pdgLive

ATLS

${{\mathit \ell}^{\pm}}$ + jets + $\not E_T$, Tsqk3, 4 degenerate light ${{\widetilde{\mathit q}}_{{{{\mathit \ell}}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = (${\mathit m}_{{{\widetilde{\mathit q}}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$)/2, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV

$> 1040$

ATLS

${{\mathit \ell}^{\pm}}$ + jets + $\not E_T$, Tsqk3, 1 light ${{\widetilde{\mathit q}}_{{{{\mathit \ell}}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = (${\mathit m}_{{{\widetilde{\mathit q}}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$)/2, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV

$> 925$

ATLS

${}\geq{}$1 jet + $\not E_T$, Tsqk1, ${\mathit m}_{{{\widetilde{\mathit q}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

$> 550$

ATLS

${}\geq{}$1 jet + $\not E_T$, Tstop3, ${\mathit m}_{{{\widetilde{\mathit t}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

$> 550$

ATLS

${}\geq{}$1 jet + $\not E_T$, Tstop4, ${\mathit m}_{{{\widetilde{\mathit t}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

$> 545$

ATLS

${}\geq{}$1 jet + $\not E_T$, Tsbot1, ${\mathit m}_{{{\widetilde{\mathit b}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

$> 1850$

ATLS

jets + $\not E_T$, Tsqk1, 8 degenerate ${{\widetilde{\mathit q}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$\bf{> 1220}$

ATLS

jets + $\not E_T$, Tsqk1, 1 non-degenerate ${{\widetilde{\mathit q}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1310$

ATLS

jets + $\not E_T$, Tsqk3, 4 degenerate ${{\widetilde{\mathit q}}_{{l}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = (${\mathit m}_{{{\widetilde{\mathit q}}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$)/2, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 3000$

ATLS

jets + $\not E_T$, combined ${{\widetilde{\mathit g}}}{{\widetilde{\mathit g}}}$, ${{\widetilde{\mathit g}}}{{\widetilde{\mathit q}}}$, ${{\widetilde{\mathit q}}}{{\widetilde{\mathit q}}}$ production, ${{\widetilde{\mathit g}}}$ $\rightarrow$ ${{\mathit q}}{{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit q}}}}$ = ${\mathit m}_{{{\widetilde{\mathit g}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1800$

⁴

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + $\not E_T$, Tsqk2A, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$ = 1500 GeV, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 100 GeV

$>1590$

⁵

CMS

2${{\mathit \gamma}}$ +$\not E_T$, Tsqk4B, 500 GeV $<{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}<$ 1500 GeV

$> 1130$

⁶

CMS

jets+$\not E_T$, Tsqk1, 1 light flavour, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1630$

⁶

CMS

jets+$\not E_T$, Tsqk1, 8 degenerate light flavours, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1430$

⁷

CMS

${{\mathit \gamma}}$ + ${{\mathit \ell}}$ + $\not E_T$, Tsqk4A, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 1200 GeV

$> 1200$

⁸

ATLS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + jets + $\not E_T$, Tsqk2, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 1 GeV, any ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$

$> 850$

⁹

ATLS

${{\mathit c}}$-jets+$\not E_T$, Tsqk1 (charm only), ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 710$

¹⁰

ATLS

${}\geq{}$1 jets+$\not E_T$, Tsqk1, ${\mathit m}_{{{\widetilde{\mathit q}}}}\sim{}{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$

$> 1820$

¹¹

ATLS

2 ${{\mathit \gamma}}$ + $\not E_T$, GGM, Tsqk4B, any NLSP mass

$> 1550$

¹²

ATLS

jets+$\not E_T$, Tsqk1, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1150$

¹³

ATLS

jets+$\not E_T$, Tsqk3, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = 0.5 (${\mathit m}_{{{\widetilde{\mathit q}}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$), ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1650$

¹⁴

CMS

${}\geq{}1{{\mathit \gamma}}$ + $\not E_T$, Tsqk4A

$> 1750$

¹⁴

CMS

${}\geq{}1{{\mathit \gamma}}$ + $\not E_T$, Tsqk4B

$> 675$

¹⁵

CMS

jets+$\not E_T$, Tsqk1, 1 light flavor state, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1320$

¹⁵

CMS

jets+$\not E_T$,Tsqk1,8 degenerate light flavor states, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$>1220$

¹⁶

ATLS

1${{\mathit \ell}}$+jets+$\not E_T$, Tsqk3, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1000$

¹⁷

ATLS

2 same-flavour, opposite-sign ${{\mathit \ell}}$ + jets + $\not E_T$, Tsqk2, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1150$

¹⁸

CMS

1 or more jets+$\not E_T$, Tsqk1, 4(flavor) x 2(isospin) = 8 mass degenerate states, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 575$

¹⁸

CMS

1 or more jets+$\not E_T$, Tsqk1, one light flavor state, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$>1370$

¹⁹

CMS

2 ${{\mathit \gamma}}$ + $\not E_T$, GGM, Tsqk4, any NLSP mass

$> 1600$

²⁰

CMS

${{\mathit \gamma}}$ + jets+$\not E_T$, Tsqk4B, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1370$

²⁰

CMS

${{\mathit \gamma}}$ + jets+$\not E_T$, Tsqk4A, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1050$

²¹

CMS

${}\geq{}$1 jets+$\not E_T$, Tsqk1, single light flavor state, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1550$

²¹

CMS

${}\geq{}$1 jets+$\not E_T$, Tsqk1, 4(flavor) x 2(isospin) = 8 degenerate mass states, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$>1390$

²²

CMS

jets+$\not E_T$, Tsqk1, 4(flavor) x 2(isospin) = 8 degenerate mass states, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$>950$

²²

CMS

jets+$\not E_T$, Tsqk1, one light flavor state, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 608$

²³

ATLS

${}\geq{}$1 jet + $\not E_T$, Tsqk1, ${\mathit m}_{{{\widetilde{\mathit q}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 5 GeV

$>1030$

²⁴

ATLS

${}\geq{}$2 jets + $\not E_T$, Tsqk1, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 600$

²⁵

CMS

jets + $\not E_T$, Tsqk1, single light squark, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1260$

²⁵

CMS

jets + $\not E_T$, Tsqk1, 8 degenerate light squarks, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$>850$

