Search for stopped gluinos in pp collisions at √s=7TeV

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Search for Stopped Gluinos in pp Collisions at

p

ffiffiffi

s

¼ 7 TeV

V. Khachatryan et al.*

(CMS Collaboration)

(Received 26 November 2010; published 7 January 2011)

The results of the first search for long-lived gluinos produced in 7 TeV pp collisions at the CERN Large Hadron Collider are presented. The search looks for evidence of long-lived particles that stop in the CMS detector and decay in the quiescent periods between beam crossings. In a dataset with a peak instantaneous luminosity of1 1032cm2s1, an integrated luminosity of10 pb1, and a search interval corresponding to 62 hours of LHC operation, no significant excess above background was observed. Limits at the 95% confidence level on gluino pair production over 13 orders of magnitude of gluino lifetime are set. For a mass difference m_~g m_~0

1> 100 GeV=c

2_{, and assuming}_{BRð~g ! g~}0

1Þ ¼ 100%,

m_~g< 370 GeV=c2_{are excluded for lifetimes from}_{10 s to 1000 s.}

DOI:10.1103/PhysRevLett.106.011801 PACS numbers: 14.80.Ly, 12.60.Jv, 13.85.Rm

Many extensions of the standard model predict the ex-istence of new heavy quasistable particles [1]. Such parti-cles are present in some supersymmetric models [2–4], ‘‘hidden valley’’ scenarios [5], and grand-unified theories (GUTs), where the new particles decay through dimension five or six operators suppressed by the GUT scale [6]. Long-lived particles are also a hallmark of split supersym-metry [7], where the gluino (~g) decay is suppressed due to

the large gluino-squark mass splitting, from which the theory gets its name. Of these possibilities, the Compact Muon Solenoid (CMS) experiment is most sensitive to models like split supersymmetry where production pro-ceeds via the strong interaction resulting in relatively large cross sections at the Large Hadron Collider (LHC) [8–11]. For this reason, we have targeted the search described in this Letter at long-lived gluinos. Existing experimental constraints on the lifetime of such gluinos are weak [12,13]; these gluinos may be stable on typical CMS experimental time scales. Lifetimes ofOð100–1000Þ sec-onds are especially interesting in cosmology since such decays would affect the primordial light element abundan-ces, and could resolve the present discrepancy between the measured6Li and7Li abundances and those predicted by conventional big-bang nucleosynthesis [14–16].

If long-lived gluinos were produced at the LHC, they would hadronize into ~gg, ~gq q, ~gqqq states, collectively known as ‘‘R hadrons’’ some of which would be charged, while others would be neutral [17–19]. Those that were charged would lose energy via ionization as they traverse the CMS detector. For slow R hadrons, this energy loss would be sufficient to bring a significant fraction of the produced particles to rest inside the CMS detector volume

[20]. These ‘‘stopped’’ R hadrons may decay seconds, days, or even weeks later, resulting in a jetlike energy deposit in the CMS calorimeter. These decays will be out of time with respect to LHC collisions and may well occur at times when there are no collisions in CMS. The obser-vation of such decays, in what should be a ‘‘quiet’’ detector except for an occasional cosmic ray, would be an unam-biguous discovery of new physics. The CMS apparatus has an overall length of 22 m, a diameter of 15 m, and weighs 14000 tons. The CMS coordinate system has the origin at the center of the detector. The z axis points along the direction of the counterclockwise beam, with the transverse plane perpendicular to the beam; is the azi-muthal angle in radians, is the polar angle, and the pseudorapidity is lnðtan½=2Þ. The central feature of the CMS apparatus is a superconducting solenoid of 6 m internal diameter, providing a field of 3.8 T. Within the field volume are the silicon pixel and strip tracker, the crystal electromagnetic calorimeter (ECAL) and the brass-scintillator hadronic calorimeter (HCAL). Muons are measured in gas-ionization detectors embedded in the steel return yoke. The HCAL, when combined with the ECAL, measures jets with a resolution E=E 100%pffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiE½GeV 5%. The calorimeter cells are grouped in projective towers, of granularity ¼ 0:087 0:087 at central rapidities. In this analysis, jets are recon-structed using an iterative cone algorithm with R¼

ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 2_þ2

p

¼ 0:5. The reconstructed jet energy E is defined as the scalar sum of the calorimeter tower energies inside the jet. The first level (L1) of the CMS trigger system, composed of custom hardware processors, uses information from the calorimeters and muon detectors to select (in less than 3 s) the most interesting events. The High Level Trigger (HLT) processor farm further decreases the event rate to 300 Hz before data storage. A more detailed description of the CMS experiment can be found elsewhere [21].

*Full author list given at the end of the article.

Published by The American Physical Society under the terms of the Creative Commons Attribution 3.0 License. Further distri-bution of this work must maintain attridistri-bution to the author(s) and the published article’s title, journal citation, and DOI.

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The 7 TeV center-of-mass pp collision data analyzed in this Letter were recorded by CMS between April and October 2010. We divide these data into two samples: the first corresponds to 95 hours of trigger live-time during LHC ‘‘fills’’, in which the instantaneous luminosity was 2–7 1027 _cm2_s1_{. We use this as a control sample to}

estimate the background rate. Because these data were recorded at relatively low instantaneous luminosity, there is negligible risk that a stopped-particle signal is present in this sample. The second sample, in which we search for the presence of a stopped-particle signal, corresponds to 62 hours of trigger live-time during which data, corre-sponding to an integrated luminosity of 10 pb1, were recorded by CMS with a peak instantaneous luminosity of 1 1032 cm2s1. In producing these data, the LHC was filled with up to 312 proton bunches per beam (out of a maximum of 2808).

We employed a dedicated trigger to search for decays of particles at times when there are no collisions. Information from the beam position and timing (BPTX) monitors are used to identify gaps between the proton bunches that comprise the LHC beam. The BPTX monitors are posi-tioned 175 m from the center of CMS on either side of the CMS interaction region and produce a signal when an LHC proton bunch passes the monitor. Even though the R-hadron decay does not produce a true jet, the resultant energy deposition is sufficiently jetlike that a jet trigger is reasonably efficient. We therefore require a jet trigger together with the condition that a coincidence of signals from both BPTX did not occur, ensuring that the trigger will not fire on jets produced from pp collisions. The L1 trigger requires a jet with at least 10 GeV transverse energy. A 20 GeV threshold on jet energy is applied in the HLT. At both L1 and HLT, the pseudorapidity of the jet, jjetj, is required to be less than 3.0. Additional selection

criteria are applied during data analysis. Despite the BPTX veto in the trigger, several beam-related processes remain possible sources of background. In order to reject back-ground events due to an unpaired proton bunch passing through CMS, events in which either BPTX is over thresh-old are vetoed. Instrumental effects during trigger genera-tion, and features of the LHC beam such as lower intensity ‘‘satellite’’ bunches that accompany the colliding protons, can cause triggers in some of the 25 ns intervals (BX’s) which precede or follow the one in which the intended proton collisions occur. We therefore reject any event occurring up to two BX’s before, or one BX after, the BX in which collisions are expected. To reject beam-halo muon events, which may not be synchronous with proton collisions, we employ a loose beam-halo veto using the cathode strip chambers (CSC) in the endcap muon system. The algorithm rejects events in which a beam-halo trigger was recorded, or a track segment was reconstructed in the CSC system with timing consistent with beam-halo, or a muon track was reconstructed with beam-halo-like

kinematics. Finally, to ensure that no out-of-time pp col-lision events due to satellite bunches contaminate the search sample, events with one or more reconstructed primary vertices are rejected. A small fraction of cosmic rays traversing the CMS detector deposit significant energy in the calorimeters. To reduce this background, events that contain reconstructed muons are vetoed. Once beam-related backgrounds and cosmic rays are removed, the remaining source of background is instrumental noise. Standard calorimeter cleaning and noise rejection criteria [22–24] are applied. Since gluinos are produced (and cor-respondingly stopped) nearly isotropically, we restrict our search to jets in the less noisy central HCAL; we require that the most energetic jet in the event hasj_jetj < 1:3. To suppress noise fluctuations and energy deposits from cos-mic rays, a jet with reconstructed energy above 50 GeV is required. To remove events where a single HCAL channel has misfired, events with more than 90% of the energy deposited in three or fewer calorimeter towers are vetoed. We also require that the leading jet has at least 60% of its energy contained in fewer than 6 towers. To suppress noise from hybrid photodiode discharge [22], events with 5 or more of the leading towers at the same azimuthal angle, or where more than 95% of the jet energy is contained within towers at the same azimuthal angle, are rejected. The HCAL electronics have a well-defined time response to charge deposits generated by showering particles. Analog signal pulses produced by these electronics are sampled at 40 MHz, synchronized with the LHC clock. These pulses are readout over ten BX samples centered around the pulse maximum. A physical pulse has some notable properties which we use to distinguish it from noise pulses. There is a clear peak in the signal pulse shape (BX_peak), significant energy in one bunch crossing before the peak (BX_peak1), and an exponential decay for several BX’s following the peak. We use the ratios R₁¼ BX_peakþ1=BX_peak and R₂ ¼ BXpeakþ2=BXpeakþ1 to characterize the exponential decay,

requiring R₁> 0:15 and 0:10 < R₂< 0:50. Since a physi-cal pulse spans only four time samples we are able to reject noise events based on the presence of energy in previous or successive BX’s. We remove events with more than 10% of the energy of the pulse outside of the central four BX’s. Energy deposits from physical particles tend to have a large fraction of the pulse energy in the peak BX. Noise does not produce this pulse shape; noise pulses tend to be spread across many BX’s or localized in one BX. We require the ratio of the peak energy to the total energy to be between 0.4 and 0.7. The requirement that the pulse shape satisfy all the preceding criteria rejects 50% of the remaining events in the background sample while preserv-ing 93% of simulated signal events.

We have developed a custom, factorized simulation of gluino production, stopping, and decay to investigate the experimental signature of this atypical signal. First, we generate qq ! ~g ~g and gg ! ~g ~g events at pffiffiffis¼ 7 TeV

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usingPYTHIA [25]. The lifetime of the gluino is set such

that it is stable. Gluino masses m_~g¼ 150 to 500 GeV=c2 are studied.PYTHIAhadronizes the produced gluino into R hadrons. A modified GEANT4 [26] that implements a ‘‘cloud model’’ of heavy stable colored interactions with matter [27] is used to simulate the interaction of these R hadrons with the CMS detector and to record the location at which those R hadrons that do not exit the detector come to rest. Using this simulation, the probability of a single R hadron to stop in the CMS detector was determined to be 0:2 for the explored gluino mass range. We also consid-ered alternative, more pessimistic, models of R-hadronic interactions with matter. For electromagnetic interactions (EM) only, the CMS stopping probability is found to be 0:06. Finally, with a ‘‘neutral R-baryon’’ model in which only R mesons stop [28,29] the stopping probability is 0:01.

Next, we again usePYTHIA to produce an R hadron at rest which we translate from the nominal vertex position to the recorded stopping location and decay the constituent gluino instantaneously to the lightest neutralino (~0₁) via ~g ! g~0

1. Finally, we use a specialized Monte Carlo

simu-lation to determine how often the stopped gluino decay would occur during a triggerable beam gap. Further details of this simulation are described elsewhere [30].

