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Hauptverfasser: Chauhan, Aman, Cicoli, Michele, Krippendorf, Sven, Maharana, Anshuman, Piantadosi, Pellegrino, Schachner, Andreas
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.04941
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author Chauhan, Aman
Cicoli, Michele
Krippendorf, Sven
Maharana, Anshuman
Piantadosi, Pellegrino
Schachner, Andreas
author_facet Chauhan, Aman
Cicoli, Michele
Krippendorf, Sven
Maharana, Anshuman
Piantadosi, Pellegrino
Schachner, Andreas
contents We present a data-driven investigation of the exhaustive ensemble of no-scale type IIB flux vacua constructed in \cite{Chauhan:2025rdj}. Using a combination of linear and non-linear dimensionality-reduction techniques, we analyse both flux and moduli spaces and demonstrate that the effective dimensionality of the underlying 12-dimensional flux space is substantially reduced. A central component of our study is a physics-informed autoencoder, which provides a non-linear compression of the flux and moduli data into a low-dimensional latent space. The learned latent representation organises vacua according to desired features and, in particular, isolates distinguished regions associated with small values of the flux superpotential $|W_0|$, revealing non-trivial correlations that are not captured by linear methods. In parallel, we apply tools from topological data analysis, specifically persistent homology, to probe the global structure of the vacuum distribution. This allows us to identify robust, long-lived topological features in both moduli and flux subspaces. This work is a necessary step for developing foundation models in string phenomenology.
format Preprint
id arxiv_https___arxiv_org_abs_2603_04941
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Parameter compression in the flux landscape
Chauhan, Aman
Cicoli, Michele
Krippendorf, Sven
Maharana, Anshuman
Piantadosi, Pellegrino
Schachner, Andreas
High Energy Physics - Theory
We present a data-driven investigation of the exhaustive ensemble of no-scale type IIB flux vacua constructed in \cite{Chauhan:2025rdj}. Using a combination of linear and non-linear dimensionality-reduction techniques, we analyse both flux and moduli spaces and demonstrate that the effective dimensionality of the underlying 12-dimensional flux space is substantially reduced. A central component of our study is a physics-informed autoencoder, which provides a non-linear compression of the flux and moduli data into a low-dimensional latent space. The learned latent representation organises vacua according to desired features and, in particular, isolates distinguished regions associated with small values of the flux superpotential $|W_0|$, revealing non-trivial correlations that are not captured by linear methods. In parallel, we apply tools from topological data analysis, specifically persistent homology, to probe the global structure of the vacuum distribution. This allows us to identify robust, long-lived topological features in both moduli and flux subspaces. This work is a necessary step for developing foundation models in string phenomenology.
title Parameter compression in the flux landscape
topic High Energy Physics - Theory
url https://arxiv.org/abs/2603.04941