Measurement of the [subscript b](3P) mass and of the relative rate of [subscript b1](1P) and [subscript b2](1P) production The MIT Faculty has made this article openly available. Please share how this access benefits you. Your story matters. Citation Aaij, R., B. Adeva, M. Adinolfi, A. Affolder, Z. Ajaltouni, S. Akar, J. Albrecht, et al. “Measurement of the [subscript b](3P) Mass and of the Relative Rate of [subscript b1](1P) and [subscript b2](1P) Production.” J. High Energ. Phys. 2014, no. 10 (October 2014). As Published http://dx.doi.org/10.1007/jhep10(2014)088 Publisher Springer-Verlag Version Final published version Accessed Thu May 26 00:33:28 EDT 2016 Citable Link http://hdl.handle.net/1721.1/92541 Terms of Use Creative Commons Attribution Detailed Terms http://creativecommons.org/licenses/by/4.0/ Published for SISSA by Springer Received: September 5, 2014 Accepted: October 1, 2014 Published: October 14, 2014 The LHCb collaboration E-mail: tournefier@lapp.in2p3.fr Abstract: The production of χb mesons in proton-proton collisions is studied using a data √ sample collected by the LHCb detector, at centre-of-mass energies of s = 7 and 8 TeV and corresponding to an integrated luminosity of 3.0 fb−1 . The χb mesons are identified through their decays to Υ(1S)γ and Υ(2S)γ using photons that converted to e+ e− pairs in the detector. The relative prompt production rate of χb1 (1P ) and χb2 (1P ) mesons is measured as a function of the Υ(1S) transverse momentum in the χb rapidity range 2.0 < y < 4.5. A precise measurement of the χb (3P ) mass is also performed. Assuming a mass splitting between the χb1 (3P ) and the χb2 (3P ) states of 10.5 MeV/c2 , the measured mass of the χb1 (3P ) meson is +1.5 2 m(χb1 (3P )) = 10515.7+2.2 −3.9 (stat)−2.1 (syst) MeV/c . Keywords: Quarkonium, Hadron-Hadron Scattering, Flavor physics ArXiv ePrint: 1409.1408 Open Access, Copyright CERN, for the benefit of the LHCb Collaboration. Article funded by SCOAP3 . doi:10.1007/JHEP10(2014)088 JHEP10(2014)088 Measurement of the χb(3P ) mass and of the relative rate of χb1(1P ) and χb2(1P ) production Contents 1 2 Detector and data samples 2 3 Event reconstruction and selection 3 4 Sample composition and fit model 4 5 χb meson masses 5.1 Mass measurements 5.2 Systematic uncertainties 6 6 7 6 Relative rate of χb2 (1P ) and χb1 (1P ) production 6.1 Measurement of the relative rates 6.2 Systematic uncertainties 9 9 10 7 Results 12 8 Conclusion 13 The LHCb collaboration 17 1 Introduction The study of production and properties of heavy quark-antiquark bound states (quarkonia) provides an important test of the underlying mechanisms described by quantum chromodynamics (QCD). The quarkonium (cc and bb) states in which quarks have parallel spins include the S-wave (J/ψ , Υ ) and the P -wave (χc , χb ) states, where each of the latter comprises a closely spaced triplet of J = 0, 1, 2 spin states (χcJ , χbJ ). In high-energy protonproton collisions at the LHC, qq pairs (q = c, b) are expected to be produced predominantly via a hard gluon-gluon interaction followed by the formation of bound quarkonium states. The production of the qq pair is described by perturbative QCD, while non-perturbative QCD is needed for the description of the evolution of the qq pair to the bound state. Several models have been developed for this non-perturbative part such as the colour singlet model [1–3] and the non-relativistic QCD (NRQCD) model [4, 5], which also includes the production of quarkonium via the colour octet mechanism. Recent studies support the leading role of the colour singlet mechanism [6, 7]. Measurements of the relative rate of J = 1 and J = 2 states provide information on the colour octet contribution. This relative rate is also predicted to have the same dependence on the meson transverse momentum (pT ) in χb and χc states, once the pT of the χb meson is scaled by the ratio of χc and χb masses [8]. –1– JHEP10(2014)088 1 Introduction 2 Detector and data samples The LHCb detector [20] is a single-arm forward spectrometer covering the pseudorapidity range 2 < η < 5, designed for the study of particles containing b or c quarks. The detector includes a high-precision tracking system consisting of a silicon-strip vertex detector (VELO) surrounding the pp interaction region, a large-area silicon-strip detector station located upstream of a dipole magnet with a bending power of about 4 Tm, and three stations of silicon-strip detectors and straw drift tubes placed downstream of the magnet. The tracking system provides a measurement of momentum, p, with a relative uncertainty that varies from 0.4% at low momentum to 0.6% at 100 GeV/c. The total material before the first tracking station corresponds to about 25% of a radiation length. The minimum