The efficiency with which triggered events pass all selection criteria is estimated from the simulation to be 54% for a representative gluino decay signal (m_~g ¼ 300 GeV=c2 _{and m}

~0

1 ¼ 200 GeV=c

2_{). This point was}

chosen to be above existing limits and within the reach of CMS. The equivalent efficiency with respect to all stopped particles is 17% since a significant number of R hadrons stop in uninstrumented regions of the CMS detec-tor where their subsequent decay would not be observable. For any new physics model that predicts events with suffi-cient visible energy, m_~g m_~0

1> 100 GeV=c

2_{, this}

effi-ciency does not change significantly. We measure the background rate in the control sample after all but one of the selection criteria are applied, RN1_control. We also mea-sure the background rate in the control sample after all selection criteria are applied, RN_control. To obtain an estimate of the background rate in the search sample after all selection criteria, we again measure the rate after omitting one selection criterion and multiply it by the ratio of the rates obtained from the control sample, RN_search ¼ RN1

searchðRNcontrol=RN1controlÞ. This procedure is performed twice,

each time omitting one of the most powerful background rejection criteria such that RN1 RN; we take the mean of both determinations as the final background rate esti-mate. We estimate the systematic uncertainty on the back-ground to be 23% from the observed variation of the control sample rate RN1_controlduring the time period in which the data were taken. There is also a potential systematic uncertainty due to the accuracy with which the energy deposition of our jetlike signal is simulated. From proton

and pion test-beam data and studies of the energy deposited in HCAL by incident cosmic rays, we estimate this intro-duces a 7% uncertainty on the acceptance. The systematic uncertainty due to trigger efficiency is negligible since the data analyzed are well above the turn-on region. Similarly, the systematic uncertainty due to reconstruction efficiency is negligible since we restrict our search to m_~g m_~0

1>

100 GeV=c2_{wherein we are fully efficient. Finally, there is}

an 11% uncertainty on the luminosity measurement [31]. Limits on a particular model (e.g., gluinos in split super-symmetry) introduce more substantial systematic uncer-tainties, since the signal yield is sensitive to the stopping probability and the stopping probability varies greatly depending on the model of R-hadronic interactions used in the simulation.

After the selection criteria described in the preceding paragraphs are applied, we perform a counting experiment and a time-profile analysis on the remaining data. For the counting experiment, we consider gluino lifetime hypoth-eses from 75 ns to106 s, where we have chosen the upper limit of the search to be the longest lifetime for which we can still expect to observe at least one event. For lifetime hypotheses shorter than one LHC orbit (89 s), we search within a time window following each filled bunch crossing. This time window is equal to 1:256 _~g for optimal sensitivity to each hypothesized gluino lifetime _~g. In addition to the lifetimes required to map the general fea-tures of the exclusion limit, we include two lifetimes for each observed event: the largest lifetime hypothesis for which the event lies outside the time window, and the smallest lifetime hypothesis for which the event is con-tained within the time window. For lifetime hypotheses longer than one LHC fill, we do not consider the possibility that any observed events may have come from gluinos produced in a previous fill.

In the search sample, we do not observe a significant excess above expected background for any lifetime hy-pothesis. The results of this counting experiment for se-lected lifetime hypotheses are presented in TableI. In the absence of any discernible signal, we proceed to set 95% confidence level (C.L.) limits over 13 orders of magnitude in gluino lifetime using a hybridCL_Smethod [32] inspired by Ref. [33]. In Fig. 1 we show the 95% C.L. limit on ðpp ! ~g ~gÞ BRð~g ! g~0

1Þ for a mass difference TABLE I. Results of counting experiments for selected values of _~g. Entries between1 105and1 106 s are identical and are suppressed from the table.

Lifetime [s] Expected Background ( stat syst) Observed

1 107 _{0:8 0:2 0:2} ₂

1 106 _{1:9 0:4 0:5} ₃

1 105 _{4:9 1:0 1:3} ₅

1 106 _{4:9 1:0 1:3} ₅

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m_~g m~0

1> 100 GeV=c

2_. _The _error _bands _include

statistical and systematic uncertainties. With the horizontal line in Fig.1we show a recentNLO þ NLL calculation of the cross section at pffiffiffis¼ 7 TeV for m_~g¼ 300 GeV=c2 from the authors of Ref. [11]. To illustrate the effect of the stopping probability uncertainty, we present three different 95% C.L. limits on ðpp ! ~g ~gÞ BRð~g ! g ~X0₁Þ in which the three different R-hadron models are used. Assuming the cloud model for the interaction of R hadrons with matter, and assuming BRð~g ! g~0₁Þ ¼ 100%, we are able to exclude lifetimes from 75 ns to 3 105 s for m_~g¼ 300 GeV=c2 _{with the counting experiment. Finally,}

we present the result as a function of the gluino mass in Fig.2. Under the same assumptions as for the cross section limit, we exclude m_~g< 370 GeV=c2for lifetimes between 10 s and 1000 s. If we assume the EM only model for R-hadronic interactions with matter in order to compare with what was done in Ref. [12], this exclusion becomes m_~g< 302 GeV=c2_.

We also perform a time-profile analysis. Whereas, for short lifetimes, a signal from a stopped gluino decay is correlated in time with the collisions, backgrounds are at in time. Since the signal and background have very different time profiles, it is possible to extract both their contribu-tions by analyzing the distribution of the observed events in time. We assume all colliding bunches in an orbit have equal individual instantaneous luminosity. We build a probability density function (PDF) for the gluino decay signal as a function of time for a given gluino lifetime hypothesis and the actual times of LHC beam crossings as recorded in our data. Figure3shows an example of such a

PDF for a gluino lifetime of1 s; the in-orbit positions of 2 observed events in the subset of our data that were recorded during an LHC fill with 140 colliding bunches are overlaid. We limit the range of lifetime hypotheses considered for this time-prole analysis to 75 ns to100 s such that the gluino lifetime is not much longer than the orbit period. For each lifetime hypothesis we build a corresponding signal time profile, fit the signal plus back-ground contribution to the data, and extract a 95% C.L. upper limit on the possible signal contribution. The ob-tained results are plotted as a dotted line in Fig. 1. This temporal analysis relies only on the flatness of the background shape; it does not have the counting experi-ment’s systematic uncertainty on the background normal-ization. Consequently, its dominant systematic uncertainty is the 11% uncertainty on the luminosity measurement. For a mass difference m_~g m_~0

1> 100 GeV=c

2_{, assuming}

BRð~g ! g~0

1Þ ¼ 100%, we are able to exclude m~g<

382 GeV=c2 _{at the 95% C.L. for a lifetime of}_{10 s with}

the time-prole analysis.

We have presented the results of the first search for long-lived gluinos produced in 7 TeV pp collisions at the LHC. We looked for the subsequent decay of those gluinos that would have stopped in the CMS detector during time intervals where there were no pp collisions. In particular, we searched for decays during gaps in the LHC beam structure. We recorded such decays with dedicated calo-rimeter triggers. In a data set with a peak instantaneous luminosity of1 1032 cm2s1, an integrated luminosity of 10 pb1, and a search interval corresponding to 62 h of LHC operation, no significant excess above background

] 2 [GeV/c g ~ m 100 150 200 250 300 350 400 450 500 ) [pb] 0 χ∼ g → g BR(× ) g g → (ppσ ₁₀ 2 10 3 10 4 10 95% C.L. Limits s - 1000 s Counting Exp. µ Expected: 10 s - 1000 s Counting Exp. µ : 10 σ 1 ± Expected s - 1000 s Counting Exp. µ : 10 σ 2 ± Expected

s - 1000 s Counting Exp. (EM only) µ Obs.: 10 s - 1000 s Counting Exp. µ Obs.: 10 s Timing Profile µ Obs.: 10 NLO+NLL Not Sensitive -1 L dt = 10 pb

∫

-1 s -2 cm 32 = 1 x 10 inst max L = 7 TeV s 2 = 100 GeV/c 0 χ∼ - m g ~ m ] 2 [GeV/c g ~ m 100 150 200 250 300 350 400 450 500 ) [pb] 0 χ∼ g → g BR(× ) g g → (ppσ ₁₀ 2 10 3 10 4 10

FIG. 2 (color online). 95% C.L. limits on gluino pair produc-tion cross secproduc-tion times branching fracproduc-tion as a funcproduc-tion of gluino mass assuming the ‘‘cloud model’’ of R-hadron interac-tions (solid line) and EM interacinterac-tions only (dot-dashed line). The m_~g m_~0

1mass difference is maintained at100 GeV=c

2_{; results}

are only presented for m_~0

1> 50 GeV=c

2_{. The} _{NLO þ NLL}

calculation is from a private communication with the authors of Ref. [11]. The lifetimes chosen are those for which the counting experiment and time-profile analysis are most sensitive.

[s] g τ -7 10 10-610-5₁₀-4 -3 10 ₁₀-2 ₁₀-1 ₁ ₁₀ ₁₀2 3 10 ₁₀4 5 10 106 ) [pb] 0 χ∼ g → g BR(× ) g g → (ppσ ₁₀ 2 10 3 10 4 10 -1 L dt = 10 pb

∫

-1 s -2 cm 32 = 1 x 10 inst max L = 7 TeV s 2 = 100 GeV/c 0 χ∼ - m g ~ m 95% C.L. Limits:

Expected: Counting Exp. : Counting Exp. σ 1 ± Expected : Counting Exp. σ 2 ± Expected Obs.: Counting Exp.

Obs.: Counting Exp. (Neutral R-Baryon) Obs.: Counting Exp. (EM only) Obs.: Timing Profile

) 2 = 300 GeV/c g ~ NLO+NLL (m [s] g τ -7 10 10-610-5₁₀-4 -3 10 ₁₀-2 ₁₀-1 ₁ ₁₀ ₁₀2 3 10 ₁₀4 5 10 106 ) [pb] 0 χ∼ g → g BR(× ) g g → (ppσ ₁₀ 2 10 3 10 4 10

FIG. 1 (color online). Expected and observed 95% C.L. limits on gluino pair production cross section times branching fraction using the ‘‘cloud model’’ of R-hadron interactions as a function of gluino lifetime from both the counting experiment and the time-profile analysis. Observed 95% C.L. limits on the gluino cross section for alternative R-hadron interaction models are also presented. The NLO þ NLL calculation is for m_~g¼ 300 GeV=c2_{from a private communication with the authors of}

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was observed. Limits at the 95% C.L. on gluino pair production over 13 orders of magnitude of gluino lifetime are set. For a mass difference m_~g m_~0

1>

100 GeV=c2_{, assuming} _{BRð~g ! g~}0

1Þ ¼ 100%, we

ex-clude m_~g< 370 GeV=c2 for lifetimes from 10 s to 1000 s with a counting experiment. Under the same as-sumptions, we are able to further exclude m_~g< 382 GeV=c2 _{at the 95% C.L. for a lifetime of}_{10 s with}

a time-prole analysis. These results extend existing limits from the D0 Collaboration [12] on both gluino lifetime and gluino mass. These limits are the most restrictive to date.