²⁶

ATLS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 100 GeV

$>250$

²⁷

ATLS

photon + $\not E_T$, ${{\mathit p}}$ ${{\mathit p}}$ $\rightarrow$ ${{\widetilde{\mathit q}}}{{\widetilde{\mathit q}}^{*}}{{\mathit \gamma}}$ , ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit q}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = ${\mathit m}_{{{\mathit c}}}$

$> 490$

²⁸

ATLS

${{\widetilde{\mathit c}}}$ $\rightarrow$ ${{\mathit c}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV

$>875$

²⁹

CMS

${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , simplified model, 8 degenerate light ${{\widetilde{\mathit q}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0

$>520$

²⁹

CMS

${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , simplified model, single light squark, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0

$> 1450$

²⁹

CMS

CMSSM, tan ${{\mathit \beta}}$ = 30, $\mathit A_{0}$ = $−$2max(${\mathit m}_{\mathrm {0}}$, ${\mathit m}_{\mathrm {1/2}}$), $\mu $ $>$ 0

$> 850$

³⁰

ATLS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, mass degenerate first and second generation squarks, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 440$

³⁰

ATLS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, single light-flavour squark, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV

$> 1700$

³⁰

ATLS

jets + $\not E_T$, mSUGRA/CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}$ = ${\mathit m}_{{{\widetilde{\mathit g}}}}$

$> 800$

³¹

CMS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 50 GeV

$> 780$

³²

CMS

multijets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV

$> 1360$

³³

ATLS

jets + $\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit g}}}}$ = ${\mathit m}_{{{\widetilde{\mathit q}}}}$

$> 1200$

³⁴

ATLS

${{\mathit \gamma}}+{{\mathit b}}+\not E_T$,higgsino-like neutralino, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $>$ 220 GeV, GMSB

³⁵

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + jets + $\not E_T$, CMSSM

$> 1250$

³⁶

CMS

0,1,2,${}\geq{}$3 ${{\mathit b}}$-jets + $\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}$ = ${\mathit m}_{{{\widetilde{\mathit g}}}}$

$> 1430$

³⁷

CMS

2${{\mathit \gamma}}$ + ${}\geq{}$4 jets + low $\not E_T$, stealth SUSY model

$> 750$

³⁸

CMS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$= 0 GeV

$> 820$

³⁹

ATLS

${{\mathit \ell}}$ +jets +$\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}={\mathit m}_{{{\widetilde{\mathit g}}}}$

$> 1200$

⁴⁰

ATLS

${{\mathit \ell}^{\pm}}$+jets+$\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}={\mathit m}_{{{\widetilde{\mathit g}}}}$

$> 870$

⁴¹

ATLS

2${{\mathit \gamma}}$ +$\not E_T$, GMSB, bino NLSP, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $>$ 50 GeV

$> 950$

⁴²

ATLS

jets + $\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}$ = ${\mathit m}_{{{\widetilde{\mathit g}}}}$

⁴³

CMS

${{\mathit e}}$, ${{\mathit \mu}}$, jets, razor, CMSSM

$> 760$

⁴⁴

CMS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}<$ 200 GeV

$> 1110$

⁴⁵

CMS

jets + $\not E_T$, CMSSM

$> 1180$

⁴⁵

CMS

jets + $\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit q}}}}={\mathit m}_{{{\widetilde{\mathit g}}}}$

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

$> 1080$

⁴⁶

ATLS

jets+$\not E_T$, Tsqk5, (${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$)/ (${\mathit m}_{{{\widetilde{\mathit q}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$) $<$ 0.95, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 60 GeV

$> 300$

⁴⁷

CMS

19-parameter pMSSM model, global Bayesian analysis, flat prior

⁴⁸

ATLS

${{\mathit \ell}^{\pm}}$ + jets + $\not E_T$

$>1650$

²⁶

ATLS

jets + $\not E_T$, ${\mathit m}_{{{\widetilde{\mathit g}}}}$ = ${\mathit m}_{{{\widetilde{\mathit q}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 1 GeV

$>790$

²⁶

ATLS

jets + $\not E_T$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\mathit W}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 100 GeV

$>820$

²⁶

ATLS

2 or 3 leptons + jets, ${{\widetilde{\mathit q}}}$ decays via sleptons, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 100 GeV

$> 850$

²⁶

ATLS

${{\mathit \tau}}$, ${{\widetilde{\mathit q}}}$ decays via staus, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 50 GeV

$>700$

⁴⁹

CMS

${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ $\rightarrow$ ${{\widetilde{\mathit S}}}{{\mathit g}}$ , ${{\widetilde{\mathit S}}}$ $\rightarrow$ ${{\mathit S}}{{\widetilde{\mathit G}}}$ , ${{\mathit S}}$ $\rightarrow$ ${{\mathit g}}{{\mathit g}}$ , ${\mathit m}_{{{\widetilde{\mathit S}}}}$ = 100 GeV, ${\mathit m}_{{{\mathit S}}}$ = 90 GeV

$> 550$

⁴⁹

CMS

${{\mathit \ell}^{\pm}}$, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\widetilde{\mathit S}}}{{\mathit W}^{\pm}}$ , ${{\widetilde{\mathit S}}}$ $\rightarrow$ ${{\mathit S}}{{\widetilde{\mathit G}}}$ , ${{\mathit S}}$ $\rightarrow$ ${{\mathit g}}{{\mathit g}}$ , ${\mathit m}_{{{\widetilde{\mathit S}}}}$ = 100 GeV, ${\mathit m}_{{{\mathit S}}}$ = 90 GeV

$>1500$

⁵⁰

CMS

${}\geq{}$2 ${{\mathit \gamma}}$, ${}\geq{}$1 jet, (Razor), bino-like NLSP, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 375 GeV

$>1000$

⁵⁰

CMS

${}\geq{}$1 ${{\mathit \gamma}}$, ${}\geq{}$2 jet, wino-like NLSP, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 375 GeV

$> 670$

⁵¹

ATLS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\pm}}$( ${{\mathit \ell}^{\mp}}$) + jets, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\mathit W}^{(*)\pm}}{{\widetilde{\mathit \chi}}_{{2}}^{0}}$ , ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ $\rightarrow$ ${{\mathit Z}^{(*)}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 300 GeV

