Top quark forward-backward asymmetry at the Tevatron: a comparative study in different new physics models

TL;DR

This study compares how two new physics models, RPV-MSSM and LR model, can explain the observed top quark forward-backward asymmetry at the Tevatron, finding the LR model more capable of matching experimental data.

Contribution

It provides a detailed comparison of the contributions of RPV-MSSM and LR models to the top quark asymmetry, identifying parameter regions where each model can account for the observed deviation.

Findings

LR model can enhance A_{FB}^t to within 2-sigma of data

RPV-MSSM can only do so in a narrow parameter space

 couplings in RPV-MSSM tend to worsen the fit

Abstract

The top quark forward-backward asymmetry A_{FB}^t measured at the Tevatron is above the Standard Model prediction by more than 2-sigma deviation, which might be a harbinger for new physics. In this work we examine the contribution to A_{FB}^t in two different new physics models: one is the minimal supersymmetric model without R-parity (RPV-MSSM) which contributes to A_{FB}^t via sparticle-mediated t-channel process d d_bar-> t t_bar; the other is the third-generation enhanced left-right model (LR model) which contributes to A_{FB}^t via Z'-mediated t-channel or s-channel processes. We find that in the parameter space allowed by the tt_bar production rate and the tt_bar invariant mass distribution at the Tevatron, the LR model can enhance A_{FB}^t to within the 2-sigma region of the Tevatron data for the major part of the parameter space, and in optimal case A_{FB}^t can reach 12% which is slightly below the 1-sigma lower bound. For the RPV-MSSM, only in a narrow part of the parameter space can the \lambda'' couplings enhance A_{FB}^t to within the 2-sigma region while the \lambda' couplings just produce negative contributions to worsen the fit.