We wish to congratulate our colleagues in the CERN accelerator departments for the excellent performance of the LHC machine. We thank the technical and administra-tive staff at CERN and other CMS institutes, and acknowl-edge support from: FMSR (Austria); FNRS and FWO (Belgium); CNPq, CAPES, FAPERJ, and FAPESP (Brazil); MES (Bulgaria); CERN; CAS, MoST, and NSFC (China); COLCIENCIAS (Colombia); MSES (Croatia); RPF (Cyprus); Academy of Sciences and NICPB (Estonia); Academy of Finland, ME, and HIP (Finland); CEA and CNRS/IN2P3 (France); BMBF, DFG, and HGF (Germany); GSRT (Greece); OTKA and NKTH (Hungary); DAE and DST (India); IPM (Iran); SFI (Ireland); INFN (Italy); NRF and WCU (Korea); LAS (Lithuania); CINVESTAV, CONACYT, SEP, and UASLP-FAI (Mexico); PAEC (Pakistan); SCSR (Poland); FCT (Portugal); JINR (Armenia, Belarus, Georgia, Ukraine, Uzbekistan); MST and MAE (Russia); MSTD (Serbia); MICINN and CPAN (Spain); Swiss Funding Agencies (Switzerland); NSC (Taipei); TUBITAK and TAEK (Turkey); STFC (United Kingdom); DOE and

NSF (USA).

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BX 0 500 1000 1500 2000 2500 3000 3500 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 BX 0 500 1000 1500 2000 2500 3000 3500 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 CMS Data (2010) s) µ = 1 τ Signal PDF ( BX 1300 1350 1400 1450 1500 1550 1600 0 0.2 0.4 0.6 0.8 1 1.2 BX 1300 1350 1400 1450 1500 1550 1600 0 0.2 0.4 0.6 0.8 1 1.2 BX 3150 3200 3250 3300 3350 3400 3450 0 0.2 0.4 0.6 0.8 1 1.2 BX 3150 3200 3250 3300 3350 3400 3450 0 0.2 0.4 0.6 0.8 1 1.2

FIG. 3 (color online). The top panel shows the in-orbit posi-tions of 2 observed events in the subset of our data that was recorded during an LHC fill with 140 colliding bunches. The decay profile for a 1 s lifetime hypothesis is overlaid. The bottom panels are zoomed views of the boxed regions around the 2 events in the top panel so that the exponential decay shape of the signal hypothesis can be seen.

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M. Jeitler,2G. Kasieczka,2W. Kiesenhofer,2M. Krammer,2D. Liko,2I. Mikulec,2M. Pernicka,2H. Rohringer,2 R. Scho¨fbeck,2J. Strauss,2A. Taurok,2F. Teischinger,2W. Waltenberger,2G. Walzel,2E. Widl,2C.-E. Wulz,2 V. Mossolov,3N. Shumeiko,3J. Suarez Gonzalez,3L. Benucci,4L. Ceard,4K. Cerny,4E. A. De Wolf,4X. Janssen,4

T. Maes,4L. Mucibello,4S. Ochesanu,4B. Roland,4R. Rougny,4M. Selvaggi,4H. Van Haevermaet,4 P. Van Mechelen,4N. Van Remortel,4V. Adler,5S. Beauceron,5F. Blekman,5S. Blyweert,5J. D’Hondt,5 O. Devroede,5A. Kalogeropoulos,5J. Maes,5M. Maes,5S. Tavernier,5W. Van Doninck,5P. Van Mulders,5 G. P. Van Onsem,5I. Villella,5O. Charaf,6B. Clerbaux,6G. De Lentdecker,6V. Dero,6A. P. R. Gay,6G. H. Hammad,6

T. Hreus,6P. E. Marage,6L. Thomas,6C. Vander Velde,6P. Vanlaer,6J. Wickens,6S. Costantini,7M. Grunewald,7 B. Klein,7A. Marinov,7D. Ryckbosch,7F. Thyssen,7M. Tytgat,7L. Vanelderen,7P. Verwilligen,7S. Walsh,7 N. Zaganidis,7S. Basegmez,8G. Bruno,8J. Caudron,8J. De Favereau De Jeneret,8C. Delaere,8P. Demin,8D. Favart,8

A. Giammanco,8G. Gre´goire,8J. Hollar,8V. Lemaitre,8J. Liao,8O. Militaru,8S. Ovyn,8D. Pagano,8A. Pin,8 K. Piotrzkowski,8L. Quertenmont,8N. Schul,8N. Beliy,9T. Caebergs,9E. Daubie,9G. A. Alves,10 D. De Jesus Damiao,10M. E. Pol,10M. H. G. Souza,10W. Carvalho,11E. M. Da Costa,11C. De Oliveira Martins,11

S. Fonseca De Souza,11L. Mundim,11H. Nogima,11V. Oguri,11W. L. Prado Da Silva,11A. Santoro,11 S. M. Silva Do Amaral,11A. Sznajder,11F. Torres Da Silva De Araujo,11F. A. Dias,12M. A. F. Dias,12 Tomei T. R. Fernandez Perez,12E. M. Gregores,12,cF. Marinho,12S. F. Novaes,12Sandra S. Padula,12 N. Darmenov,13,bL. Dimitrov,13V. Genchev,13,bP. Iaydjiev,13,bS. Piperov,13M. Rodozov,13S. Stoykova,13 G. Sultanov,13V. Tcholakov,13R. Trayanov,13I. Vankov,13M. Dyulendarova,14R. Hadjiiska,14V. Kozhuharov,14

L. Litov,14E. Marinova,14M. Mateev,14B. Pavlov,14P. Petkov,14J. G. Bian,15G. M. Chen,15H. S. Chen,15 C. H. Jiang,15D. Liang,15S. Liang,15J. Wang,15J. Wang,15X. Wang,15Z. Wang,15M. Xu,15M. Yang,15J. Zang,15

Z. Zhang,15Y. Ban,16S. Guo,16W. Li,16Y. Mao,16S. J. Qian,16H. Teng,16B. Zhu,16A. Cabrera,17 B. Gomez Moreno,17A. A. Ocampo Rios,17A. F. Osorio Oliveros,17J. C. Sanabria,17N. Godinovic,18D. Lelas,18

K. Lelas,18R. Plestina,18,dD. Polic,18I. Puljak,18Z. Antunovic,19M. Dzelalija,19V. Brigljevic,20S. Duric,20 K. Kadija,20S. Morovic,20A. Attikis,21R. Fereos,21M. Galanti,21J. Mousa,21C. Nicolaou,21F. Ptochos,21 P. A. Razis,21H. Rykaczewski,21Y. Assran,22,eM. A. Mahmoud,22,fA. Hektor,23M. Kadastik,23K. Kannike,23 M. Mu¨ntel,23M. Raidal,23L. Rebane,23V. Azzolini,24P. Eerola,24S. Czellar,25J. Ha¨rko¨nen,25A. Heikkinen,25 V. Karima¨ki,25R. Kinnunen,25J. Klem,25M. J. Kortelainen,25T. Lampe´n,25K. Lassila-Perini,25S. Lehti,25

T. Lindeń,25P. Luukka,25T. Maënpaä¨,25E. Tuominen,25J. Tuominiemi,25E. Tuovinen,25D. Ungaro,25 L. Wendland,25K. Banzuzi,26A. Korpela,26T. Tuuva,26D. Sillou,27M. Besancon,28M. Dejardin,28D. Denegri,28

B. Fabbro,28J. L. Faure,28F. Ferri,28S. Ganjour,28F. X. Gentit,28A. Givernaud,28P. Gras,28

G. Hamel de Monchenault,28P. Jarry,28E. Locci,28J. Malcles,28M. Marionneau,28L. Millischer,28J. Rander,28 A. Rosowsky,28I. Shreyber,28M. Titov,28P. Verrecchia,28S. Baffioni,29F. Beaudette,29L. Bianchini,29M. Bluj,29,g C. Broutin,29P. Busson,29C. Charlot,29L. Dobrzynski,29R. Granier de Cassagnac,29M. Haguenauer,29P. Mine´,29 C. Mironov,29C. Ochando,29P. Paganini,29S. Porteboeuf,29D. Sabes,29R. Salerno,29Y. Sirois,29C. Thiebaux,29

B. Wyslouch,29,hA. Zabi,29J.-L. Agram,30,iJ. Andrea,30A. Besson,30D. Bloch,30D. Bodin,30J.-M. Brom,30 M. Cardaci,30E. C. Chabert,30C. Collard,30E. Conte,30,iF. Drouhin,30,iC. Ferro,30J.-C. Fontaine,30,iD. Gele´,30

U. Goerlach,30S. Greder,30P. Juillot,30M. Karim,30,iA.-C. Le Bihan,30Y. Mikami,30P. Van Hove,30F. Fassi,31 D. Mercier,31C. Baty,32N. Beaupere,32M. Bedjidian,32O. Bondu,32G. Boudoul,32D. Boumediene,32H. Brun,32 N. Chanon,32R. Chierici,32D. Contardo,32P. Depasse,32H. El Mamouni,32A. Falkiewicz,32J. Fay,32S. Gascon,32 B. Ille,32T. Kurca,32T. Le Grand,32M. Lethuillier,32L. Mirabito,32S. Perries,32V. Sordini,32S. Tosi,32Y. Tschudi,32 P. Verdier,32H. Xiao,32V. Roinishvili,33G. Anagnostou,34M. Edelhoff,34L. Feld,34N. Heracleous,34O. Hindrichs,34 R. Jussen,34K. Klein,34J. Merz,34N. Mohr,34A. Ostapchuk,34A. Perieanu,34F. Raupach,34J. Sammet,34S. Schael,34 D. Sprenger,34H. Weber,34M. Weber,34B. Wittmer,34M. Ata,35W. Bender,35M. Erdmann,35J. Frangenheim,35

T. Hebbeker,35A. Hinzmann,35K. Hoepfner,35C. Hof,35T. Klimkovich,35D. Klingebiel,35P. Kreuzer,35,b D. Lanske,35,aC. Magass,35G. Masetti,35M. Merschmeyer,35A. Meyer,35P. Papacz,35H. Pieta,35H. Reithler,35 S. A. Schmitz,35L. Sonnenschein,35J. Steggemann,35D. Teyssier,35M. Bontenackels,36M. Davids,36M. Duda,36

G. Flu¨gge,36H. Geenen,36M. Giffels,36W. Haj Ahmad,36D. Heydhausen,36T. Kress,36Y. Kuessel,36A. Linn,36 A. Nowack,36L. Perchalla,36O. Pooth,36J. Rennefeld,36P. Sauerland,36A. Stahl,36M. Thomas,36D. Tornier,36

M. H. Zoeller,36M. Aldaya Martin,37W. Behrenhoff,37U. Behrens,37M. Bergholz,37,jK. Borras,37A. Cakir,37 A. Campbell,37E. Castro,37D. Dammann,37G. Eckerlin,37D. Eckstein,37A. Flossdorf,37G. Flucke,37A. Geiser,37

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A. Knutsson,37D. Kru¨cker,37E. Kuznetsova,37W. Lange,37W. Lohmann,37,jR. Mankel,37M. Marienfeld,37 I.-A. Melzer-Pellmann,37A. B. Meyer,37J. Mnich,37A. Mussgiller,37J. Olzem,37A. Parenti,37A. Raspereza,37 A. Raval,37R. Schmidt,37,jT. Schoerner-Sadenius,37N. Sen,37M. Stein,37J. Tomaszewska,37D. Volyanskyy,37

R. Walsh,37C. Wissing,37C. Autermann,38S. Bobrovskyi,38J. Draeger,38H. Enderle,38U. Gebbert,38 K. Kaschube,38G. Kaussen,38R. Klanner,38B. Mura,38S. Naumann-Emme,38F. Nowak,38N. Pietsch,38C. Sander,38

