pdgLive

2021

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{R}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{L}}}}$ and ${{\widetilde{\mathit \ell}}}={{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 150$

2020

ATLS

2${{\mathit \ell}}$ (soft), jets, $\not E_T$, ${{\widetilde{\mathit \mu}}_{{R}}}$ only, ${\mathit m}_{{{\widetilde{\mathit \mu}}_{{R}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 8.2 GeV

$> 216$

2020

ATLS

2${{\mathit \ell}}$ (soft), jets, $\not E_T$, ${{\widetilde{\mathit \mu}}_{{L}}}$ only, ${\mathit m}_{{{\widetilde{\mathit \mu}}_{{L}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 10 GeV

$\bf{> 700}$

⁴

2020

ATLS

2${{\mathit \ell}}+\not E_T$, ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{R}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{L}}}}$ and ${{\widetilde{\mathit \ell}}}={{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$=0 GeV

$\bf{> 210}$

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${{\widetilde{\mathit \mu}}_{{R}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 280$

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${{\widetilde{\mathit \mu}}_{{L}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 290$

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${{\widetilde{\mathit \ell}}_{{R}}}$ and ${{\widetilde{\mathit \ell}}}={{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 400$

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${{\widetilde{\mathit \ell}}_{{L}}}$ and ${{\widetilde{\mathit \ell}}}={{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 450$

CMS

$> 310$

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, ${\mathit m}_{{{\widetilde{\mathit \mu}}_{{R}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \mu}}_{{L}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 190$

⁶

2018

ATLS

2${{\mathit \ell}}$ (soft) + $\not E_T$, ${\mathit m}_{{{\widetilde{\mathit e}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \mu}}}}$, ${\mathit m}_{{{\widetilde{\mathit \mu}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

⁷

CHATRCHYAN

2014

CMS

${}\geq{}3{{\mathit \ell}^{\pm}}$, ${{\widetilde{\mathit \ell}}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \tau}^{\mp}}{{\mathit \tau}^{\mp}}{{\widetilde{\mathit G}}}$ simplified model, GMSB, stau (N)NLSP scenario

⁸

2013

ATLS

2${{\mathit \ell}^{\pm}}$ + $\not E_T$, SMS, pMSSM

$>91.0$

⁹

ABBIENDI

OPAL

$\Delta \mathit m>$3 GeV, ${{\widetilde{\mathit \mu}}_{{R+}}}{{\widetilde{\mathit \mu}}_{{R-}}}$ , $\vert {{\mathit \mu}}\vert >100~$GeV, tan $\beta $=1.5

$>86.7$

¹⁰

ACHARD

$\Delta \mathit m>$10 GeV, ${{\widetilde{\mathit \mu}}_{{R}}^{+}}{{\widetilde{\mathit \mu}}_{{R}}^{-}}$, $\vert {{\mathit \mu}}\vert >200~$GeV, tan $\beta {}\geq{}$2

$\text{none 30 - 88}$

¹¹

ABDALLAH

2003

DLPH

$\Delta {{\mathit m}}>$5~GeV, ${{\widetilde{\mathit \mu}}_{{R}}^{+}}{{\widetilde{\mathit \mu}}_{{R}}^{-}}$

$\bf{>94}$

¹²

ABDALLAH

2003

DLPH

${{\widetilde{\mathit \mu}}_{{R}}},1{}\leq{}$tan $\beta {}\leq{}$40, $\Delta {{\mathit m}}>$10~GeV

$>88$

¹³

HEISTER

2002

ALEP

$\Delta \mathit m>15$ GeV, ${{\widetilde{\mathit \mu}}_{{R+}}}{{\widetilde{\mathit \mu}}_{{R-}}}$

• • We do not use the following data for averages, fits, limits, etc. • •

$> 500$

¹⁴

2018

ATLS

2${{\mathit \ell}}$ + $\not E_T$, ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{R}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{L}}}}$ and ${{\widetilde{\mathit \ell}}}={{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, ${{\widetilde{\mathit \tau}}}$ , with ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$\text{none 90 - 325}$

¹⁵

2014

ATLS

${{\widetilde{\mathit \ell}}}$ ${{\widetilde{\mathit \ell}}}$ $\rightarrow$ ${{\mathit \ell}^{+}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}{{\mathit \ell}^{-}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , simplified model, ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{L}}}}$ = ${\mathit m}_{{{\widetilde{\mathit \ell}}_{{R}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