$> 780$

⁵¹

ATLS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\pm}}$( ${{\mathit \ell}^{\mp}}$) + jets, ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ /${{\widetilde{\mathit \chi}}_{{2}}^{0}}$, ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \nu}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$( ${{\mathit \nu}}{{\mathit \nu}}$) ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model

$> 700$

⁵²

CMS

${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$ + jets + $\not E_T$, CMSSM, ${\mathit m}_{\mathrm {0}}<$ 700 GeV

$> 1350$

⁵³

CMS

jets (+ leptons) + $\not E_T$, CMSSM, ${\mathit m}_{{{\widetilde{\mathit g}}}}$ = ${\mathit m}_{{{\widetilde{\mathit q}}}}$

$> 800$

⁵⁴

CMS

${}\geq{}$1 photons + jets + $\not E_T$, GGM, wino-like NLSP, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 375 GeV

$> 1000$

⁵⁴

CMS

${}\geq{}$2 photons + jets + $\not E_T$, GGM, bino-like NLSP, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 375 GeV

$> 340$

⁵⁵

DREINER

THEO

${\mathit m}_{{{\widetilde{\mathit q}}}}$ $\sim{}{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$

$> 650$

⁵⁶

DREINER

THEO

${\mathit m}_{{{\widetilde{\mathit q}}}}$ = ${\mathit m}_{{{\widetilde{\mathit g}}}}$ $\sim{}{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$

AAD 2021AK searched in 139 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for pair production of gluinos and squarks in events with a single isolated electron or muon, originating from the decay of a ${{\mathit W}}$ boson, multiple jets and significant $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1B simplified model and on the squark mass in the Tsqk3 simplified model, see their Figure 8.

AAD 2021F searched in 139 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for pair production of squarks in events with a high-$p_T$ jet and $\not E_T$. No significant excess above the Standard Model predictions is observed. Limits are set on the ${{\widetilde{\mathit t}}}$ mass in the Tstop3 and Tstop4, on the ${{\widetilde{\mathit b}}}$ mass in the Tsbot1, and on the ${{\widetilde{\mathit q}}}$ mass in the Tsqk1 simplified model (four-flavour, two chirality states degeneracy).

AAD 2021L searched in 139 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for pair production of gluinos and squarks in events with jets, large missing transverse momentum but no electrons or muons. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A and Tglu1B simplified models, on the squark mass in the Tsqk1 and Tsqk3 simplified models and in a simplified model for gluino-squark production, see their Figures 13-17.

⁴

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.

⁵

SIRUNYAN 2019AG searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with two photons and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu4B simplified model and on the squark mass in the Tsqk4B simplified model, see their Figure 3.

⁶

SIRUNYAN 2019CH searched in 137 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events containing multiple jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A, Tglu1C, Tglu2A and Tglu3A simplified models, see their Figure 13. Limits are also set on squark, sbottom and stop masses in the Tsqk1, Tsbot1, Tstop1 simplified models, see their Figure 14.

⁷

SIRUNYAN 2019K searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with a photon, an electron or muon, and large $\not E_T$. No significant excess above the Standard Model expectations is observed. In the framework of GMSB, limits are set on the chargino and neutralino mass in the Tchi1n1A simplified model, see their Figure 6. Limits are also set on the gluino mass in the Tglu4A simplified model, and on the squark mass in the Tsqk4A simplified model, see their Figure 7.

⁸

AABOUD 2018BJ searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV in events with two opposite-sign charged leptons (electrons and muons), jets and missing transverse momentum, with various requirements to be sensitive to signals with different kinematic endpoint values in the dilepton invariant mass distribution. The data are found to be consistent with the SM expectation. Results are interpreted in the Tsqk2 model in case of ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 1 GeV: for any ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$, squark masses below 1200 GeV are excluded, see their Fig. 14(b).

⁹

AABOUD 2018BV searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with at least one jet identified as ${{\mathit c}}$-jet, large missing transverse energy and no leptons. Good agreement is observed between the number of events in data and Standard Model predictions. The results are translated into exclusion limits in Tsqk1 models considering only ${{\widetilde{\mathit c}}_{{1}}}$. In scenarios with massless neutralinos, scharm masses below 850 GeV are excluded. If the differences of the ${{\widetilde{\mathit c}}_{{1}}}$ and ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ masses is below 100 GeV, scharm masses below 500 GeV are excluded. See their Fig.6 and Fig.7.

¹⁰

AABOUD 2018I searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with at least one jet with a transverse momentum above 250 GeV and no leptons. Good agreement is observed between the number of events in data and Standard Model predictions. The results are translated into exclusion limits in Tsqk1 models. In the compressed scenario with similar squark and neutralino masses, squark masses below 710 GeV are excluded. See their Fig.10(b).

¹¹

AABOUD 2018U searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV in events with at least one isolated photon, possibly jets and significant transverse momentum targeting generalised models of gauge-mediated SUSY breaking. No significant excess of events is observed above the SM prediction. Results are interpreted in terms of lower limits on the masses of squark in Tsqk4B models. Masses below 1820 GeV are excluded for any NLSP mass, see their Fig. 9.

¹²

¹³

AABOUD 2018V searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV in events with no charged leptons, jets and missing transverse momentum. The data are found to be consistent with the SM expectation. Results are interpreted in the Tsqk3 model. Assuming that ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = 0.5 (${\mathit m}_{{{\widetilde{\mathit q}}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$), squark masses below 1150 GeV are excluded for massless LSP, see their Fig. 14(a). Exclusions are also shown assuming ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 60 GeV, see their Fig. 14(b).

¹⁴

SIRUNYAN 2018AA searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with at least one photon and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on wino masses in a general gauge-mediated SUSY breaking (GGM) scenario with bino-like ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ and wino-like ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ and ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ , see Figure 7. Limits are also set on the NLSP mass in the Tchi1n1A and Tchi1chi1A simplified models, see their Figure 8. Finally, limits are set on the gluino mass in the Tglu4A and Tglu4B simplified models, see their Figure 9, and on the squark mass in the Tskq4A and Tsqk4B simplified models, see their Figure 10.

¹⁵

SIRUNYAN 2018AY searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events containing one or more jets and significant $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A, Tglu2A and Tglu3A simplified models, see their Figure 3. Limits are also set on squark, sbottom and stop masses in the Tsqk1, Tsbot1, Tstop1 and Tstop4 simplified models, see their Figure 3. Finally, limits are set on long-lived gluino masses in a Tglu1A simplified model where the gluino is metastable or long-lived with proper decay lengths in the range $10^{-3}$ mm $<$ c${{\mathit \tau}}$ $<$ $10^{5}$ mm, see their Figure 4.