H. Schettler,38P. Schleper,38M. Schro¨der,38T. Schum,38J. Schwandt,38A. K. Srivastava,38H. Stadie,38 G. Steinbru¨ck,38J. Thomsen,38R. Wolf,38J. Bauer,39V. Buege,39T. Chwalek,39W. De Boer,39A. Dierlamm,39 G. Dirkes,39M. Feindt,39J. Gruschke,39C. Hackstein,39F. Hartmann,39S. M. Heindl,39M. Heinrich,39H. Held,39

K. H. Hoffmann,39S. Honc,39T. Kuhr,39D. Martschei,39S. Mueller,39Th. Mu¨ller,39M. Niegel,39O. Oberst,39 A. Oehler,39J. Ott,39T. Peiffer,39D. Piparo,39G. Quast,39K. Rabbertz,39F. Ratnikov,39M. Renz,39C. Saout,39 A. Scheurer,39P. Schieferdecker,39F.-P. Schilling,39G. Schott,39H. J. Simonis,39F. M. Stober,39D. Troendle,39 J. Wagner-Kuhr,39M. Zeise,39V. Zhukov,39,kE. B. Ziebarth,39G. Daskalakis,40T. Geralis,40S. Kesisoglou,40

A. Kyriakis,40D. Loukas,40I. Manolakos,40A. Markou,40C. Markou,40C. Mavrommatis,40E. Petrakou,40 L. Gouskos,41T. J. Mertzimekis,41A. Panagiotou,41,bI. Evangelou,42C. Foudas,42P. Kokkas,42N. Manthos,42

I. Papadopoulos,42V. Patras,42F. A. Triantis,42A. Aranyi,43G. Bencze,43L. Boldizsar,43G. Debreczeni,43 C. Hajdu,43,bD. Horvath,43,lA. Kapusi,43K. Krajczar,43,mA. Laszlo,43F. Sikler,43G. Vesztergombi,43,mN. Beni,44

J. Molnar,44J. Palinkas,44Z. Szillasi,44V. Veszpremi,44P. Raics,45Z. L. Trocsanyi,45B. Ujvari,45S. Bansal,46 S. B. Beri,46V. Bhatnagar,46N. Dhingra,46M. Jindal,46M. Kaur,46J. M. Kohli,46M. Z. Mehta,46N. Nishu,46

L. K. Saini,46A. Sharma,46A. P. Singh,46J. B. Singh,46S. P. Singh,46S. Ahuja,47S. Bhattacharya,47 B. C. Choudhary,47P. Gupta,47S. Jain,47S. Jain,47A. Kumar,47R. K. Shivpuri,47R. K. Choudhury,48D. Dutta,48 S. Kailas,48S. K. Kataria,48A. K. Mohanty,48,bL. M. Pant,48P. Shukla,48P. Suggisetti,48T. Aziz,49M. Guchait,49,n

A. Gurtu,49M. Maity,49,oD. Majumder,49G. Majumder,49K. Mazumdar,49G. B. Mohanty,49A. Saha,49 K. Sudhakar,49N. Wickramage,49S. Banerjee,50S. Dugad,50N. K. Mondal,50H. Arfaei,51H. Bakhshiansohi,51

S. M. Etesami,51A. Fahim,51M. Hashemi,51A. Jafari,51M. Khakzad,51A. Mohammadi,51

M. Mohammadi Najafabadi,51S. Paktinat Mehdiabadi,51B. Safarzadeh,51M. Zeinali,51M. Abbrescia,52a,52b L. Barbone,52a,52bC. Calabria,52a,52bA. Colaleo,52aD. Creanza,52a,52cN. De Filippis,52a,52cM. De Palma,52a,52b

A. Dimitrov,52aL. Fiore,52aG. Iaselli,52a,52cL. Lusito,52a,52b,bG. Maggi,52a,52cM. Maggi,52aN. Manna,52a,52b B. Marangelli,52a,52bS. My,52a,52cS. Nuzzo,52a,52bN. Pacifico,52a,52bG. A. Pierro,52aA. Pompili,52a,52b G. Pugliese,52a,52cF. Romano,52a,52cG. Roselli,52a,52bG. Selvaggi,52a,52bL. Silvestris,52aR. Trentadue,52a S. Tupputi,52a,52bG. Zito,52aG. Abbiendi,53aA. C. Benvenuti,53aD. Bonacorsi,53aS. Braibant-Giacomelli,53a,53b

P. Capiluppi,53a,53bA. Castro,53a,53bF. R. Cavallo,53aM. Cuffiani,53a,53bG. M. Dallavalle,53aF. Fabbri,53a A. Fanfani,53a,53bD. Fasanella,53aP. Giacomelli,53aM. Giunta,53aC. Grandi,53aS. Marcellini,53a M. Meneghelli,53a,53bA. Montanari,53aF. L. Navarria,53a,53bF. Odorici,53aA. Perrotta,53aA. M. Rossi,53a,53b T. Rovelli,53a,53bG. Siroli,53a,53bR. Travaglini,53a,53bS. Albergo,54a,54bG. Cappello,54a,54bM. Chiorboli,54a,54b,b S. Costa,54a,54bA. Tricomi,54a,54bC. Tuve,54aG. Barbagli,55aV. Ciulli,55a,55bC. Civinini,55aR. D’Alessandro,55a,55b

E. Focardi,55a,55bS. Frosali,55a,55bE. Gallo,55aC. Genta,55aP. Lenzi,55a,55bM. Meschini,55aS. Paoletti,55a G. Sguazzoni,55aA. Tropiano,55a,bL. Benussi,56S. Bianco,56S. Colafranceschi,56,pF. Fabbri,56D. Piccolo,56 P. Fabbricatore,57R. Musenich,57A. Benaglia,58a,58bG. B. Cerati,58a,58bF. De Guio,58a,58b,bL. Di Matteo,58a,58b

A. Ghezzi,58a,58b,bM. Malberti,58a,58bS. Malvezzi,58aA. Martelli,58a,58bA. Massironi,58a,58bD. Menasce,58a L. Moroni,58aM. Paganoni,58a,58bD. Pedrini,58aS. Ragazzi,58a,58bN. Redaelli,58aS. Sala,58a

T. Tabarelli de Fatis,58a,58bV. Tancini,58a,58bS. Buontempo,59aC. A. Carrillo Montoya,59aA. Cimmino,59a,59b A. De Cosa,59a,59bM. De Gruttola,59a,59bF. Fabozzi,59a,qA. O. M. Iorio,59aL. Lista,59aM. Merola,59a,59b P. Noli,59a,59bP. Paolucci,59aP. Azzi,60aN. Bacchetta,60aP. Bellan,60a,60bM. Bellato,60aD. Bisello,60a,60b A. Branca,60aP. Checchia,60aE. Conti,60aM. De Mattia,60a,60bT. Dorigo,60aF. Gasparini,60a,60bP. Giubilato,60a,60b

A. Gresele,60a,60cS. Lacaprara,60a,rI. Lazzizzera,60a,60bM. Margoni,60a,60bG. Maron,60a,rA. T. Meneguzzo,60a,60b M. Nespolo,60aM. Passaseo,60aL. Perrozzi,60a,bN. Pozzobon,60a,60bP. Ronchese,60a,60bF. Simonetto,60a,60b E. Torassa,60aM. Tosi,60a,60bA. Triossi,60aS. Vanini,60a,60bP. Zotto,60a,60bG. Zumerle,60a,60bP. Baesso,61a,61b U. Berzano,61aC. Riccardi,61a,61bP. Torre,61a,61bP. Vitulo,61a,61bC. Viviani,61a,61bM. Biasini,62a,62bG. M. Bilei,62a

B. Caponeri,62a,62bL. Fano`,62a,62bP. Lariccia,62a,62bA. Lucaroni,62a,62b,bG. Mantovani,62a,62bM. Menichelli,62a A. Nappi,62a,62bA. Santocchia,62a,62bL. Servoli,62aS. Taroni,62a,62bM. Valdata,62a,62bR. Volpe,62a,62b,b

P. Azzurri,63a,63cG. Bagliesi,63aJ. Bernardini,63a,63bT. Boccali,63a,bG. Broccolo,63a,63cR. Castaldi,63a

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R. T. D’Agnolo,63a,63cR. Dell’Orso,63aF. Fiori,63a,63bL. Foa`,63a,63cA. Giassi,63aA. Kraan,63aF. Ligabue,63a,63c T. Lomtadze,63aL. Martini,63aA. Messineo,63a,63bF. Palla,63aF. Palmonari,63aS. Sarkar,63a,63cG. Segneri,63a A. T. Serban,63aP. Spagnolo,63aR. Tenchini,63aG. Tonelli,63a,63b,bA. Venturi,63a,bP. G. Verdini,63aL. Barone,64a,64b F. Cavallari,64aD. Del Re,64a,64bE. Di Marco,64a,64bM. Diemoz,64aD. Franci,64a,64bM. Grassi,64aE. Longo,64a,64b

G. Organtini,64a,64bA. Palma,64a,64bF. Pandolfi,64a,64b,bR. Paramatti,64aS. Rahatlou,64a,64bN. Amapane,65a,65b R. Arcidiacono,65a,65cS. Argiro,65a,65bM. Arneodo,65a,65cC. Biino,65aC. Botta,65a,65b,bN. Cartiglia,65a R. Castello,65a,65bM. Costa,65a,65bN. Demaria,65aA. Graziano,65a,65b,bC. Mariotti,65aM. Marone,65a,65b S. Maselli,65aE. Migliore,65a,65bG. Mila,65a,65bV. Monaco,65a,65bM. Musich,65a,65bM. M. Obertino,65a,65c

N. Pastrone,65aM. Pelliccioni,65a,65b,bA. Romero,65a,65bM. Ruspa,65a,65cR. Sacchi,65a,65bV. Sola,65a,65b A. Solano,65a,65bA. Staiano,65aD. Trocino,65a,65bA. Vilela Pereira,65a,65b,bF. Ambroglini,66a,66bS. Belforte,66a

F. Cossutti,66aG. Della Ricca,66a,66bB. Gobbo,66aD. Montanino,66a,66bA. Penzo,66aS. G. Heo,67S. Chang,68 J. Chung,68D. H. Kim,68G. N. Kim,68J. E. Kim,68D. J. Kong,68H. Park,68D. Son,68D. C. Son,68Zero Kim,69 J. Y. Kim,69S. Song,69S. Choi,70B. Hong,70M. Jo,70H. Kim,70J. H. Kim,70T. J. Kim,70K. S. Lee,70D. H. Moon,70 S. K. Park,70H. B. Rhee,70E. Seo,70S. Shin,70K. S. Sim,70M. Choi,71S. Kang,71H. Kim,71C. Park,71I. C. Park,71

S. Park,71G. Ryu,71Y. Choi,72Y. K. Choi,72J. Goh,72J. Lee,72S. Lee,72H. Seo,72I. Yu,72M. J. Bilinskas,73 I. Grigelionis,73M. Janulis,73D. Martisiute,73P. Petrov,73T. Sabonis,73H. Castilla Valdez,74E. De La Cruz Burelo,74

