenge for scale separation in these backgrounds. We trace this effect to a universal contribution arising from the 10-dimensional equations of motion, and comment on the importance of a 10-dimensional treatment of the warped volume modulus for effective field theories and model building.
format Preprint
id arxiv_https___arxiv_org_abs_2509_18419
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Toward an Effective Theory of the Volume Modulus
Agarwal, Naman
Frey, Andrew R.
Underwood, Bret
High Energy Physics - Theory
We investigate the 4-dimensional effective theory of the warped volume modulus in the presence of stabilizing effects from gaugino condensation by analyzing the linearized 10-dimensional supergravity equations of motion. Warping is generally expected to scale down the masses of bulk modes to the IR scale at the tip of a throat. We find that the mass of the warped volume modulus evades expectations and is largely insensitive to the effects of warping, even in strongly warped backgrounds. Instead, the mass is parametrically tied to the 4-dimensional AdS curvature scale $m^2 \sim {\mathcal O}(1) |\hat R_{\rm AdS}|$, presenting a challenge for scale separation in these backgrounds. We trace this effect to a universal contribution arising from the 10-dimensional equations of motion, and comment on the importance of a 10-dimensional treatment of the warped volume modulus for effective field theories and model building.
title Toward an Effective Theory of the Volume Modulus
topic High Energy Physics - Theory
url https://arxiv.org/abs/2509.18419