¹⁶

AABOUD 2017AR searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with one isolated lepton, at least two jets and large missing transverse momentum. No significant excess above the Standard Model expectations is observed. Limits up to 1.25 TeV are set on the 1st and 2nd generation squark masses in Tsqk3 simplified models, with $\mathit x$ = (${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$) $/$ (${\mathit m}_{{{\widetilde{\mathit q}}}}−{\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$) = 1/2. Similar limits are obtained for variable $\mathit x$ and fixed neutralino mass, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 60 GeV. See their Figure 13.

¹⁷

AABOUD 2017N searched in 14.7 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with 2 same-flavour, opposite-sign leptons (electrons or muons), jets and large missing transverse momentum. The results are interpreted as 95$\%$ C.L. limits in Tsqk2 models, assuming ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0 GeV and ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$ = 600 GeV. See their Fig. 12 for exclusion limits as a function of ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$.

¹⁸

KHACHATRYAN 2017P searched in 2.3 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with one or more jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A, Tglu2A, Tglu3A, Tglu3B, Tglu3C and Tglu3D simplified models, see their Figures 7 and 8. Limits are also set on the squark mass in the Tsqk1 simplified model, see their Fig. 7, and on the sbottom mass in the Tsbot1 simplified model, see Fig. 8. Finally, limits are set on the stop mass in the Tstop1, Tstop3, Tstop4, Tstop6 and Tstop7 simplified models, see Fig. 8.

¹⁹

KHACHATRYAN 2017V searched in 2.3 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with two photons and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino and squark mass in the context of general gauge mediation models Tglu4B and Tsqk4, see their Fig. 4.

²⁰

SIRUNYAN 2017AY searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with at least one photon, jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu4A and Tglu4B simplified models, and on the squark mass in the Tskq4A and Tsqk4B simplified models, see their Figure 6.

²¹

SIRUNYAN 2017AZ searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with one or more jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A, Tglu2A, Tglu3A simplified models, see their Figures 6. Limits are also set on the squark mass in the Tsqk1 simplified model (for single light squark and for 8 degenerate light squarks), on the sbottom mass in the Tsbot1 simplified model and on the stop mass in the Tstop1 simplified model, see their Fig. 7. Finally, limits are set on the stop mass in the Tstop2, Tstop4 and Tstop8 simplified models, see Fig. 8.

²²

SIRUNYAN 2017P searched in 35.9 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with multiple jets and large $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on the gluino mass in the Tglu1A, Tglu1C, Tglu2A, Tglu3A and Tglu3D simplified models, see their Fig. 12. Limits are also set on the squark mass in the Tsqk1 simplified model, on the stop mass in the Tstop1 simplified model, and on the sbottom mass in the Tsbot1 simplified model, see Fig. 13.

²³

AABOUD 2016D searched in 3.2 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with an energetic jet and large missing transverse momentum. The results are interpreted as 95$\%$ C.L. limits on masses of first and second generation squarks decaying into a quark and the lightest neutralino in scenarios with ${\mathit m}_{{{\widetilde{\mathit q}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 25 GeV. See their Fig. 6.

²⁴

AABOUD 2016N searched in 3.2 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events containing hadronic jets, large $\not E_T$, and no electrons or muons. No significant excess above the Standard Model expectations is observed. First- and second-generation squark masses below 1030 GeV are excluded at the 95$\%$ C.L. decaying to quarks and a massless lightest neutralino. See their Fig. 7a.

²⁵

KHACHATRYAN 2016BS searched in 2.3 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV for events with at least one energetic jet , no isolated leptons, and significant $\not E_T$, using the transverse mass variable ${{\mathit M}_{{T2}}}$ to discriminate between signal and background processes. No significant excess above the Standard Model expectations is observed. Limits are set on the squark mass in the Tskq1 simplified model, both in the assumption of a single light squark and of 8 degenerate squarks, see Fig. 11 and Table 3.

²⁶

AAD 2015BV summarized and extended ATLAS searches for gluinos and first- and second-generation squarks in final states containing jets and missing transverse momentum, with or without leptons or ${\mathit {\mathit b}}$-jets in the $\sqrt {s }$ = 8 TeV data set collected in 2012. The paper reports the results of new interpretations and statistical combinations of previously published analyses, as well as new analyses. Exclusion limits at 95$\%$ C.L. are set on the squark mass in several R-parity conserving models. See their Figs. 9, 11, 18, 22, 24, 27, 28.

²⁷

AAD 2015CS searched in 20.3 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for evidence of pair production of squarks, decaying into a quark and a neutralino, where a photon was radiated either from an initial-state quark, from an intermediate squark, or from a final-state quark. No evidence was found for an excess above the expected level of Standard Model background and a 95$\%$ C.L. exclusion limit was set on the squark mass as a function of the squark-neutralino mass difference, see Fig. 19.

²⁸

AAD 2015K searched in 20.3 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events containing at least two jets, where the two leading jets are each identified as originating from ${\mathit {\mathit c}}$-quarks, and large missing transverse momentum. No excess of events above the expected level of Standard Model background was found. Exclusion limits at 95$\%$ C.L. are set on the mass of superpartners of charm quarks (${{\widetilde{\mathit c}}}$). Assuming that the decay ${{\widetilde{\mathit c}}}$ $\rightarrow$ ${{\mathit c}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ takes place 100$\%$ of the time, a scalar charm mass below 490 GeV is excluded for ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV. For more details, see their Fig. 2.

²⁹

KHACHATRYAN 2015AF searched in 19.5 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events with at least two energetic jets and significant $\not E_T$, using the transverse mass variable ${{\mathit M}_{{T2}}}$ to discriminate between signal and background processes. No significant excess above the Standard Model expectations is observed. Limits are set on the squark mass in simplified models where the decay ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ takes place with a branching ratio of 100$\%$, both for the case of a single light squark or 8 degenerate squarks, see Fig. 12. See also Table 5. Exclusions in the CMSSM, assuming tan ${{\mathit \beta}}$ = 30, $\mathit A_{0}$ = $−$2 max(${\mathit m}_{\mathrm {0}}$, ${\mathit m}_{\mathrm {1/2}}$) and ${{\mathit \mu}}$ $>$ 0, are also presented, see Fig. 15.