R. Lopez-Fernandez,74A. Sa´nchez Herna´ndez,74L. M. Villasenor-Cendejas,74S. Carrillo Moreno,75 F. Vazquez Valencia,75H. A. Salazar Ibarguen,76E. Casimiro Linares,77A. Morelos Pineda,77M. A. Reyes-Santos,77

P. Allfrey,78D. Krofcheck,78J. Tam,78P. H. Butler,79R. Doesburg,79H. Silverwood,79M. Ahmad,80I. Ahmed,80 M. I. Asghar,80H. R. Hoorani,80W. A. Khan,80T. Khurshid,80S. Qazi,80M. Cwiok,81W. Dominik,81K. Doroba,81

A. Kalinowski,81M. Konecki,81J. Krolikowski,81T. Frueboes,82R. Gokieli,82M. Go´rski,82M. Kazana,82 K. Nawrocki,82K. Romanowska-Rybinska,82M. Szleper,82G. Wrochna,82P. Zalewski,82N. Almeida,83A. David,83

P. Faccioli,83P. G. Ferreira Parracho,83M. Gallinaro,83P. Martins,83P. Musella,83A. Nayak,83P. Q. Ribeiro,83 J. Seixas,83P. Silva,83J. Varela,83,bH. K. Wo¨hri,83I. Belotelov,84P. Bunin,84M. Finger,84M. Finger, Jr.,84 I. Golutvin,84A. Kamenev,84V. Karjavin,84G. Kozlov,84A. Lanev,84P. Moisenz,84V. Palichik,84V. Perelygin,84

S. Shmatov,84V. Smirnov,84A. Volodko,84A. Zarubin,84N. Bondar,85V. Golovtsov,85Y. Ivanov,85V. Kim,85 P. Levchenko,85V. Murzin,85V. Oreshkin,85I. Smirnov,85V. Sulimov,85L. Uvarov,85S. Vavilov,85A. Vorobyev,85

Yu. Andreev,86S. Gninenko,86N. Golubev,86M. Kirsanov,86N. Krasnikov,86V. Matveev,86A. Pashenkov,86 A. Toropin,86S. Troitsky,86V. Epshteyn,87V. Gavrilov,87V. Kaftanov,87,aM. Kossov,87,bA. Krokhotin,87 N. Lychkovskaya,87G. Safronov,87S. Semenov,87V. Stolin,87E. Vlasov,87A. Zhokin,87E. Boos,88M. Dubinin,88,s

L. Dudko,88A. Ershov,88A. Gribushin,88O. Kodolova,88I. Lokhtin,88S. Obraztsov,88S. Petrushanko,88 L. Sarycheva,88V. Savrin,88A. Snigirev,88V. Andreev,89M. Azarkin,89I. Dremin,89M. Kirakosyan,89 S. V. Rusakov,89A. Vinogradov,89I. Azhgirey,90S. Bitioukov,90V. Grishin,90,bV. Kachanov,90D. Konstantinov,90

A. Korablev,90V. Krychkine,90V. Petrov,90R. Ryutin,90S. Slabospitsky,90A. Sobol,90L. Tourtchanovitch,90 S. Troshin,90N. Tyurin,90A. Uzunian,90A. Volkov,90P. Adzic,91,tM. Djordjevic,91D. Krpic,91,tJ. Milosevic,91

M. Aguilar-Benitez,92J. Alcaraz Maestre,92P. Arce,92C. Battilana,92E. Calvo,92M. Cepeda,92M. Cerrada,92 N. Colino,92B. De La Cruz,92C. Diez Pardos,92C. Fernandez Bedoya,92J. P. Ferna´ndez Ramos,92A. Ferrando,92

J. Flix,92M. C. Fouz,92P. Garcia-Abia,92O. Gonzalez Lopez,92S. Goy Lopez,92J. M. Hernandez,92M. I. Josa,92 G. Merino,92J. Puerta Pelayo,92I. Redondo,92L. Romero,92J. Santaolalla,92C. Willmott,92C. Albajar,93 G. Codispoti,93J. F. de Troco´niz,93J. Cuevas,94J. Fernandez Menendez,94S. Folgueras,94I. Gonzalez Caballero,94

L. Lloret Iglesias,94J. M. Vizan Garcia,94J. A. Brochero Cifuentes,95I. J. Cabrillo,95A. Calderon,95 M. Chamizo Llatas,95S. H. Chuang,95J. Duarte Campderros,95M. Felcini,95,uM. Fernandez,95G. Gomez,95

J. Gonzalez Sanchez,95R. Gonzalez Suarez,95C. Jorda,95P. Lobelle Pardo,95A. Lopez Virto,95J. Marco,95 R. Marco,95C. Martinez Rivero,95F. Matorras,95F. J. Munoz Sanchez,95J. Piedra Gomez,95,vT. Rodrigo,95 A. Ruiz Jimeno,95L. Scodellaro,95M. Sobron Sanudo,95I. Vila,95R. Vilar Cortabitarte,95D. Abbaneo,96 E. Auffray,96G. Auzinger,96P. Baillon,96A. H. Ball,96D. Barney,96A. J. Bell,96,wD. Benedetti,96C. Bernet,96,d W. Bialas,96P. Bloch,96A. Bocci,96S. Bolognesi,96H. Breuker,96G. Brona,96K. Bunkowski,96T. Camporesi,96 E. Cano,96G. Cerminara,96T. Christiansen,96J. A. Coarasa Perez,96R. Covarelli,96B. Cure´,96D. D’Enterria,96

T. Dahms,96A. De Roeck,96F. Duarte Ramos,96A. Elliott-Peisert,96W. Funk,96A. Gaddi,96S. Gennai,96 G. Georgiou,96H. Gerwig,96D. Gigi,96K. Gill,96D. Giordano,96F. Glege,96R. Gomez-Reino Garrido,96 M. Gouzevitch,96P. Govoni,96S. Gowdy,96L. Guiducci,96M. Hansen,96J. Harvey,96J. Hegeman,96B. Hegner,96

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C. Henderson,96H. F. Hoffmann,96A. Honma,96V. Innocente,96P. Janot,96E. Karavakis,96P. Lecoq,96 C. Leonidopoulos,96C. Lourenc¸o,96A. Macpherson,96T. Ma¨ki,96L. Malgeri,96M. Mannelli,96L. Masetti,96 F. Meijers,96S. Mersi,96E. Meschi,96R. Moser,96M. U. Mozer,96M. Mulders,96E. Nesvold,96,bM. Nguyen,96 T. Orimoto,96L. Orsini,96E. Perez,96A. Petrilli,96A. Pfeiffer,96M. Pierini,96M. Pimia¨,96G. Polese,96A. Racz,96

G. Rolandi,96,xT. Rommerskirchen,96C. Rovelli,96,yM. Rovere,96H. Sakulin,96C. Scha¨fer,96C. Schwick,96 I. Segoni,96A. Sharma,96P. Siegrist,96M. Simon,96P. Sphicas,96,zD. Spiga,96M. Spiropulu,96,sF. Sto¨ckli,96

M. Stoye,96P. Tropea,96A. Tsirou,96A. Tsyganov,96G. I. Veres,96,mP. Vichoudis,96M. Voutilainen,96 W. D. Zeuner,96W. Bertl,97K. Deiters,97W. Erdmann,97K. Gabathuler,97R. Horisberger,97Q. Ingram,97 H. C. Kaestli,97S. Ko¨nig,97D. Kotlinski,97U. Langenegger,97F. Meier,97D. Renker,97T. Rohe,97J. Sibille,97,aa

A. Starodumov,97,bbP. Bortignon,98L. Caminada,98,ccZ. Chen,98S. Cittolin,98G. Dissertori,98M. Dittmar,98 J. Eugster,98K. Freudenreich,98C. Grab,98A. Herve´,98W. Hintz,98P. Lecomte,98W. Lustermann,98C. Marchica,98,cc P. Martinez Ruiz del Arbol,98P. Meridiani,98P. Milenovic,98,ddF. Moortgat,98P. Nef,98F. Nessi-Tedaldi,98L. Pape,98

F. Pauss,98T. Punz,98A. Rizzi,98F. J. Ronga,98L. Sala,98A. K. Sanchez,98M.-C. Sawley,98B. Stieger,98 L. Tauscher,98,aA. Thea,98K. Theofilatos,98D. Treille,98C. Urscheler,98R. Wallny,98,uM. Weber,98L. Wehrli,98

J. Weng,98E. Aguilo´,99C. Amsler,99V. Chiochia,99S. De Visscher,99C. Favaro,99M. Ivova Rikova,99 B. Millan Mejias,99C. Regenfus,99P. Robmann,99A. Schmidt,99H. Snoek,99L. Wilke,99Y. H. Chang,100 K. H. Chen,100W. T. Chen,100S. Dutta,100A. Go,100C. M. Kuo,100S. W. Li,100W. Lin,100M. H. Liu,100Z. K. Liu,100

Y. J. Lu,100J. H. Wu,100S. S. Yu,100P. Bartalini,101P. Chang,101Y. H. Chang,101Y. W. Chang,101Y. Chao,101 K. F. Chen,101W.-S. Hou,101Y. Hsiung,101K. Y. Kao,101Y. J. Lei,101R.-S. Lu,101J. G. Shiu,101Y. M. Tzeng,101

M. Wang,101A. Adiguzel,102M. N. Bakirci,102S. Cerci,102,eeC. Dozen,102I. Dumanoglu,102E. Eskut,102 S. Girgis,102G. Gokbulut,102Y. Guler,102E. Gurpinar,102I. Hos,102E. E. Kangal,102T. Karaman,102 A. Kayis Topaksu,102A. Nart,102G. Onengut,102K. Ozdemir,102S. Ozturk,102A. Polatoz,102K. Sogut,102,ff B. Tali,102H. Topakli,102D. Uzun,102L. N. Vergili,102M. Vergili,102C. Zorbilmez,102I. V. Akin,103T. Aliev,103 S. Bilmis,103M. Deniz,103H. Gamsizkan,103A. M. Guler,103K. Ocalan,103A. Ozpineci,103M. Serin,103R. Sever,103

U. E. Surat,103E. Yildirim,103M. Zeyrek,103M. Deliomeroglu,104D. Demir,104,ggE. Gu¨lmez,104A. Halu,104 B. Isildak,104M. Kaya,104,hhO. Kaya,104,hhM. O¨ zbek,104S. Ozkorucuklu,104,iiN. Sonmez,104,jjL. Levchuk,105 P. Bell,106F. Bostock,106J. J. Brooke,106T. L. Cheng,106E. Clement,106D. Cussans,106R. Frazier,106J. Goldstein,106

M. Grimes,106M. Hansen,106D. Hartley,106G. P. Heath,106H. F. Heath,106B. Huckvale,106J. Jackson,106 L. Kreczko,106S. Metson,106D. M. Newbold,106,kkK. Nirunpong,106A. Poll,106S. Senkin,106V. J. Smith,106

S. Ward,106L. Basso,107K. W. Bell,107A. Belyaev,107C. Brew,107R. M. Brown,107B. Camanzi,107 D. J. A. Cockerill,107J. A. Coughlan,107K. Harder,107S. Harper,107B. W. Kennedy,107E. Olaiya,107D. Petyt,107 B. C. Radburn-Smith,107C. H. Shepherd-Themistocleous,107I. R. Tomalin,107W. J. Womersley,107S. D. Worm,107

