Abstract
We apply machine learning techniques to solve a specific classification problem in 4D F-theory. For a divisor D on a given complex threefold base, we want to read out the non-Higgsable gauge group on it using local geometric information near D. The input features are the triple intersection numbers among divisors near D and the output label is the non-Higgsable gauge group. We use decision tree to solve this problem and achieved 85%-98% out-of-sample accuracies for different classes of divisors, where the data sets are generated from toric threefold bases without (4,6) curves. We have explicitly generated a large number of analytic rules directly from the decision tree and proved a small number of them. As a crosscheck, we applied these decision trees on bases with (4,6) curves as well and achieved high accuracies. Additionally, we have trained a decision tree to distinguish toric (4,6) curves as well. Finally, we present an application of these analytic rules to construct local base configurations with interesting gauge groups such as SU(3).
Highlights
The existence of mutiple vacuum solutions is a central feature of string/M-theory paradigm of quantum gravity
One can choose a particular regime of string theory and a class of geometries to probe a part of the landscape
F-theory can be thought as a compactification of IIB string theory on a nonRicci-flat space B, while the non-zero curvature is balanced by the inclusion of 7-branes
Summary
The existence of mutiple vacuum solutions is a central feature of string/M-theory paradigm of quantum gravity. In 6D F-theory, the base B is a complex surface and the non-Higgsable gauge groups are carried by the complex curves on B. In 4D F-theory, the base is a complex threefold and the non-Higgsable gauge groups locate on complex surfaces (divisors). Given local triple intersection numbers near a divisor D as the input vector (the features), we train a classifier to predict the non-Higgsable gauge group on D (the label). We discuss two potential applications of the decision tree trained in section 7: applying them to the resolvable bases and constructing local configurations reversely with the analytic rules.
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