📝 SummarXiv

Abstract

We provide a detailed geometric and physical interpretation of infinite distance limits in the complex structure moduli space of Type IIB compactifications on Calabi-Yau threefolds, motivated by the Emergent String Conjecture. In the framework of semi-stable degenerations, such limits are characterised by a simple fibration structure of the fastest vanishing three-cycles. The previously studied Hodge theoretic classification of infinite distance limits of type II, III, and IV is reflected in the number of one-cycles of the shrinking fibres. Complementing our recent work on limits of type II, we focus here on type III and type IV degenerations. Based on effective field theory considerations, these are expected to be decompactification limits to 6d and 5d, respectively. However, establishing the existence of the associated Kaluza-Klein tower(s) of states with both the appropriate mass scaling and the correct degeneracy requires explicit geometric input. We show that the aforementioned vanishing three-cycles are special Lagrangian three-tori, thus giving rise to towers of asymptotically massless BPS particles from multi-wrapped D3-branes with the degeneracy of a Kaluza-Klein tower. We furthermore relate the BPS index of these three-cycles to the Euler characteristic of the threefold. Finally, we systematically analyse infinite distance trajectories in multi-parameter limits described by so-called enhancement chains. We find that the primary singularity type encodes the gravitational duality frame of the limit whereas the secondary singularity type is related to the rank of the gauge group coupled to gravity. The specifics of the asymptotic physics depend crucially on whether or not the trajectory is induced by the backreaction of an EFT string.