R. Bainbridge,108G. Ball,108J. Ballin,108R. Beuselinck,108O. Buchmuller,108D. Colling,108N. Cripps,108 M. Cutajar,108G. Davies,108M. Della Negra,108J. Fulcher,108D. Futyan,108A. Guneratne Bryer,108G. Hall,108

Z. Hatherell,108J. Hays,108G. Iles,108G. Karapostoli,108L. Lyons,108A.-M. Magnan,108J. Marrouche,108 R. Nandi,108J. Nash,108A. Nikitenko,108,bbA. Papageorgiou,108M. Pesaresi,108K. Petridis,108M. Pioppi,108,ll D. M. Raymond,108N. Rompotis,108A. Rose,108M. J. Ryan,108C. Seez,108P. Sharp,108A. Sparrow,108A. Tapper,108 S. Tourneur,108M. Vazquez Acosta,108T. Virdee,108S. Wakefield,108D. Wardrope,108T. Whyntie,108M. Barrett,109 M. Chadwick,109J. E. Cole,109P. R. Hobson,109A. Khan,109P. Kyberd,109D. Leslie,109W. Martin,109I. D. Reid,109 L. Teodorescu,109K. Hatakeyama,110T. Bose,111E. Carrera Jarrin,111A. Clough,111C. Fantasia,111A. Heister,111 J. St. John,111P. Lawson,111D. Lazic,111J. Rohlf,111D. Sperka,111L. Sulak,111A. Avetisyan,112S. Bhattacharya,112 J. P. Chou,112D. Cutts,112S. Esen,112A. Ferapontov,112U. Heintz,112S. Jabeen,112G. Kukartsev,112G. Landsberg,112

M. Narain,112D. Nguyen,112M. Segala,112T. Speer,112K. V. Tsang,112M. A. Borgia,113R. Breedon,113 M. Calderon De La Barca Sanchez,113D. Cebra,113S. Chauhan,113M. Chertok,113J. Conway,113P. T. Cox,113

J. Dolen,113R. Erbacher,113E. Friis,113W. Ko,113A. Kopecky,113R. Lander,113H. Liu,113S. Maruyama,113 T. Miceli,113M. Nikolic,113D. Pellett,113J. Robles,113T. Schwarz,113M. Searle,113J. Smith,113M. Squires,113

M. Tripathi,113R. Vasquez Sierra,113C. Veelken,113V. Andreev,114K. Arisaka,114D. Cline,114R. Cousins,114 A. Deisher,114J. Duris,114S. Erhan,114,bC. Farrell,114J. Hauser,114M. Ignatenko,114C. Jarvis,114C. Plager,114

G. Rakness,114P. Schlein,114,aJ. Tucker,114V. Valuev,114J. Babb,115R. Clare,115J. Ellison,115J. W. Gary,115 F. Giordano,115G. Hanson,115G. Y. Jeng,115S. C. Kao,115F. Liu,115H. Liu,115A. Luthra,115H. Nguyen,115 G. Pasztor,115,mmA. Satpathy,115B. C. Shen,115,aR. Stringer,115J. Sturdy,115S. Sumowidagdo,115R. Wilken,115

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S. Wimpenny,115W. Andrews,116J. G. Branson,116E. Dusinberre,116D. Evans,116F. Golf,116A. Holzner,116 R. Kelley,116M. Lebourgeois,116J. Letts,116B. Mangano,116J. Muelmenstaedt,116S. Padhi,116C. Palmer,116 G. Petrucciani,116H. Pi,116M. Pieri,116R. Ranieri,116M. Sani,116V. Sharma,116,bS. Simon,116Y. Tu,116A. Vartak,116

F. Wu¨rthwein,116A. Yagil,116D. Barge,117R. Bellan,117C. Campagnari,117M. D’Alfonso,117T. Danielson,117 P. Geffert,117J. Incandela,117C. Justus,117P. Kalavase,117S. A. Koay,117D. Kovalskyi,117V. Krutelyov,117 S. Lowette,117N. Mccoll,117V. Pavlunin,117F. Rebassoo,117J. Ribnik,117J. Richman,117R. Rossin,117D. Stuart,117

W. To,117J. R. Vlimant,117A. Bornheim,118J. Bunn,118Y. Chen,118M. Gataullin,118D. Kcira,118V. Litvine,118 Y. Ma,118A. Mott,118H. B. Newman,118C. Rogan,118V. Timciuc,118P. Traczyk,118J. Veverka,118R. Wilkinson,118

Y. Yang,118R. Y. Zhu,118B. Akgun,119R. Carroll,119T. Ferguson,119Y. Iiyama,119D. W. Jang,119S. Y. Jun,119 Y. F. Liu,119M. Paulini,119J. Russ,119N. Terentyev,119H. Vogel,119I. Vorobiev,119J. P. Cumalat,120M. E. Dinardo,120 B. R. Drell,120C. J. Edelmaier,120W. T. Ford,120B. Heyburn,120E. Luiggi Lopez,120U. Nauenberg,120J. G. Smith,120 K. Stenson,120K. A. Ulmer,120S. R. Wagner,120S. L. Zang,120L. Agostino,121J. Alexander,121A. Chatterjee,121 S. Das,121N. Eggert,121L. J. Fields,121L. K. Gibbons,121B. Heltsley,121W. Hopkins,121A. Khukhunaishvili,121 B. Kreis,121V. Kuznetsov,121G. Nicolas Kaufman,121J. R. Patterson,121D. Puigh,121D. Riley,121A. Ryd,121 X. Shi,121W. Sun,121W. D. Teo,121J. Thom,121J. Thompson,121J. Vaughan,121Y. Weng,121L. Winstrom,121 P. Wittich,121A. Biselli,122G. Cirino,122D. Winn,122S. Abdullin,123M. Albrow,123J. Anderson,123G. Apollinari,123

M. Atac,123J. A. Bakken,123S. Banerjee,123L. A. T. Bauerdick,123A. Beretvas,123J. Berryhill,123P. C. Bhat,123 I. Bloch,123F. Borcherding,123K. Burkett,123J. N. Butler,123V. Chetluru,123H. W. K. Cheung,123F. Chlebana,123

S. Cihangir,123M. Demarteau,123D. P. Eartly,123V. D. Elvira,123I. Fisk,123J. Freeman,123Y. Gao,123 E. Gottschalk,123D. Green,123K. Gunthoti,123O. Gutsche,123A. Hahn,123J. Hanlon,123R. M. Harris,123 J. Hirschauer,123B. Hooberman,123E. James,123H. Jensen,123M. Johnson,123U. Joshi,123R. Khatiwada,123 B. Kilminster,123B. Klima,123K. Kousouris,123S. Kunori,123S. Kwan,123P. Limon,123R. Lipton,123J. Lykken,123

K. Maeshima,123J. M. Marraffino,123D. Mason,123P. McBride,123T. McCauley,123T. Miao,123K. Mishra,123 S. Mrenna,123Y. Musienko,123,nnC. Newman-Holmes,123V. O’Dell,123S. Popescu,123,ooR. Pordes,123 O. Prokofyev,123N. Saoulidou,123E. Sexton-Kennedy,123S. Sharma,123A. Soha,123W. J. Spalding,123L. Spiegel,123 P. Tan,123L. Taylor,123S. Tkaczyk,123L. Uplegger,123E. W. Vaandering,123R. Vidal,123J. Whitmore,123W. Wu,123

F. Yang,123F. Yumiceva,123J. C. Yun,123D. Acosta,124P. Avery,124D. Bourilkov,124M. Chen,124 G. P. Di Giovanni,124D. Dobur,124A. Drozdetskiy,124R. D. Field,124M. Fisher,124Y. Fu,124I. K. Furic,124 J. Gartner,124S. Goldberg,124B. Kim,124S. Klimenko,124J. Konigsberg,124A. Korytov,124A. Kropivnitskaya,124 T. Kypreos,124K. Matchev,124G. Mitselmakher,124L. Muniz,124Y. Pakhotin,124C. Prescott,124R. Remington,124 M. Schmitt,124B. Scurlock,124P. Sellers,124N. Skhirtladze,124D. Wang,124J. Yelton,124M. Zakaria,124C. Ceron,125

V. Gaultney,125L. Kramer,125L. M. Lebolo,125S. Linn,125P. Markowitz,125G. Martinez,125J. L. Rodriguez,125 T. Adams,126A. Askew,126D. Bandurin,126J. Bochenek,126J. Chen,126B. Diamond,126S. V. Gleyzer,126J. Haas,126 S. Hagopian,126V. Hagopian,126M. Jenkins,126K. F. Johnson,126H. Prosper,126S. Sekmen,126V. Veeraraghavan,126

M. M. Baarmand,127B. Dorney,127S. Guragain,127M. Hohlmann,127H. Kalakhety,127R. Ralich,127 I. Vodopiyanov,127M. R. Adams,128I. M. Anghel,128L. Apanasevich,128Y. Bai,128V. E. Bazterra,128R. R. Betts,128

J. Callner,128R. Cavanaugh,128C. Dragoiu,128E. J. Garcia-Solis,128C. E. Gerber,128D. J. Hofman,128 S. Khalatyan,128F. Lacroix,128C. O’Brien,128C. Silvestre,128A. Smoron,128D. Strom,128N. Varelas,128 U. Akgun,129E. A. Albayrak,129B. Bilki,129K. Cankocak,129,ppW. Clarida,129F. Duru,129C. K. Lae,129 E. McCliment,129J.-P. Merlo,129H. Mermerkaya,129A. Mestvirishvili,129A. Moeller,129J. Nachtman,129 C. R. Newsom,129E. Norbeck,129J. Olson,129Y. Onel,129F. Ozok,129S. Sen,129J. Wetzel,129T. Yetkin,129K. Yi,129

B. A. Barnett,130B. Blumenfeld,130A. Bonato,130C. Eskew,130D. Fehling,130G. Giurgiu,130A. V. Gritsan,130 Z. J. Guo,130G. Hu,130P. Maksimovic,130S. Rappoccio,130M. Swartz,130N. V. Tran,130A. Whitbeck,130 P. Baringer,131A. Bean,131G. Benelli,131O. Grachov,131M. Murray,131D. Noonan,131V. Radicci,131S. Sanders,131

J. S. Wood,131V. Zhukova,131T. Bolton,132I. Chakaberia,132A. Ivanov,132M. Makouski,132Y. Maravin,132 S. Shrestha,132I. Svintradze,132Z. Wan,132J. Gronberg,133D. Lange,133D. Wright,133A. Baden,134 M. Boutemeur,134S. C. Eno,134D. Ferencek,134J. A. Gomez,134N. J. Hadley,134R. G. Kellogg,134M. Kirn,134

Y. Lu,134A. C. Mignerey,134K. Rossato,134P. Rumerio,134F. Santanastasio,134A. Skuja,134J. Temple,134 M. B. Tonjes,134S. C. Tonwar,134E. Twedt,134B. Alver,135G. Bauer,135J. Bendavid,135W. Busza,135E. Butz,135

I. A. Cali,135M. Chan,135V. Dutta,135P. Everaerts,135G. Gomez Ceballos,135M. Goncharov,135K. A. Hahn,135 P. Harris,135Y. Kim,135M. Klute,135Y.-J. Lee,135W. Li,135C. Loizides,135P. D. Luckey,135T. Ma,135S. Nahn,135