³⁰

AAD 2014AE searched in 20.3 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for strongly produced supersymmetric particles in events containing jets and large missing transverse momentum, and no electrons or muons. No excess over the expected SM background is observed. Exclusion limits are derived in simplified models containing squarks that decay via ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , where either a single light state or two degenerate generations of squarks are assumed, see Fig. 10.

³¹

CHATRCHYAN 2014AH searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with at least two energetic jets and significant $\not E_T$, using the razor variables (${{\mathit M}_{{R}}}$ and ${{\mathit R}^{2}}$) to discriminate between signal and background processes. No significant excess above the Standard Model expectations is observed. Limits are set on squark masses in simplified models where the decay ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ takes place with a branching ratio of 100$\%$, see Fig. 28. Exclusions in the CMSSM, assuming tan $\beta $ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, are also presented, see Fig. 26.

³²

CHATRCHYAN 2014I searched in 19.5 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events containing multijets and large $\not E_T$. No excess over the expected SM background is observed. Exclusion limits are derived in simplified models containing squarks that decay via ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ , where either a single light state or two degenerate generations of squarks are assumed, see Fig. 7a.

³³

AAD 2013L searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for the production of squarks and gluinos in events containing jets, missing transverse momentum and no high-$p_T$ electrons or muons. No excess over the expected SM background is observed. In mSUGRA/CMSSM models with tan $\beta $ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, squarks and gluinos of equal mass are excluded for masses below 1360 GeV at 95$\%$ C.L. In a simplified model containing only squarks of the first two generations, a gluino octet and a massless neutralino, squark masses below 1320 GeV are excluded at 95$\%$ C.L. for gluino masses below 2 TeV. See Figures $10 - 15$ for more precise bounds.

³⁴

AAD 2013Q searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events containing a high-$p_T$ isolated photon, at least one jet identified as originating from a bottom quark, and high missing transverse momentum. Such signatures may originate from supersymmetric models with gauge-mediated supersymmetry breaking in events in which one of a pair of higgsino-like neutralinos decays into a photon and a gravitino while the other decays into a Higgs boson and a gravitino. No significant excess above the expected background was found and limits were set on the squark mass as a function of the neutralino mass in a generalized GMSB model (GGM) with a higgsino-like neutralino NLSP, see their Fig. 4. For neutralino masses greater than 220 GeV, squark masses below 1020 GeV are excluded at 95$\%$ C.L.

³⁵

CHATRCHYAN 2013 looked in 4.98 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with two opposite-sign leptons (${{\mathit e}}$, ${{\mathit \mu}}$, ${{\mathit \tau}}$), jets and missing transverse energy. No excess beyond the Standard Model expectation is observed. Exclusion limits are derived in the mSUGRA/CMSSM model with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, see Fig. 6.

³⁶

CHATRCHYAN 2013G searched in 4.98 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for the production of squarks and gluinos in events containing 0,1,2, ${}\geq{}$3 ${{\mathit b}}$-jets, missing transverse momentum and no electrons or muons. No excess over the expected SM background is observed. In mSUGRA/CMSSM models with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0, and ${{\mathit \mu}}$ $>$ 0, squarks and gluinos of equal mass are excluded for masses below 1250 GeV at 95$\%$ C.L. Exclusions are also derived in various simplified models, see Fig. 7.

³⁷

CHATRCHYAN 2013H searched in 4.96 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with two photons, ${}\geq{}$4 jets and low $\not E_T$ due to ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit \gamma}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ decays in a stealth SUSY framework, where the ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ decays through a singlino (${{\widetilde{\mathit S}}}$) intermediate state to ${{\mathit \gamma}}{{\mathit S}}{{\widetilde{\mathit G}}}$ , with the singlet state ${{\mathit S}}$ decaying to two jets. No significant excess above the expected background was found and limits were set in a particular R-parity conserving stealth SUSY model. The model assumes ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 0.5 ${\mathit m}_{{{\widetilde{\mathit q}}}}$, ${\mathit m}_{{{\widetilde{\mathit S}}}}$ = 100 GeV and ${\mathit m}_{{{\mathit S}}}$ = 90 GeV. Under these assumptions, squark masses less than 1430 GeV were excluded at the 95$\%$ C.L.

³⁸

CHATRCHYAN 2013T searched in 11.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events with at least two energetic jets and significant $\not E_T$, using the ${{\mathit \alpha}_{{T}}}$ variable to discriminate between processes with genuine and misreconstructed $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on squark masses in simplified models where the decay ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ takes place with a branching ratio of 100$\%$, assuming an eightfold degeneracy of the masses of the first two generation squarks, see Fig. 8 and Table 9. Also limits in the case of a single light squark are given.

³⁹

AAD 2012AX searched in 1.04 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for supersymmetry in events containing jets, missing transverse momentum and one isolated electron or muon. No excess over the expected SM background is observed and model-independent limits are set on the cross section of new physics contributions to the signal regions. In mSUGRA/CMSSM models with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, squarks and gluinos of equal mass are excluded for masses below 820 GeV at 95$\%$ C.L. Limits are also set on simplified models for squark production and decay via an intermediate chargino and on supersymmetric models with bilinear R-parity violation. Supersedes AAD 2011G.

⁴⁰

AAD 2012CJ searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events containing one or more isolated leptons (electrons or muons), jets and $\not E_T$. The observations are in good agreement with the SM expectations and exclusion limits have been set in number of SUSY models. In the mSUGRA/CMSSM model with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0, and ${{\mathit \mu}}$ $>$ 0, 95$\%$ C.L. exclusion limits have been derived for ${\mathit m}_{{{\widetilde{\mathit q}}}}$ $<$ 1200 GeV, assuming equal squark and gluino masses. In minimal GMSB, values of the effective SUSY breaking scale ${{\mathit \Lambda}}$ $<$ 50 TeV are excluded at 95$\%$ C.L. for tan ${{\mathit \beta}}$ $<$ 45. Also exclusion limits in a number of simplified models have been presented, see Figs. 10 and 12.

