English

Probing Light Stops with Stoponium

High Energy Physics - Phenomenology 2015-06-04 v2 High Energy Physics - Experiment

Abstract

We derive new limits on light stops from diboson resonance searches in the γγ\gamma\gamma, ZγZ \gamma, ZZZZ, WWWW and hhhh channels from the first run of the LHC. If the two-body decays of the light stop are mildly suppressed or kinematically forbidden, stoponium bound states will form in pppp collisions and subsequently decay via the pair annihilation of the constituent stops to diboson final states, yielding striking resonance signatures. Remarkably, we find that stoponium searches are highly complementary to direct collider searches and indirect probes of light stops such as Higgs coupling measurements. Using an empirical quarkonia potential model and including the first two SS-wave stoponium states, we find that in the decoupling limit mt~1130m_{\widetilde t_1} \lesssim 130 GeV is excluded for any value of the stop mixing angle and heavy stop mass by the combination of the latest resonance searches and the indirect constraints. The γγ\gamma \gamma searches are the most complementary to the indirect constraints, probing the stop "blind spot" parameter region in which the h0t~1t~1h^0 \tilde t_1 \tilde t_1^* trilinear coupling is small. Interestingly, we also find that the ZγZ\gamma searches give a stronger constraint, mt~1170m_{\widetilde t_1} \lesssim 170 GeV, if the stop is primarily left-handed. For a scenario with a bino LSP and stop NLSP, several gaps in the direct collider searches for stops can unambiguously be filled with the next run of the LHC. For a stop LSP decaying through an R-parity violating UDDUDD coupling, the stoponium searches can fill the gap 100 GeV mt~1200\lesssim m_{\tilde t_1} \lesssim 200 GeV in the direct searches for couplings λ"102\lambda" \lesssim 10^{-2}.

Keywords

Cite

@article{arxiv.1504.01740,
  title  = {Probing Light Stops with Stoponium},
  author = {Brian Batell and Sunghoon Jung},
  journal= {arXiv preprint arXiv:1504.01740},
  year   = {2015}
}

Comments

35 pages, 33 figures. v2: references added

R2 v1 2026-06-22T09:12:03.215Z