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C. Paus,135C. Roland,135G. Roland,135M. Rudolph,135G. S. F. Stephans,135K. Sumorok,135K. Sung,135 E. A. Wenger,135S. Xie,135M. Yang,135Y. Yilmaz,135A. S. Yoon,135M. Zanetti,135P. Cole,136S. I. Cooper,136 P. Cushman,136B. Dahmes,136A. De Benedetti,136P. R. Dudero,136G. Franzoni,136J. Haupt,136K. Klapoetke,136

Y. Kubota,136J. Mans,136V. Rekovic,136R. Rusack,136M. Sasseville,136A. Singovsky,136L. M. Cremaldi,137 R. Godang,137R. Kroeger,137L. Perera,137R. Rahmat,137D. A. Sanders,137D. Summers,137K. Bloom,138S. Bose,138 J. Butt,138D. R. Claes,138A. Dominguez,138M. Eads,138J. Keller,138T. Kelly,138I. Kravchenko,138J. Lazo-Flores,138

C. Lundstedt,138H. Malbouisson,138S. Malik,138G. R. Snow,138U. Baur,139A. Godshalk,139I. Iashvili,139 A. Kharchilava,139A. Kumar,139S. P. Shipkowski,139K. Smith,139G. Alverson,140E. Barberis,140D. Baumgartel,140 O. Boeriu,140M. Chasco,140K. Kaadze,140S. Reucroft,140J. Swain,140D. Wood,140J. Zhang,140A. Anastassov,141 A. Kubik,141N. Odell,141R. A. Ofierzynski,141B. Pollack,141A. Pozdnyakov,141M. Schmitt,141S. Stoynev,141 M. Velasco,141S. Won,141L. Antonelli,142D. Berry,142M. Hildreth,142C. Jessop,142D. J. Karmgard,142J. Kolb,142 T. Kolberg,142K. Lannon,142W. Luo,142S. Lynch,142N. Marinelli,142D. M. Morse,142T. Pearson,142R. Ruchti,142 J. Slaunwhite,142N. Valls,142J. Warchol,142M. Wayne,142J. Ziegler,142B. Bylsma,143L. S. Durkin,143J. Gu,143 C. Hill,143P. Killewald,143K. Kotov,143T. Y. Ling,143M. Rodenburg,143G. Williams,143N. Adam,144E. Berry,144

P. Elmer,144D. Gerbaudo,144V. Halyo,144P. Hebda,144A. Hunt,144J. Jones,144E. Laird,144D. Lopes Pegna,144 D. Marlow,144T. Medvedeva,144M. Mooney,144J. Olsen,144P. Piroue´,144X. Quan,144H. Saka,144D. Stickland,144

C. Tully,144J. S. Werner,144A. Zuranski,144J. G. Acosta,145X. T. Huang,145A. Lopez,145H. Mendez,145 S. Oliveros,145J. E. Ramirez Vargas,145A. Zatserklyaniy,145E. Alagoz,146V. E. Barnes,146G. Bolla,146 L. Borrello,146D. Bortoletto,146A. Everett,146A. F. Garfinkel,146Z. Gecse,146L. Gutay,146Z. Hu,146M. Jones,146

O. Koybasi,146A. T. Laasanen,146N. Leonardo,146C. Liu,146V. Maroussov,146P. Merkel,146D. H. Miller,146 N. Neumeister,146K. Potamianos,146I. Shipsey,146D. Silvers,146A. Svyatkovskiy,146H. D. Yoo,146J. Zablocki,146

Y. Zheng,146P. Jindal,147N. Parashar,147C. Boulahouache,148V. Cuplov,148K. M. Ecklund,148F. J. M. Geurts,148 J. H. Liu,148J. Morales,148B. P. Padley,148R. Redjimi,148J. Roberts,148J. Zabel,148B. Betchart,149A. Bodek,149 Y. S. Chung,149P. de Barbaro,149R. Demina,149Y. Eshaq,149H. Flacher,149A. Garcia-Bellido,149P. Goldenzweig,149 Y. Gotra,149J. Han,149A. Harel,149D. C. Miner,149D. Orbaker,149G. Petrillo,149D. Vishnevskiy,149M. Zielinski,149

A. Bhatti,150L. Demortier,150K. Goulianos,150G. Lungu,150C. Mesropian,150M. Yan,150O. Atramentov,151 A. Barker,151D. Duggan,151Y. Gershtein,151R. Gray,151E. Halkiadakis,151D. Hidas,151D. Hits,151A. Lath,151 S. Panwalkar,151R. Patel,151A. Richards,151K. Rose,151S. Schnetzer,151S. Somalwar,151R. Stone,151S. Thomas,151

G. Cerizza,152M. Hollingsworth,152S. Spanier,152Z. C. Yang,152A. York,152J. Asaadi,153R. Eusebi,153 J. Gilmore,153A. Gurrola,153T. Kamon,153V. Khotilovich,153R. Montalvo,153C. N. Nguyen,153J. Pivarski,153 A. Safonov,153S. Sengupta,153A. Tatarinov,153D. Toback,153M. Weinberger,153N. Akchurin,154C. Bardak,154 J. Damgov,154C. Jeong,154K. Kovitanggoon,154S. W. Lee,154P. Mane,154Y. Roh,154A. Sill,154I. Volobouev,154 R. Wigmans,154E. Yazgan,154E. Appelt,155E. Brownson,155D. Engh,155C. Florez,155W. Gabella,155W. Johns,155 P. Kurt,155C. Maguire,155A. Melo,155P. Sheldon,155J. Velkovska,155M. W. Arenton,156M. Balazs,156S. Boutle,156

M. Buehler,156S. Conetti,156B. Cox,156B. Francis,156R. Hirosky,156A. Ledovskoy,156C. Lin,156C. Neu,156 R. Yohay,156S. Gollapinni,157R. Harr,157P. E. Karchin,157M. Mattson,157C. Milste`ne,157A. Sakharov,157

M. Anderson,158M. Bachtis,158J. N. Bellinger,158D. Carlsmith,158S. Dasu,158J. Efron,158L. Gray,158 K. S. Grogg,158M. Grothe,158R. Hall-Wilton,158,bM. Herndon,158P. Klabbers,158J. Klukas,158A. Lanaro,158

C. Lazaridis,158J. Leonard,158D. Lomidze,158R. Loveless,158A. Mohapatra,158W. Parker,158D. Reeder,158 I. Ross,158A. Savin,158W. H. Smith,158J. Swanson,158and M. Weinberg158

(CMS Collaboration)

1_{Yerevan Physics Institute, Yerevan, Armenia} 2_{Institut fu¨r Hochenergiephysik der OeAW, Wien, Austria} 3_{National Centre for Particle and High Energy Physics, Minsk, Belarus}

4_{Universiteit Antwerpen, Antwerpen, Belgium} 5

Vrije Universiteit Brussel, Brussel, Belgium

6_{Universite´ Libre de Bruxelles, Bruxelles, Belgium} 7_{Ghent University, Ghent, Belgium}

8_{Universite´ Catholique de Louvain, Louvain-la-Neuve, Belgium} 9_{Universite´ de Mons, Mons, Belgium}

10_{Centro Brasileiro de Pesquisas Fisicas, Rio de Janeiro, Brazil}

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11_{Universidade do Estado do Rio de Janeiro, Rio de Janeiro, Brazil} 12_{Instituto de Fisica Teorica, Universidade Estadual Paulista, Sao Paulo, Brazil}

13_{Institute for Nuclear Research and Nuclear Energy, Sofia, Bulgaria} 14_{University of Sofia, Sofia, Bulgaria}

15_{Institute of High Energy Physics, Beijing, China}

16_{State Key Lab. of Nucl. Phys. and Tech., Peking University, Beijing, China} 17_{Universidad de Los Andes, Bogota, Colombia}

18_{Technical University of Split, Split, Croatia} 19

University of Split, Split, Croatia

20_{Institute Rudjer Boskovic, Zagreb, Croatia} 21_{University of Cyprus, Nicosia, Cyprus}

22_{Academy of Scientific Research and Technology of the Arab Republic of Egypt, Egyptian Network of High Energy Physics,}

Cairo, Egypt

23_{National Institute of Chemical Physics and Biophysics, Tallinn, Estonia} 24_{Department of Physics, University of Helsinki, Helsinki, Finland}

25_{Helsinki Institute of Physics, Helsinki, Finland} 26_{Lappeenranta University of Technology, Lappeenranta, Finland}

27_{Laboratoire d’Annecy-le-Vieux de Physique des Particules, IN2P3-CNRS, Annecy-le-Vieux, France} 28_{DSM/IRFU, CEA/Saclay, Gif-sur-Yvette, France}

29_{Laboratoire Leprince-Ringuet, Ecole Polytechnique, IN2P3-CNRS, Palaiseau, France}

30_{Institut Pluridisciplinaire Hubert Curien, Universite´ de Strasbourg, Universite´ de Haute Alsace Mulhouse, CNRS/IN2P3,}

Strasbourg, France

31_{Centre de Calcul de l’Institut National de Physique Nucleaire et de Physique des Particules (IN2P3), Villeurbanne, France} 32_{Universite´ de Lyon, Universite´ Claude Bernard Lyon 1, CNRS-IN2P3, Institut de Physique Nucle´aire de Lyon, Villeurbanne, France}

33

E. Andronikashvili Institute of Physics, Academy of Science, Tbilisi, Georgia

34_{RWTH Aachen University, I. Physikalisches Institut, Aachen, Germany} 35_{RWTH Aachen University, III. Physikalisches Institut A, Aachen, Germany} 36_{RWTH Aachen University, III. Physikalisches Institut B, Aachen, Germany}

37_{Deutsches Elektronen-Synchrotron, Hamburg, Germany} 38_{University of Hamburg, Hamburg, Germany} 39_{Institut fu¨r Experimentelle Kernphysik, Karlsruhe, Germany} 40_{Institute of Nuclear Physics "Demokritos", Aghia Paraskevi, Greece}

41_{University of Athens, Athens, Greece} 42_{University of Ioa´nnina, Ioa´nnina, Greece}

43_{KFKI Research Institute for Particle and Nuclear Physics, Budapest, Hungary} 44_{Institute of Nuclear Research ATOMKI, Debrecen, Hungary}

45_{University of Debrecen, Debrecen, Hungary} 46_{Panjab University, Chandigarh, India}

47_{University of Delhi, Delhi, India} 48_{Bhabha Atomic Research Centre, Mumbai, India} 49_{Tata Institute of Fundamental Research - EHEP, Mumbai, India} 50_{Tata Institute of Fundamental Research - HECR, Mumbai, India} 51_{Institute for Studies in Theoretical Physics & Mathematics (IPM), Tehran, Iran}

52a_{INFN Sezione di Bari, Bari, Italy} 52b_{Universita` di Bari, Bari, Italy} 52c_{Politecnico di Bari, Bari, Italy} 53a_{INFN Sezione di Bologna, Bologna, Italy}

53b

Universita` di Bologna, Bologna, Italy

54a_{INFN Sezione di Catania, Catania, Italy} 54b_{Universita` di Catania, Catania, Italy} 55a_{INFN Sezione di Firenze, Firenze, Italy}

55b_{Universita` di Firenze, Firenze, Italy}

56_{INFN Laboratori Nazionali di Frascati, Frascati, Italy} 57_{INFN Sezione di Genova, Genova, Italy} 58a_{INFN Sezione di Milano-Biccoca, Milano, Italy}