⁴¹

AAD 2012CP searched in 4.8 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with two photons and large $\not E_T$ due to ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ $\rightarrow$ ${{\mathit \gamma}}{{\widetilde{\mathit G}}}$ decays in a GMSB framework. No significant excess above the expected background was found and limits were set on the squark mass as a function of the neutralino mass in a generalized GMSB model (GGM) with a bino-like neutralino NLSP. The other sparticle masses were decoupled, tan ${{\mathit \beta}}$ = 2 and ${{\mathit c}}{{\mathit \tau}_{{NLSP}}}$ $<$ 0.1 mm. Also, in the framework of the SPS8 model, a 95$\%$ C.L. lower limit was set on the breaking scale ${{\mathit \Lambda}}$ of 196 TeV.

⁴²

AAD 2012W searched in 1.04 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for the production of squarks and gluinos in events containing jets, missing transverse momentum and no electrons or muons. No excess over the expected SM background is observed. In mSUGRA/CMSSM models with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, squarks and gluinos of equal mass are excluded for masses below 950 GeV at 95$\%$ C.L. In a simplified model containing only squarks of the first two generations, a gluino octet and a massless neutralino, squark masses below 875 GeV are excluded at 95$\%$ C.L.

⁴³

CHATRCHYAN 2012 looked in 35 pb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with ${{\mathit e}}$ and/or ${{\mathit \mu}}$ and/or jets, a large total transverse energy, and $\not E_T$. The event selection is based on the dimensionless razor variable ${{\mathit R}}$, related to the $\not E_T$ and ${{\mathit M}_{{R}}}$, an indicator of the heavy particle mass scale. No evidence for an excess over the expected background is observed. Limits are derived in the CMSSM (${{\mathit m}_{{0}}}$, ${{\mathit m}_{{1/2}}}$) plane for tan ${{\mathit \beta}}$ = 3, 10 and 50 (see Fig. 7 and 8). Limits are also obtained for Simplified Model Spectra.

⁴⁴

CHATRCHYAN 2012AE searched in 4.98 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with at least three jets and large missing transverse momentum. No significant excesses over the expected SM backgrounds are observed and 95$\%$ C.L. limits on the production cross section of squarks in a scenario where ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ with a 100$\%$ branching ratio, see Fig. 3. For ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 200 GeV, values of ${\mathit m}_{{{\widetilde{\mathit q}}}}$ below 760 GeV are excluded at 95$\%$ C.L. Also limits in the CMSSM are presented, see Fig. 2.

⁴⁵

CHATRCHYAN 2012AT searched in 4.73 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for the production of squarks and gluinos in events containing jets, missing transverse momentum and no electrons or muons. No excess over the expected SM background is observed. In mSUGRA/CMSSM models with tan $\beta $ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, squarks with masses below 1110 GeV are excluded at 95$\%$ C.L. Squarks and gluinos of equal mass are excluded for masses below 1180 GeV at 95$\%$ C.L. Exclusions are also derived in various simplified models, see Fig. 6.

⁴⁶

AABOUD 2018V searched in 36.1 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 13 TeV in events with no charged leptons, jets and missing transverse momentum. The data are found to be consistent with the SM expectation. Results are interpreted in the Tsqk5 model. Squark masses below 1100 GeV are excluded if (${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}})/({\mathit m}_{{{\widetilde{\mathit q}}}}$ $−$ ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$) $<$ 0.95 and ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ = 60 GeV, see their Fig. 16(a).

⁴⁷

KHACHATRYAN 2016BT performed a global Bayesian analysis of a wide range of CMS results obtained with data samples corresponding to 5.0 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV and in 19.5 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV. The set of searches considered, both individually and in combination, includes those with all-hadronic final states, same-sign and opposite-sign dileptons, and multi-lepton final states. An interpretation was given in a scan of the 19-parameter pMSSM. No scan points with a gluino mass less than 500 GeV survived and 98$\%$ of models with a squark mass less than 300 GeV were excluded.

⁴⁸

AAD 2015AI searched in 20 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events containing at least one isolated lepton (electron or muon), jets, and large missing transverse momentum. No excess of events above the expected level of Standard Model background was found. Exclusion limits at 95$\%$ C.L. are set on the squark masses in the CMSSM/mSUGRA, see Fig. 15, in the NUHMG, see Fig. 16, and in various simplified models, see Figs. $19 - 21$.

⁴⁹

KHACHATRYAN 2015AR searched in 19.7 of ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events containing jets, either a charged lepton or a photon, and low missing transverse momentum. No significant excess above the Standard Model expectations is observed. Limits are set on the squark mass in a stealth SUSY model where the decays ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\widetilde{\mathit S}}}{{\mathit W}^{\pm}}$ , ${{\widetilde{\mathit S}}}$ $\rightarrow$ ${{\mathit S}}{{\widetilde{\mathit G}}}$ and ${{\mathit S}}$ $\rightarrow$ ${{\mathit g}}{{\mathit g}}$ , with ${\mathit m}_{{{\widetilde{\mathit S}}}}$ = 100 GeV and ${\mathit m}_{{{\mathit S}}}$ = 90 GeV, take place with a branching ratio of 100$\%$. See Fig. 6 for ${{\mathit \gamma}}$ or Fig. 7 for ${{\mathit \ell}^{\pm}}$ analyses.

⁵⁰

KHACHATRYAN 2015AZ searched in 19.7 ${\mathrm {fb}}{}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for events with either at least one photon, hadronic jets and $\not E_T$ (single photon channel) or with at least two photons and at least one jet and using the razor variables. No significant excess above the Standard Model expectations is observed. Limits are set on gluino masses in the general gauge-mediated SUSY breaking model (GGM), for both a bino-like and wino-like neutralino NLSP scenario, see Fig. 8 and 9.