¹⁶

KHACHATRYAN

2014

CMS

${{\widetilde{\mathit \ell}}}$ $\rightarrow$ ${{\mathit \ell}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , simplified model

$>80$

¹⁷

ABREU

2000

DLPH

${{\widetilde{\mathit \mu}}_{{R}}}{{\widetilde{\mathit \mu}}_{{R}}}$ ( ${{\widetilde{\mathit \mu}}_{{R}}}$ $\rightarrow$ ${{\mathit \mu}}{{\widetilde{\mathit G}}}$ ), ${\mathit m}_{{{\widetilde{\mathit G}}}}>$8 eV

SIRUNYAN 2021M searched in 137 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for supersymmetry in events with two opposite-sign same-flavor leptons (electrons, muons) and $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the simplified model Tglu4C, see their Figure 10, on the ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ and ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ mass in Tchi1n2Fa, see their Figure 11, on the ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ mass in Tn1n1C and Tn1n1B for ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}={\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}={\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$, see their Figure 12. Limits are also set on the light squark mass for the simplified model Tsqk2A, on the sbottom mass in Tsbot3, see their Figure 13, and on the slepton mass in direct electroweak pair production of mass-degenerate left- and right-handed sleptons (selectrons and smuons), see their Figure 14.

AAD 2020I reported on ATLAS searches for slepton pair production in models with compressed mass spectra. A dataset of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV corresponding to an integrated luminosity of 139 ${\mathrm {fb}}{}^{-1}$ was used. Events with $\not E_T$, two same-flavour, opposite-charge, low-transverse-momentum leptons, and jets from initial-state radiation or characteristic of vector-boson fusion production are selected. Light-flavour sleptons ${{\widetilde{\mathit e}}}$ and ${{\widetilde{\mathit \mu}}}$ are constrained at 95$\%$ C.L. to have masses above 251 GeV for a mass splitting slepton$−{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ of 10 GeV, with constraints extending down to mass splittings of 550 MeV at the LEP slepton limits (73 GeV). See their Fig. 16(a). If only smuon are considered, and ${{\widetilde{\mathit \mu}}}$ = ${{\widetilde{\mathit \mu}}_{{R}}}$, masses below 150 GeV are excluded for mass splitting ${{\widetilde{\mathit \mu}}_{{R}}}$, ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ of 8.2 GeV. See their Fig. 16(b).

AAD 2020I reported on ATLAS searches for slepton pair production in models with compressed mass spectra. A dataset of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV corresponding to an integrated luminosity of 139 ${\mathrm {fb}}{}^{-1}$ was used. Events with $\not E_T$, two same-flavour, opposite-charge, low-transverse-momentum leptons, and jets from initial-state radiation or characteristic of vector-boson fusion production are selected. Light-flavour sleptons ${{\widetilde{\mathit e}}}$ and ${{\widetilde{\mathit \mu}}}$ are constrained at 95$\%$ C.L. to have masses above 251 GeV for a mass splitting slepton$−{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ of 10 GeV, with constraints extending down to mass splittings of 550 MeV at the LEP slepton limits (73 GeV). See their Fig. 16(a). If only smuon are considered, and ${{\widetilde{\mathit \mu}}}$ = ${{\widetilde{\mathit \mu}}_{{L}}}$, masses below 216 GeV are excluded for mass splitting ${{\widetilde{\mathit \mu}}_{{L}}}$, ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ of 10 GeV. See their Fig. 16(b).

⁴

AAD 2020O reported on a search for electroweak production in models with charginos and sleptons decaying into final states with exactly two oppositely charged leptons and missing transverse momentum. A dataset of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV corresponding to an integrated luminosity of 139 ${\mathrm {fb}}{}^{-1}$ was used. Light-flavour sleptons ${{\widetilde{\mathit e}}}$ and ${{\widetilde{\mathit \mu}}}$ are constrained at 95$\%$ C.L. to have masses above 700 GeV for massless lightest neutralino, see their Fig. 7(c). Exclusion limits are also set for selectrons and smuons separately, considering either right- or left-handed components, by including only the di-electron and di-muon same-flavour signal regions defined in the search, see their Fig. 8.

⁵

SIRUNYAN 2019AW searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for direct electroweak pair production of selectrons or smuons in events with two leptons (electrons or muons) of the opposite electric charge and same flavour, no jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the selectron mass assuming left-handed, right-handed or both left- and right-handed (mass degenerate) production, see their Figure 6. Similarly, limits are set on the smuon mass, see their Figure 7. Limits are also set on slepton masses under the assumption that the selectron and smuon are mass degenerate, see their Figure 5.

