Flavor and LHC Searches for New Physics

TL;DR

This paper reviews how flavor physics influences LHC searches for supersymmetry, emphasizing the importance of flavor-dependent models and measurements in uncovering new physics related to electroweak symmetry breaking.

Contribution

It highlights the role of flavor effects in supersymmetry searches and proposes methods to measure small mass splittings and mixings, advancing search strategies for new physics.

Findings

Flavor dependence affects supersymmetry search strategies.

Flavor-dependent models alter kinematic endpoint analyses.

Methods for measuring small mass splittings are discussed.

Abstract

Uncovering the physics of electroweak symmetry breaking (EWSB) is the raison-d'etre of the LHC. Flavor questions, it would seem, are of minor relevance for this quest, apart from their role in constraining the possible structure of EWSB physics. In this short review article, we outline, using flavor-dependent sleptons as an example, how flavor can affect both searches for supersymmetry, and future measurements aimed at understanding the nature of any new discoveries. If the production cross-sections for supersymmetry are relatively low, as indicated by the fact that it has not revealed itself yet in standard searches, the usual assumptions about the superpartner spectra need re-thinking. Furthermore, one must consider more intricate searches, such as lepton-based searches, which could be susceptible to flavor effects. We start by reviewing the flavor structure of existing frameworks for mediating supersymmetry breaking, emphasizing flavor-dependent models proposed recently. We use the kinematic endpoints of invariant mass distributions to demonstrate how flavor dependence can impact both searches for supersymmetry and the Inverse Problem. We also discuss methods for measuring small-mass splittings and mixings at the LHC, both in models with a neutralino LSP and in models with a charged slepton (N)LSP.