⁵¹

AAD 2014E searched in 20.3 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 8 TeV for strongly produced supersymmetric particles in events containing jets and two same-sign leptons or three leptons. The search also utilises jets originating from ${{\mathit b}}$-quarks, missing transverse momentum and other variables. No excess over the expected SM background is observed. Exclusion limits are derived in simplified models containing gluinos and squarks, see Figures 5 and 6. In the ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\mathit W}^{(*)\pm}}{{\widetilde{\mathit \chi}}_{{2}}^{0}}$ , ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ $\rightarrow$ ${{\mathit Z}^{(*)}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, the following assumptions have been made: ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = 0.5 ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ + ${\mathit m}_{{{\widetilde{\mathit g}}}}$, ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$ = 0.5 ( ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ + ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ ). In the ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ or ${{\widetilde{\mathit q}}}$ $\rightarrow$ ${{\mathit q}^{\,'}}{{\widetilde{\mathit \chi}}_{{2}}^{0}}$ , ${{\widetilde{\mathit \chi}}_{{1}}^{\pm}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \nu}}{{\widetilde{\mathit \chi}}_{{1}}^{0}}$ or ${{\widetilde{\mathit \chi}}_{{2}}^{0}}$ $\rightarrow$ ${{\mathit \ell}^{\pm}}{{\mathit \ell}^{\mp}}$( ${{\mathit \nu}}{{\mathit \nu}}$) ${{\widetilde{\mathit \chi}}_{{1}}^{0}}$ simplified model, the following assumptions have been made: ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{\pm}}}$ = ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{2}}^{0}}}$ = 0.5 ( ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ + ${\mathit m}_{{{\widetilde{\mathit q}}}}$ ), ${\mathit m}_{{{\widetilde{\mathit \chi}}_{{1}}^{0}}}$ $<$ 460 GeV. Limits are also derived in the mSUGRA/CMSSM, bRPV and GMSB models, see their Fig. 8.

⁵²

CHATRCHYAN 2013AO searched in 4.98 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with two opposite-sign isolated leptons accompanied by hadronic jets and $\not E_T$. No significant excesses over the expected SM backgrounds are observed and 95$\%$ C.L. exclusion limits are derived in the mSUGRA/CMSSM model with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, see Fig. 8.

⁵³

CHATRCHYAN 2013AV searched in 4.7 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for new heavy particle pairs decaying into jets (possibly ${{\mathit b}}$-tagged), leptons and $\not E_T$ using the Razor variables. No significant excesses over the expected SM backgrounds are observed and 95$\%$ C.L. exclusion limits are derived in the mSUGRA/CMSSM model with tan ${{\mathit \beta}}$ = 10, ${{\mathit A}_{{0}}}$ = 0 and ${{\mathit \mu}}$ $>$ 0, see Fig. 3. The results are also interpreted in various simplified models, see Fig. 4.

⁵⁴

CHATRCHYAN 2013W searched in 4.93 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ collisions at $\sqrt {s }$ = 7 TeV for events with one or more photons, hadronic jets and $\not E_T$. No significant excess above the Standard Model expectations is observed. Limits are set on squark masses in the general gauge-mediated SUSY breaking model (GGM), for both a wino-like and bino-like neutralino NLSP scenario, see Fig. 5.

⁵⁵	DREINER 2012A reassesses constraints from CMS (at 7 TeV, $\sim{}$4.4 fb${}^{-1}$) under the assumption that the fist and second generation squarks and the lightest SUSY particle are quasi-degenerate in mass (compressed spectrum).

⁵⁶	DREINER 2012A reassesses constraints from CMS (at 7 TeV, $\sim{}$4.4 fb${}^{-1}$) under the assumption that the first and second generation squarks, the gluino, and the lightest SUSY particle are quasi-degenerate in mass (compressed spectrum).

References:

2021L

JHEP 2102 143

Search for squarks and gluinos in final states with jets and missing transverse momentum using 139 fb$^{-1}$ of $\sqrt{s}$ =13 TeV $pp$ collision data with the ATLAS detector

2021F

PR D103 112006

Search for new phenomena in events with an energetic jet and missing transverse momentum in $pp$ collisions at $\sqrt {s}$ =13 TeV with the ATLAS detector

2021AK

EPJ C81 600

Search for squarks and gluinos in final states with one isolated lepton, jets, and missing transverse momentum at $\sqrt{s}=13$� with the ATLAS detector

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

2019AG

JHEP 1906 143

Search for supersymmetry in final states with photons and missing transverse momentum in proton-proton collisions at 13 TeV

2019CH

JHEP 1910 244

Search for supersymmetry in proton-proton collisions at 13 TeV in final states with jets and missing transverse momentum

2019K

JHEP 1901 154

Search for supersymmetry in events with a photon, a lepton, and missing transverse momentum in proton-proton collisions at $\sqrt{s} =$ 13 TeV

2018I

JHEP 1801 126

Search for Dark Matter and other New Phenomena in Events with an Energetic Jet and Large Missing Transverse Momentum using the ATLAS Detector

2018V

PR D97 112001

Search for squarks and gluinos in final states with jets and missing transverse momentum using 36??fb$^{-1}$ of $\sqrt{s}=13$??TeV pp collision data with the ATLAS detector

2018BJ

EPJ C78 625

Search for new phenomena using the invariant mass distribution of same-flavour opposite-sign dilepton pairs in events with missing transverse momentum in $\sqrt{s}=13$ � $\text {Te}\text {V}$ pp collisions with the ATLAS detector

2018U

PR D97 092006

Search for photonic signatures of gauge-mediated supersymmetry in 13�TeV $pp$ collisions with the ATLAS detector

2018BV

JHEP 1809 050

Search for supersymmetry in final states with charm jets and missing transverse momentum in 13 TeV $pp$ collisions with the ATLAS detector

2018AA

PL B780 118

Search for gauge-mediated supersymmetry in events with at least one photon and missing transverse momentum in pp collisions at $\sqrt{s} = $ 13 TeV

2018AY

JHEP 1805 025

Search for natural and split supersymmetry in proton-proton collisions at $ \sqrt{s}=13 $ TeV in final states with jets and missing transverse momentum

2017N

EPJ C77 144

Search for New Phenomena in Events Containing a Same-Flavour Opposite-Sign Dilepton Pair, Jets, and Large Missing Transverse Momentum in $\sqrt {s }$ = 13 ${{\mathit p}}{{\mathit p}}$ Collisions with the ATLAS Detector

2017AR

PR D96 112010

Search for squarks and gluinos in Events with an Isolated Lepton, Jets, and Missing Transverse Momentum at $\sqrt {s }$ = 13 TeV with the ATLAS Detector

2017V

PL B769 391

Search for Supersymmetry in Events with Photons and Missing Transverse Energy in ${{\mathit p}}{{\mathit p}}$ Collisions at 13 TeV

2017P

EPJ C77 294

A Search for New Phenomena in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 13TeV in Final States with Missing Transverse Momentum and at Least One Jet using the $\alpha _{T}$ Variable

