The MSSM confronts the precision electroweak data and the muon g-2

TL;DR

This paper updates the MSSM's predictions against recent electroweak and muon g-2 data, identifying favored parameter regions that reconcile experimental results with theoretical models, including various supersymmetry breaking scenarios.

Contribution

It provides a comprehensive analysis of MSSM parameter space considering recent muon g-2, electroweak, and flavor constraints, highlighting regions compatible with current experimental data.

Findings

Light sleptons (~100-200 GeV) are favored by electroweak data.

Heavier sleptons (~1000 GeV) can explain muon g-2 at high tanβ.

Certain SUSY breaking models accommodate the combined constraints.

Abstract

We update the electroweak study of the predictions of the Minimal Supersymmetric Standard Model (MSSM) including the recent results on the muon anomalous magnetic moment, the weak boson masses, and the final precision data on the Z boson parameters from LEP and SLC. We find that the region of the parameter space where the slepton masses are a few hundred GeV is favored from the muon g-2 for \tan\beta \ltsim 10, whereas for \tan\beta \simeq 50 heavier slepton mass up to \sim 1000 GeV can account for the reported 3.2 \sigma difference between its experimental value and the Standard Model (SM) prediction. As for the electroweak measurements, the SM gives a good description, and the sfermions lighter than 200 GeV tend to make the fit worse. We find, however, that sleptons as light as 100 to 200 GeV are favored also from the electroweak data, if we leave out the jet asymmetry data that do not agree with the leptonic asymmetry data. We extend the survey of the preferred MSSM parameters by including the constraints from the b \to s \gamma transition, and find favorable scenarios in the minimal supergravity, gauge-, and mirage-mediation models of supersymmetry breaking.