58b_{Universita` di Milano-Bicocca, Milano, Italy} 59a

INFN Sezione di Napoli, Napoli, Italy

59b_{Universita` di Napoli "Federico II", Napoli, Italy} 60a_{INFN Sezione di Padova, Padova, Italy}

60b_{Universita` di Padova, Padova, Italy} 60c_{Universita` di Trento (Trento), Padova, Italy}

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61a_{INFN Sezione di Pavia, Pavia, Italy} 61b_{Universita` di Pavia, Pavia, Italy} 62a_{INFN Sezione di Perugia, Perugia, Italy}

62b_{Universita` di Perugia, Perugia, Italy} 63a_{INFN Sezione di Pisa, Pisa, Italy}

63b_{Universita` di Pisa, Pisa, Italy} 63c_{Scuola Normale Superiore di Pisa, Pisa, Italy}

64a_{INFN Sezione di Roma, Roma, Italy} 64b

Universita` di Roma "La Sapienza", Roma, Italy

65a_{INFN Sezione di Torino, Torino, Italy} 65b_{Universita` di Torino, Torino, Italy}

65c_{Universita` del Piemonte Orientale (Novara), Torino, Italy} 66a_{INFN Sezione di Trieste, Trieste, Italy}

66b_{Universita` di Trieste, Trieste, Italy} 67_{Kangwon National University, Chunchon, Korea}

68_{Kyungpook National University, Daegu, Korea}

69_{Chonnam National University, Institute for Universe and Elementary Particles, Kwangju, Korea} 70_{Korea University, Seoul, Korea}

71_{University of Seoul, Seoul, Korea} 72_{Sungkyunkwan University, Suwon, Korea}

73_{Vilnius University, Vilnius, Lithuania}

74_{Centro de Investigacion y de Estudios Avanzados del IPN, Mexico City, Mexico} 75_{Universidad Iberoamericana, Mexico City, Mexico}

76_{Benemerita Universidad Autonoma de Puebla, Puebla, Mexico} 77

Universidad Auto´noma de San Luis Potosı´, San Luis Potosı´, Mexico

78_{University of Auckland, Auckland, New Zealand} 79_{University of Canterbury, Christchurch, New Zealand}

80_{National Centre for Physics, Quaid-I-Azam University, Islamabad, Pakistan} 81_{Institute of Experimental Physics, Faculty of Physics, University of Warsaw, Warsaw, Poland}

82_{Soltan Institute for Nuclear Studies, Warsaw, Poland}

83_{Laborato´rio de Instrumentaçaõ e Fı´sica Experimental de Partıćulas, Lisboa, Portugal} 84_{Joint Institute for Nuclear Research, Dubna, Russia}

85_{Petersburg Nuclear Physics Institute, Gatchina (St Petersburg), Russia} 86_{Institute for Nuclear Research, Moscow, Russia}

87_{Institute for Theoretical and Experimental Physics, Moscow, Russia} 88_{Moscow State University, Moscow, Russia}

89_{P.N. Lebedev Physical Institute, Moscow, Russia}

90_{State Research Center of Russian Federation, Institute for High Energy Physics, Protvino, Russia} 91_{University of Belgrade, Faculty of Physics and Vinca Institute of Nuclear Sciences, Belgrade, Serbia}

92_{Centro de Investigaciones Energe´ticas Medioambientales y Tecnolo´gicas (CIEMAT), Madrid, Spain} 93_{Universidad Auto´noma de Madrid, Madrid, Spain}

94_{Universidad de Oviedo, Oviedo, Spain}

95_{Instituto de Fı´sica de Cantabria (IFCA), CSIC-Universidad de Cantabria, Santander, Spain} 96_{CERN, European Organization for Nuclear Research, Geneva, Switzerland}

97_{Paul Scherrer Institut, Villigen, Switzerland}

98_{Institute for Particle Physics, ETH Zurich, Zurich, Switzerland} 99_{Universita¨t Zu¨rich, Zurich, Switzerland}

100

National Central University, Chung-Li, Taiwan

101_{National Taiwan University (NTU), Taipei, Taiwan} 102_{Cukurova University, Adana, Turkey}

103_{Middle East Technical University, Physics Department, Ankara, Turkey} 104_{Bogazici University, Istanbul, Turkey}

105_{National Scientific Center, Kharkov Institute of Physics and Technology, Kharkov, Ukraine} 106_{University of Bristol, Bristol, United Kingdom}

107_{Rutherford Appleton Laboratory, Didcot, United Kingdom} 108_{Imperial College, London, United Kingdom} 109

Brunel University, Uxbridge, United Kingdom

110_{Baylor University, Waco, Texas 76706, USA} 111_{Boston University, Boston, Massachusetts 02215, USA} 112_{Brown University, Providence, Rhode Island 02912, USA} 113_{University of California, Davis, Davis, California 95616, USA}

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114_{University of California, Los Angeles, Los Angeles, California 90095, USA} 115_{University of California, Riverside, Riverside, California 92521, USA} 116_{University of California, San Diego, La Jolla, California 92093, USA} 117_{University of California, Santa Barbara, Santa Barbara, California 93106, USA}

118_{California Institute of Technology, Pasadena, California 91125, USA} 119_{Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, USA} 120_{University of Colorado at Boulder, Boulder, Colorado 80309, USA}

121_{Cornell University, Ithaca, New York 14853-5001, USA} 122

Fairfield University, Fairfield, Connecticut 06824, USA

123_{Fermi National Accelerator Laboratory, Batavia, Illinois 60510-0500, USA} 124_{University of Florida, Gainesville, Florida 32611-8440, USA} 125_{Florida International University, Miami, Florida 33199, USA} 126_{Florida State University, Tallahassee, Florida 32306-4350, USA} 127_{Florida Institute of Technology, Melbourne, Florida 32901, USA} 128_{University of Illinois at Chicago (UIC), Chicago, Illinois 60607-7059, USA}

129_{The University of Iowa, Iowa City, Iowa 52242-1479, USA} 130_{Johns Hopkins University, Baltimore, Maryland 21218, USA}

131_{The University of Kansas, Lawrence, Kansas 66045, USA} 132_{Kansas State University, Manhattan, Kansas 66506, USA}

133_{Lawrence Livermore National Laboratory, Livermore, California 94720, USA} 134_{University of Maryland, College Park, Maryland 20742, USA} 135_{Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA}

136_{University of Minnesota, Minneapolis, Minnesota 55455, USA} 137_{University of Mississippi, University, Mississippi 38677, USA} 138

University of Nebraska-Lincoln, Lincoln, Nebraska 68588-0111, USA

139_{State University of New York at Buffalo, Buffalo, New York 14260-1500, USA} 140_{Northeastern University, Boston, Massachusetts 02115, USA} 141_{Northwestern University, Evanston, Illinois 60208-3112, USA}

142_{University of Notre Dame, Notre Dame, Indiana 46556, USA} 143_{The Ohio State University, Columbus, Ohio 43210, USA} 144_{Princeton University, Princeton, New Jersey 08544-0708, USA}

145_{University of Puerto Rico, Mayaguez, Puerto Rico 00680} 146_{Purdue University, West Lafayette, Indiana 47907-1396, USA}

147_{Purdue University Calumet, Hammond, Indiana 46323, USA} 148_{Rice University, Houston, Texas 77251-1892, USA} 149_{University of Rochester, Rochester, New York 14627-0171, USA}

150_{The Rockefeller University, New York, New York, USA}

151_{Rutgers, the State University of New Jersey, Piscataway, New York 10021-6399, USA} 152_{University of Tennessee, Knoxville, Tennessee 37996-1200, USA}

153_{Texas A&M University, College Station, Texas 77843-4242, USA} 154_{Texas Tech University, Lubbock, Texas 79409-1051, USA}

155_{Vanderbilt University, Nashville, Tennessee 37235, USA} 156_{University of Virginia, Charlottesville, Virginia 22901, USA}

157_{Wayne State University, Detroit, Michigan 48202, USA} 158_{University of Wisconsin, Madison, Wisconsin 53706, USA}

a_Deceased.

b_{Also at CERN, European Organization for Nuclear Research, Geneva, Switzerland.} c_{Also at Universidade Federal do ABC, Santo Andre, Brazil.}

d_{Also at Laboratoire Leprince-Ringuet, Ecole Polytechnique, IN2P3-CNRS, Palaiseau, France.} e_{Also at Suez Canal University, Suez, Egypt.}

f_{Also at Fayoum University, El-Fayoum, Egypt.}

g_{Also at Soltan Institute for Nuclear Studies, Warsaw, Poland.}

h_{Also at Massachusetts Institute of Technology, Cambridge, MA, USA.} i_{Also at Universite´ de Haute-Alsace, Mulhouse, France.}

j

Also at Brandenburg University of Technology, Cottbus, Germany.

k_{Also at Moscow State University, Moscow, Russia.}

l_{Also at Institute of Nuclear Research ATOMKI, Debrecen, Hungary.} m_{Also at Eo¨tvo¨s Lora´nd University, Budapest, Hungary.}

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n_{Also at Tata Institute of Fundamental Research—HECR, Mumbai, India.} o_{Also at University of Visva-Bharati, Santiniketan, India.}

p_{Also at Facolta` Ingegneria Universita` di Roma ’’La Sapienza’’, Roma, Italy.} q_{Also at Universita` della Basilicata, Potenza, Italy.}

r_{Also at Laboratori Nazionali di Legnaro dell’ INFN, Legnaro, Italy.} s_{Also at California Institute of Technology, Pasadena, CA, USA.} t_{Also at Faculty of Physics of University of Belgrade, Belgrade, Serbia.} u_{Also at University of California, Los Angeles, Los Angeles, CA, USA.} v_{Also at University of Florida, Gainesville, FL, USA.}

w_{Also at Universite´ de Gene`ve, Geneva, Switzerland.} x_{Also at Scuola Normale e Sezione dell’ INFN, Pisa, Italy.}

y_{Also at INFN Sezione di Roma; Universita` di Roma ‘‘La Sapienza’’, Roma, Italy.} z_{Also at University of Athens, Athens, Greece.}

aa_{Also at The University of Kansas, Lawrence, KS, USA.} bb

Also at Institute for Theoretical and Experimental Physics, Moscow, Russia.

cc_{Also at Paul Scherrer Institut, Villigen, Switzerland.}

dd_{Also at University of Belgrade, Faculty of Physics and Vinca Institute of Nuclear Sciences, Belgrade, Serbia.} ee_{Also at Adiyaman University, Adiyaman, Turkey.}

ff_{Also at Mersin University, Mersin, Turkey.}

gg_{Also at Izmir Institute of Technology, Izmir, Turkey.} hh_{Also at Kafkas University, Kars, Turkey.}

ii_{Also at Suleyman Demirel University, Isparta, Turkey.} jj_{Also at Ege University, Izmir, Turkey.}

kk_{Also at Rutherford Appleton Laboratory, Didcot, United Kingdom.} ll_{Also at INFN Sezione di Perugia; Universita` di Perugia, Perugia, Italy.}

mm_{Also at KFKI Research Institute for Particle and Nuclear Physics, Budapest, Hungary.} nn_{Also at Institute for Nuclear Research, Moscow, Russia.}

oo_{Also at Horia Hulubei National Institute of Physics and Nuclear Engineering (IFIN-HH), Bucharest, Romania.} pp_{Also at Istanbul Technical University, Istanbul, Turkey.}