Forward-Backward Asymmetry of Top Quark Pair Production

TL;DR

This paper uses a Markov Chain Monte Carlo approach to evaluate various new physics models explaining the top quark forward-backward asymmetry observed at the Tevatron, highlighting the importance of resonance effects, scale dependence, and NLO corrections.

Contribution

It systematically compares multiple new physics models against experimental data, identifying specific models that improve fit over the Standard Model and emphasizing overlooked effects in such analyses.

Findings

Axial vector exotic gluon around 1-2 TeV fits data well.

W' boson near 2 TeV also improves fit.

Other models do not significantly outperform the Standard Model.

Abstract

We adopt a Markov Chain Monte Carlo method to examine various new physics models which can generate the forward-backward asymmetry in top quark pair production observed at the Tevatron by the CDF Collaboration. We study the following new physics models: (1) exotic gluon $G^\prime$, (2) extra $Z^\prime$ boson with flavor-conserving interaction, (3) extra $Z^\prime$ with flavor-violating $u$-$t$-$Z^\prime$ interaction, (4) extra $W^\prime$ with flavor-violating $d$-$t$-$W^\prime$ interaction, and (5) extra scalars $S$ and $S^\pm$ with flavor-violating $u$-$t$-$S$ and $d$-$t$-$S^\pm$ interactions. After combining the forward-backward asymmetry with the measurement of the top pair production cross section and the $t\bar{t}$ invariant mass distribution at the Tevatron, we find that an axial vector exotic gluon $G^\prime$ of mass about $1 {\rm TeV}$ or $2 {\rm TeV}$ or a $W^\prime$ of mass about $2 {\rm TeV}$ offer an improvement over the Standard Model. The other models considered do not fit the data significantly better than the Standard Model. We also emphasize a few points which have been long ignored in the literature for new physics searches: (1) heavy resonance width effects, (2) renormalization scale dependence, and (3) NLO corrections to the $t\bar{t}$ invariant mass spectrum. We argue that these three effects are crucial to test or exclude new physics effects in the top quark pair asymmetry.