2017AY

JHEP 1712 142

Search for Supersymmetry in Events with at Least One Photon, Missing Transverse Momentum, and Large Transverse Event Activity in Proton-Proton Collisions at $\sqrt {s }$ =13 TeV

2017AZ

EPJ C77 710

Search for New Phenomena with the $\mathit M_{T2}$ Variable in the All-Hadronic Final State Produced in Proton-Proton Collisions at $\sqrt {s }$ = 13 TeV

2017P

PR D96 032003

Search for Supersymmetry in Multijet Events with Missing Transverse Momentum in Proton-Proton Collisions at 13 TeV

2016N

EPJ C76 392

Search for Squarks and Gluinos in Final States with Jets and Missing Transverse Momentum at $\sqrt {s }$ = 13 TeV with the ATLAS Detector

2016D

PR D94 032005

Search for New Phenomena in Final States with an Energetic Jet and Large Missing Transverse Momentum in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 13 TeV using the ATLAS Detector

2016BS

JHEP 1610 006

Search for New Physics with the MT2 Variable in all-Jets Final States Produced in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 13 TeV

2016BT

JHEP 1610 129

Phenomenological MSSM Interpretation of CMS Searches in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 and 8 TeV

2015BV

JHEP 1510 054

Summary of the Searches for Squarks and Gluinos using $\sqrt {s }$ = 8 TeV ${{\mathit p}}{{\mathit p}}$ Collisions with the ATLAS Experiment at the LHC

2015CS

PR D91 012008

Search for New Phenomena in Events with a Photon and Missing Transverse Momentum in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

Also

PR D92 059903 (errat.)

Erratum to AAD 2015CS: Search for New Phenomena in Events with a Photon and Missing Transverse Momentum in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

2015AI

JHEP 1504 116

Search for Squarks and Gluinos in Events with Isolated Leptons, Jets and Missing Transverse Momentum at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

2015K

PRL 114 161801

Search for Scalar Charm Quark Pair Production in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

2015AR

PL B743 503

Collins and Sivers Asymmetries in Muonproduction of Pions and Kaons off Transversely Polarised Protons

2015AZ

PR D92 072006

Search for Supersymmetry with Photons in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV

2015AF

JHEP 1505 078

Searches for Supersymmetry using the $\mathit M_{T2}$ Variable in Hadronic Events Produced in ${{\mathit p}}{{\mathit p}}$ Collisions at 8 TeV

2014E

JHEP 1406 035

Search for Supersymmetry at $\sqrt {s }$ = 8 TeV in Final States with Jets and Two Same-Sign Leptons or Three Leptons with the ATLAS Detector

2014AE

JHEP 1409 176

Search for squarks and gluinos with the ATLAS Detector in Final States with Jets and Missing Transverse Momentum using $\sqrt {s }$ = 8 TeV Proton-Proton Collision Data

2014I

JHEP 1406 055

Search for New Physics in the Multijet and Missing Transverse Momentum Final State in Proton-Proton Collisions at $\sqrt {s }$ = 8 TeV

2014AH

PR D90 112001

Search for Supersymmetry with Razor Variables in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2013Q

PL B719 261

Search for Supersymmetry in Events with Photons, Bottom Quarks, and Missing Transverse Momentum in Proton$−$Proton Collisions at a Centre-of-Mass Energy of 7 TeV with the ATLAS Detector

2013L

PR D87 012008

Search for Squarks and Gluinos with the ATLAS Detector in Final States with Jets and Missing Transverse Momentum using 4.7 ${\mathrm {fb}}{}^{-1}$ of $\sqrt {s }$ = 7 TeV Proton-Proton Collision Data

2013W

JHEP 1303 111

Search for New Physics in Events with Photons, Jets, and Missing Transverse Energy in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2013AO

PR D87 072001

Search for Supersymmetry in Events with Opposite-Sign Dileptons and Missing Transverse Energy using an Artificial Neural Network

2013H

PL B719 42

Search for Supersymmetry in Events with Photons and Low Missing Transverse Energy in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2013G

JHEP 1301 077

Search for Supersymmetry in Final States with Missing Transverse Energy and 0, 1, 2, or ${}\geq{}$3 ${\mathit {\mathit b}}$-Quark Jets in 7 TeV ${{\mathit p}}{{\mathit p}}$ Collisions using the Variable ${{\mathit \alpha}_{{T}}}$

PL B718 815

Search for New Physics in Events with Opposite-Sign Leptons, Jets, and Missing Transverse Energy in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2013T

EPJ C73 2568

Search for Supersymmetry in Hadronic Final States with Missing Transverse Energy using the Variables $\alpha _{T}$ and ${\mathit {\mathit b}}$-Quark Multiplicity in ${{\mathit p}}{{\mathit p}}$ Collisions at 8 TeV

2013AV

PRL 111 081802

Inclusive Search for Supersymmetry Using the Razor Variables in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2012CJ

PR D86 092002

Further Search for Supersymmetry at $\sqrt {s }$ = 7 TeV in Final States with Jets, Missing Transverse Momentum, and Isolated Leptons with the ATLAS Detector

2012CP

PL B718 411

Search for Diphoton Events with Large Missing Transverse Momentum in 7 TeV Proton$−$Proton Collision Data with the ATLAS Detector

2012W

PL B710 67

Search for squarks and gluinos using Final States with Jets and Missing Transverse Momentum with the ATLAS Detector in $\sqrt {s }$ = 7 TeV Proton$−$Proton Collisions

2012AX

PR D85 012006

Search for Supersymmetry in Final States with Jets, Missing Transverse Momentum and One Isolated Lepton in $\sqrt {s }$ = 7 TeV ${{\mathit p}}{{\mathit p}}$ Collisions using 1 ${\mathrm {fb}}{}^{-1}$ of ATLAS data

Also

PR D87 099903 (errat.)

Erratum to AAD 2012AX: Search for Supersymmetry in Final States with Jets, Missing Transverse Momentum and one Isolated Lepton in $\sqrt {s }$ = 7 TeV ${{\mathit p}}{{\mathit p}}$ Collisions using 1 $\mathit fb{}^{-1}$ of ATLAS Data

2012AT

JHEP 1210 018

Search for Supersymmetry in Hadronic Final States using $\mathit M_{T2}$ in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

PR D85 012004

Inclusive Search for Squarks and Gluinos in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV