Searching for supersymmetric Higgs bosons on the compressed frontier

18 December 2017 | By

Figure 1: The distribution of the di-electron or di-muon invariant mass (mll), where the signal events tend to cluster at low values of mll. Solid histograms indicate Standard Model background processes, points with error bars indicate the data, and the dashed lines indicate hypothetical Higgsino events. The bottom plot shows the ratio of the data to the total Standard Model background. (Image: ATLAS Collaboration/CERN)

The Standard Model has a number of puzzling features. For instance, why does the Higgs boson have a relatively low mass? Could its mass arise from a hidden symmetry that keeps it from being extremely heavy? And what about dark matter? While the Standard Model has some (almost) invisible particles, like neutrinos, those particles can’t account for all of the dark matter observed by cosmological measurements.

These puzzles could be solved by supersymmetry, a theory that provides a natural mechanism for protecting the Higgs mass and also has a dark matter candidate. Supersymmetry predicts the existence of “super-partner” particles that are heavier than their Standard Model counterparts. As long as the supersymmetric partners of the Higgs boson, called "higgsinos", aren’t too heavy, then supersymmetry can explain a Higgs mass consistent with current observations. The lightest higgsino, the “LSP” (for “lightest supersymmetric particle”), would be a dark matter candidate, while heavier higgsinos decay to the LSP along with other particles like electrons or muons.

Detecting higgsinos can be difficult, especially if the heavier higgsinos and the LSP have very similar masses. In such “compressed” scenarios, the electrons and muons from the heavier higgsino decays have very low momenta, making them difficult to detect. In recent years, ATLAS has made significant progress in understanding these low-momentum particles, which has opened the door to new searches.


These latest results exploit unique features of higgsino decays, most importantly how the small mass difference between the higgsinos causes the electron or muon pair to have a correspondingly small mass.


Figure 2: Limits on Higgsino production from the soft-lepton analysis described here (in blue) and a separate search for “disappearing” tracks. The mass of the heavier charged Higgsino is on the horizontal axis, while the difference in mass between the heavier Higgsino and the LSP is shown on the vertical axis. The dashed lines and solid fill show the expected limits (assuming no signal) and observed limits, respectively, where models within the filled areas are excluded. The grey region represents the models excluded by the LEP experiments. (Image: ATLAS Collaboration/CERN)

In December 2017, ATLAS presented new updates in the compressed supersymmetry search at the SUSY17 conference. These latest results exploit unique features of higgsino decays, most importantly how the small mass difference between the higgsinos causes the electron or muon pair to have a correspondingly small mass, as illustrated in Figure 1. The data are consistent with the Standard Model predictions and have thus been used to set limits on higgsino masses. The new limits are shown in Figure 2, along with limits from another recent ATLAS search that probes SUSY models with even more compressed spectra. For the first time, these LHC results surpass constraints set in 2004 by the Large Electron Positron (LEP) collider that was hosted in the same 27 km circumference tunnel that now holds the LHC.

As many of the still viable supersymmetry scenarios have very small higgsino mass differences, there remains plenty of room for investigation. Look forward to new searches of the compressed frontier as ATLAS continues to collect and analyse data from the LHC.


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