Stop Search in the Compressed Region via Semileptonic Decays

TL;DR

This paper proposes a novel method using semileptonic decays and missing transverse energy reconstruction to improve the detection of supersymmetric top partners (stops) in compressed mass spectra at the LHC.

Contribution

It introduces a new analysis technique leveraging semileptonic decay channels and kinematic assumptions to distinguish stop signals from background in compressed spectra.

Findings

Semileptonic decay channel offers better discovery potential than fully hadronic channel.

The method can discover stops up to 500 GeV with 300 fb^{-1} at 13 TeV LHC.

The approach effectively reduces background contamination in compressed mass scenarios.

Abstract

In supersymmetric extensions of the Standard Model, the superpartners of the top quark (stops) play the crucial role in addressing the naturalness problem. For direct pair-production of stops with each stop decaying into a top quark plus the lightest neutralino, the standard stop searches have difficulty finding the stop for a compressed spectrum where the mass difference between the stop and the lightest neutralino is close to the top quark mass, because the events look too similar to the large $t\bar{t}$ background. With an additional hard ISR jet, the two neutralinos from the stop decays are boosted in the opposite direction and they can give rise to some missing transverse energy. This may be used to distinguish the stop decays from the backgrounds. In this paper we study the semileptonic decay of such signal events for the compressed mass spectrum. Although the neutrino from the $W$ decay also produces some missing transverse energy, its momentum can be reconstructed from the kinematic assumptions and mass-shell conditions. It can then be subtracted from the total missing transverse momentum to obtain the neutralino contribution. Because it suffers from less backgrounds, we show that the semileptonic decay channel has a better discovery reach than the fully hadronic decay channel along the compressed line $m_{\tilde{t}} - m_{\tilde{\chi}}\approx m_t$. With 300 $\text{fb}^{-1}$, the 13 TeV LHC can discover the stop up to 500 GeV, covering the most natural parameter space region.