⁶

AABOUD 2018R searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for electroweak production in scenarios with compressed mass spectra in final states with two low-momentum leptons and missing transverse momentum. The data are found to be consistent with the SM prediction. Results are interpreted in slepton pair production models with a fourfold degeneracy assumed in selectron and smuon masses. The ${{\widetilde{\mathit \mu}}}$ masses are excluded up to 190 GeV for ${\mathit m}_{{{\widetilde{\mathit \mu}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV. The exclusion limits extend down to mass splittings of 1 GeV, see their Fig. 11.

⁷

CHATRCHYAN 2014R searched in 19.5 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events with at least three leptons (electrons, muons, taus) in the final state. No significant excess above the Standard Model expectations is observed. Limits are set on the slepton mass in a stau (N)NLSP simplified model (GMSB) where the decay ${{\widetilde{\mathit \ell}}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \tau}^{\pm}}{{\mathit \tau}^{\mp}}{{\widetilde{\mathit G}}}$ takes place with a branching ratio of 100$\%$, see Fig. 8.

⁸

AAD 2013B searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for sleptons decaying to a final state with two leptons (${{\mathit e}}$ and ${{\mathit \mu}}$) and missing transverse energy. No excess beyond the Standard Model expectation is observed. Limits are derived in a simplified model of direct left-handed slepton pair production, where left-handed slepton masses between 85 and 195 GeV are excluded at 95$\%$ C.L. for ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 20 GeV. See also Fig. 2(a). Exclusion limits are also derived in the phenomenological MSSM, see Fig. 3.

⁹

ABBIENDI 2004 search for ${{\widetilde{\mathit \mu}}_{{R}}}{{\widetilde{\mathit \mu}}_{{R}}}$ production in acoplanar di-muon final states in the $183 - 208$~GeV data. See Fig.$~$14 for the dependence of the limits on ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ and for the limit at tan $\beta $=35. Under the assumption of 100\% branching ratio for ${{\widetilde{\mathit \mu}}_{{R}}}$ $\rightarrow$ ${{\mathit \mu}}$ ~${{\widetilde{\mathit \chi}}_{{1}}^{0}}$, the limit improves to 94.0 GeV for $\Delta \mathit m>$ 4$~$GeV. See Fig.~11 for the dependence of the limits on m$_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ at several values of the branching ratio. This limit supersedes ABBIENDI 2000G.

¹⁰

ACHARD 2004 search for ${{\widetilde{\mathit \mu}}_{{R}}}{{\widetilde{\mathit \mu}}_{{R}}}$ production in acoplanar di-muon final states in the $192 - 209$ GeV data. Limits on ${\mathit m}_{{{\widetilde{\mathit \mu}}_{{R}}}}$ are derived from a scan over the MSSM parameter space with universal GUT scale gaugino and scalar masses and ${\mathit m}_{{{\mathit 0}}}$, 1${}\leq{}$tan $\beta {}\leq{}$60 and $-2{}\leq{}\mu {}\leq{}$2 TeV. See Fig.~4 for the dependence of the limits on ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$. This limit supersedes ACCIARRI 1999W.

¹¹

ABDALLAH 2003M looked for acoplanar dimuon $\text{+}\not E$ final states at $\sqrt {s }$ = $189 - 208$ GeV. The limit assumes B( ${{\widetilde{\mathit \mu}}}$ $\rightarrow$ ${{\mathit \mu}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ ) = 100\%. See Fig.~16 for limits on the (${\mathit m}_{{{\widetilde{\mathit \mu}}_{{R}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$) plane. These limits include and update the results of ABREU 2001 .

¹²

ABDALLAH 2003M uses data from $\sqrt {s }$ = $192 - 208$ GeV to obtain limits in the framework of the MSSM with gaugino and sfermion mass universality at the GUT scale. An indirect limit on the mass is derived by constraining the MSSM parameter space by the results from direct searches for neutralinos (including cascade decays) and for sleptons. These limits are valid for values of M$_{2}<$ 1 TeV, $\vert {{\mathit \mu}}\vert {}\leq{}$1 TeV with the ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ as LSP. The quoted limit is obtained when there is no mixing in the third family. See Fig.~43 for the mass limits as a function of tan $\beta $. These limits update the results of ABREU 2000W.

¹³

HEISTER 2002E looked for acoplanar dimuon + $\not E_T$ final states from ${{\mathit e}^{+}}{{\mathit e}^{-}}$ interactions between 183 and 209 GeV. The mass limit assumes B( ${{\widetilde{\mathit \mu}}}$ $\rightarrow$ ${{\mathit \mu}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ )=1. See their Fig.$~$4 for the dependence of the limit on $\Delta \mathit m$. These limits include and update the results of BARATE 2001 .

¹⁴

AABOUD 2018BT searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for direct electroweak production of charginos, chargino and next-to-lightest neutralinos and sleptons in events with two or three leptons (electrons or muons), with or without jets, and large missing transverse energy. No significant excess above the Standard Model expectations is observed. Limits are set on the slepton mass up to 500 GeV for massless ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$, assuming degeneracy of ${{\widetilde{\mathit e}}}$, ${{\widetilde{\mathit \mu}}}$, and ${{\widetilde{\mathit \tau}}}$ and exploiting the 2${{\mathit \ell}}$ signature, see their Figure 8(b).

¹⁵

AAD 2014G searched in 20.3 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for electroweak production of slepton pairs, decaying to a final sate with two leptons (${{\mathit e}}$ and ${{\mathit \mu}}$) and missing transverse momentum. No excess beyond the Standard Model expectation is observed. Exclusion limits are derived in simplified models of slepton pair production, see Fig. 8. An interpretation in the pMSSM is also given, see Fig. 10.

¹⁶

KHACHATRYAN 2014I searched in 19.5 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for electroweak production of slepton pairs decaying to a final state with opposite-sign lepton pairs (${{\mathit e}}$ or ${{\mathit \mu}}$) and missing transverse momentum. No excess beyond the Standard Model expectation is observed. Exclusion limits are derived in simplified models, see Fig. 18.

¹⁷

ABREU 2000V use data from $\sqrt {\mathit s }$= $130 - 189$ GeV to search for tracks with large impact parameter or visible decay vertices. Limits are obtained as function of ${\mathit m}_{{{\widetilde{\mathit G}}}}$, after combining these results with the search for slepton pair production in the SUGRA framework from ABREU 2001 to cover prompt decays and on stable particle searches from ABREU 2000Q. For limits at different ${\mathit m}_{{{\widetilde{\mathit G}}}}$, see their Fig.$~$12.

References:

2021M

JHEP 2104 123

Search for supersymmetry in final states with two oppositely charged same-flavor leptons and missing transverse momentum in proton-proton collisions at $\sqrt{s} =$ 13 TeV

2020I

PR D101 052005

Searches for electroweak production of supersymmetric particles with compressed mass spectra in $\sqrt{s}=$ 13 TeV $pp$ collisions with the ATLAS detector

2020O

EPJ C80 123

Search for electroweak production of charginos and sleptons decaying into final states with two leptons and missing transverse momentum in $\sqrt{s}=13$ TeV $pp$ collisions using the ATLAS detector

2019AW

PL B790 140

Search for supersymmetric partners of electrons and muons in proton-proton collisions at $\sqrt{s}=$ 13 TeV

2018BT

EPJ C78 995

Search for electroweak production of supersymmetric particles in final states with two or three leptons at $\sqrt{s}=13\,$TeV with the ATLAS detector

2018R

PR D97 052010

Search for electroweak production of supersymmetric states in scenarios with compressed mass spectra at $\sqrt{s}=13$ TeV with the ATLAS detector

2014G

JHEP 1405 071

Search for Direct Production of charginos, neutralinos and sleptons in Final States with Two Leptons and Missing Transverse Momentum in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

CHATRCHYAN

2014R

PR D90 032006

Search for Anomalous Production of Events with Three or More Leptons in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV

KHACHATRYAN

2014I

EPJ C74 3036

Searches for Electroweak Production of charginos, neutralinos, and sleptons Decaying to Leptons and ${{\mathit W}}$, ${{\mathit Z}}$, and Higgs Bosons in ${{\mathit p}}{{\mathit p}}$ Collisions at 8 TeV

2013B

PL B718 879

Search for Direct Slepton and Gaugino Production in Final States with Two Leptons and Missing Transverse Momentum with the ATLAS Detector in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

ABBIENDI

EPJ C32 453

Search for Anomalous Production of Dilepton Events with Missing Transverse Momentum in ${{\mathit e}^{+}}{{\mathit e}^{-}}$ Collisions at $\sqrt {s }$ = $183 - 209$ GeV

ACHARD