distance of a track to a primary vertex, the impact parameter, is measured with a resolution of (15 + 29/pT ) µm, where pT is in GeV/c. Different types of charged hadrons are distinguished using information from two ring-imaging Cherenkov detectors. Photon, electron and hadron candidates are identified by a calorimeter system consisting of scintillating-pad and preshower detectors, an electromagnetic calorimeter (ECAL) and a hadronic calorimeter. The reconstruction of converted photons is described in section 3. Muons are identified by a system composed of alternating layers of iron and multiwire proportional chambers. The LHCb coordinate system is right-handed with its origin at the nominal interaction point, the z axis aligned along the beam line towards the magnet and the y axis pointing upwards. The magnetic field is oriented along the y axis. –2– JHEP10(2014)088 Measurements of χc production and the ratio of the χc1 and χc2 production crosssections have been made previously using various particle beams and energies [9–13]. All the χb states are below the BB threshold (where B stands for b mesons) and therefore can be studied through their radiative decays to the Υ mesons, in the same way as the χc states were studied through their radiative decays to the J/ψ meson [13]. In this paper we report a measurement of the ratio of χb2 (1P ) to χb1 (1P ) production √ cross-sections σ(pp → χb2 (1P )X)/σ(pp → χb1 (1P )X) at centre-of-mass energies of s = 7 and 8 TeV in the rapidity range 2.0 < y < 4.5 as a function of the Υ (1S) transverse momentum from 5 to 25 GeV/c. The full LHCb sample is used, corresponding to an integrated luminosity of 3.0 fb−1 . The observation in LHCb data of the recently observed χb (3P ) state [14, 15] is also presented. The measurement of its mass and of the mass splitting between the χbJ (1P ) states (J = 1 and J = 2) provide useful information for testing QCD models [16–18]. The kinematically allowed transitions χb (1P ) → Υ (1S)γ, χb (2P ) → Υ (1S)γ, χb (3P ) → Υ (1S)γ and χb (3P ) → Υ (2S)γ are studied. The Υ (mS) (m = 1, 2) meson is reconstructed in the dimuon final state and only photons that convert in the detector material are used. The converted photons are reconstructed using e+ and e− tracks, allowing a separation of the χb1 and χb2 mass peaks, due to the improved energy resolution of converted photons with respect to that of photons identified with the calorimeter. Any contribution from the χb0 mesons decays is neglected, as their radiative decay rate is expected to be suppressed by an order of magnitude compared to that of the χb2 meson [17, 19]. 3 Event reconstruction and selection The reconstruction and selection of χb candidates closely follows ref. [13]. Photons that convert in the detector material are reconstructed from pairs of oppositely charged electron candidates. Since the acceptance is lower for photons that convert in the VELO and the energy resolution is worse, only γ → e+ e− candidates without VELO hits are considered. This selection strongly favours conversions that occur between the downstream end of the VELO and the first tracking station upstream of the magnet. The e+ e− candidates are required to be within the ECAL acceptance and to produce electromagnetic clusters that have compatible coordinates in the non bending plane. Any photon whose position in the ECAL is compatible with a straight line extrapolation of the electron track from the first tracking station is considered as a bremstrahlung photon. Its energy is added to the electron energy. If the same bremsstrahlung candidate is found for both the e+ and the e− , the photon energy is added randomly to one of the tracks. The e+ and e− tracks (corrected for bremsstrahlung) are then extrapolated backwards in order to determine the conversion point and a vertex fit is performed to reconstruct the photon momentum. The transverse momentum of the photon candidate (pγT ) is required to be larger than 600 MeV/c and the invariant mass of the e+ e− pair is required to be less than 50 MeV/c2 , which removes most of the combinatorial background. The resulting purity of the photon sample is determined from simulation to be about 99%. The Υ candidate is reconstructed in its decay to the µ+ µ− final state. Each track must be identified as a muon with pT > 2 GeV/c and p > 8 GeV/c. The two muons must originate from a common vertex with vertex fit χ2 /ndf smaller than 25. Only Υ candidates with transverse momentum (pΥT ) greater than 4 GeV/c are kept. Figure 1 shows the invariant mass of Υ candidates. The mass resolution is about 43 MeV/c2 . The accepted mass ranges for the Υ (1S) and for the Υ (2S) candidates are given in table 1. –3– JHEP10(2014)088 The trigger consists of a hardware stage, based on information from the calorimeter and muon systems, followed by a software stage, which applies a full event reconstruction. Events used in this analysis are first required to pass a hardware trigger that selects muon candidates with pT > 1.76 GeV/c or dimuon candidates with a product of their pT larger than (1.6 GeV/c)2 . In the software trigger both muons are required to have pT > 0.5 GeV/c, total momentum p > 6 GeV/c, and dimuon invariant mass greater than 4.7 GeV/c2 . In the simulation, pp collisions are generated using Pythia [21, 22] with a specific LHCb configuration [23]. Decays of hadronic particles are described by EvtGen [24], in which final state radiation is generated using Photos [25]. The interaction of the generated particles with the detector and its response are implemented using the Geant4 toolkit [26, 27] as described in ref. [28]. The simulated samples consist of events containing at least one Υ meson that is forced to decay to two muons. In a sample used for background studies, no restriction on the Υ meson production mechanism is imposed. This sample is referred to as inclusive Υ in the following. In another sample, used for the estimation of signal efficiencies and parametrisation, the Υ is required to originate from a χb meson. This simulated sample is about 10 times larger than the data sample. (n, m) (1,1) (2,1) (3,1) (3,2) pΥT pγT > 4.0 > 4.0 > 5.0 > 6.0 > 0.6 > 0.9 > 1.3 > 0.7 9360 < m(µ+ µ− ) < 9560 9960 < m(µ+ µ− ) < 10100 Low mass SB range ( MeV/c2 ) 9000 < m(µ+ µ− ) < 9200 9650 < m(µ+ µ− ) < 9850 High mass SB range ( MeV/c2 ) 9650 < m(µ+ µ− ) < 9850 10150 < m(µ+ µ− ) < 10250 ( GeV/c) ( GeV/c) Υ mass range ( MeV/c2 ) Table 1. Selection criteria for each χb (nP ) → Υ(mS)γ transition. SB indicates sideband. 4 Sample composition and fit model Two background sources are considered in the sample of χb candidates. One source is the non-Υ background originating mainly from the Drell-Yan process where the dimuon pair is combined with a photon. The second source is the combinatorial background where a genuine Υ is combined with a random photon. The functions used for the fits are the sums of a background and signal functions. The χb1 and χb2 peaks are each parametrised with a double sided Crystal Ball (CB) function [29]: 1 m∗ − mi 2 CBi (m ) ∝ exp − 2 σi ∗ if − αL < –4– m∗ − mi < αR σi JHEP10(2014)088 The Υ and γ candidates are each associated with the primary vertex (PV) relative to which they have the smallest impact parameter χ2 , defined as the difference between the χ2 of the PV reconstructed with and without the considered tracks. They are then combined to form a χb candidate. The χb decay time has to be smaller than 0.1 ps (about 5 times the observed resolution). Loose requirements are applied in order to reject combinatorial background and poorly reconstructed candidates using the following variables: the difference in z-positions of the primary vertices associated with the Υ and γ candidates, the χ2 of the χb candidate vertex fit and the difference between the χ2 of the PV fitted with and without the χb candidate. These requirements remove about 30% of the background and 8% of the signal. The cosine of the angle between the photon momentum in the χb rest frame and the χb momentum is required to be positive. This requirement halves the background while preserving 92% of the signal. The χb candidates are selected in the rapidity range 2.0 < y < 4.5. The χb candidates’ mass is defined as m∗ (µ+ µ− γ) ≡ m(µ+ µ− γ) − m(µ+ µ− ) + m(Υ ), where m(Υ (1S)) = 9460.3 ± 0.3 MeV/c2 and m(Υ (2S)) = 10023.3 ± 0.3 MeV/c2 are the known Υ mass values [19]. This allows a nearly exact cancellation of the uncertainty due to the Υ mass resolution and any possible bias on the Υ candidates mass. The χb mass resolution is therefore dominated by the resolution on the photon energy. The requirements on pΥT and pγT and the Υ signal mass ranges used for each χb (nP ) → Υ (mS)γ decay mode are given in table 1. Candidates / (10 MeV/c2) 2000 LHCb 1500 1000 0 9000 9500 10000 10500 11000 m(µ +µ -) [MeV/c2] Figure 1. Invariant dimuon mass of the Υ candidates after the event selection requirements and before the Υ mass range requirement. The distribution is fitted with the sum (blue line) of a double-sided Crystal Ball function for each Υ state (dashed red line for Υ (1S), dotted pink line for Υ (2S), dash-dotted green line for Υ (3S)) and a second-order polynomial for the background (not shown). The hatched red bands show the signal regions and the hatched blue bands show the mass sidebands used for background studies. 2) (nL /αL )nL exp(− 12 αL (nL /αL − αL − (m∗ − mi )/σi )nL 2) (nR /αR )nR exp(− 12 αR CBi (m∗ ) ∝ (nR /αR − αR + (m∗ − mi )/σi )nR CBi (m∗ ) ∝ if m∗ − mi < −αL σi if m∗ − mi > αR , σi (4.1) where the index i = 1(2) refers to the χb1 (χb2 ) CB function. The CB left tail accounts for events with unreconstructed bremsstrahlung, while the right tail accounts for events with overcorrected bremsstrahlung. Simulation shows that the same tail parameters αR and nL,R can be used for all the χbi (nP ) states, nL = nR = 2.5 and αR = 1.0, while different values of αL have to be used: αL = 0.20, 0.25 and 0.30, for the χbi (1P ), χbi (2P ) and χbi (3P ) shapes, respectively. Since in the study of χc states it was found that the CB tail parameters were similar in data and simulation [13], the values found with simulation are used for the χb . The CB width, σ, increases with the mass difference between the considered χb and Υ states. Fits to the mass distributions of χb (1P ) → Υ (1S)γ and χb (2P ) → Υ (1S)γ candidates indicate that the width is 10% − 20% larger in data than in simulation. Therefore, the CB width is fixed to the value found with simulated events increased by 10% and it is varied by ±10% for studies of the systematic effects. The shape of the non-Υ background and its amplitude are estimated using the Υ mass sidebands shown in figure 1 and given in table 1. The mass distribution of these candidates is fitted with an empirical function ∗ ∗ m − m0 m ∗ fbkg (m ) ∝ arctan +b −1 +a, (4.2) c m0 –5– JHEP10(2014)088 500 5 5.1 χb meson masses Mass measurements The masses of the χb mesons are determined using unbinned maximum likelihood fits to the χb mass distributions using the parametrisation described in section 4. Figures 2 (a) and (b) show the mass distributions for the χb (1P ) → Υ (1S)γ and χb (2P ) → Υ (1S)γ decays with the fit results overlaid. In these fits the free parameters are m1 , A1 , ∆m12 , r12 and Acomb . Table 2 reports the resulting mass determinations for these states compared to the world average values [19]. A small bias is expected on the measured masses, attributed to unreconstructed bremsstrahlung of the e+ e− pair. This bias is proportional to the Q-value of the transition and is expected, from simulation, to be about −0.5 and −1.5 MeV/c2 for the χb (1P ) → Υ (1S)γ and χb (2P ) → Υ (1S)γ decays, respectively. The measurements given in table 2 are not corrected for this bias and are consistent with such a bias. On the other hand the χb (3P ) mass measured using the χb (3P ) → Υ (mS)γ transitions is corrected for the bias estimated with simulation, −3.0 ± 2.0 MeV/c2 and −0.5 ± 0.5 MeV/c2 for m = 1 and m = 2, respectively, where the uncertainties cover possible discrepancies between data and simulation. In the case of the χb (3P ) meson, the mass splitting and the relative yields are also fixed, as the spin-1 and spin-2 peaks cannot be separated. Theory predictions vary from 9 to 12 MeV/c2 [16, 17] for ∆m12 and this parameter is fixed to 10.5 MeV/c2 . The value of r12 is fixed based on theoretical predictions [17] and our experimental measurement. It can be expressed as the product of the ratio of branching fractions to Υ γ and of the ratio of production cross-sections of the χb2 (3P ) and χb1 (3P ) states. Predictions for branching fractions are found in refs. [17, 18]. The predictions from ref. [17] agree well with the experimental measurements for the χb (1P ) and the χb (2P ) mesons. The model of ref. [17] predicts similar values for the two transitions, B(χb2 (3P ) → Υ (mS)γ))/B(χb1 (3P ) → Υ (mS)γ) ≈ 0.47 (m = 1, 2). According to ref. [8] the ratio of production cross-sections is expected to be the same for the χb (3P ) and χb (1P ) mesons and thus, using the measurement detailed in section 6, we obtain σ(χb2 (nP ))/σ(χb1 (nP )) = 0.9 ± 0.2. –6– JHEP10(2014)088 where m0 , a, b and c are free parameters. This function is then used to parametrise the non-Υ background contribution with all parameters fixed to the fitted values. The shape of the combinatorial background is estimated using the inclusive Υ simulated sample and parametrised with eq. (4.2). All parameters are fixed to the values found with simulation except for the normalisation. In the case of the χb (3P ) → Υ (2S)γ transition, this shape does not reproduce the data properly and the value of the m0 parameter is therefore left free in the fit. This discrepancy is due to mismodeling of the pΥT spectrum in simulation and is accounted for in the systematic uncertainties. The fits have at most six free parameters: the mean mass value for the χb1 peak m1 , the mass difference between the χb2 and χb1 peaks ∆m12 , the normalisation of the χb1 CB function A1 , the ratio of the χb2 to χb1 CB amplitudes r12 , the normalisation of the combinatorial background Acomb and the m0 parameter for the combinatorial background shape. (n, m) (1,1) (2,1) m1 9892.3 ± 0.5 10254.7 ± 1.3 m1 world average 9892.8 ± 0.4 10255.5 ± 0.6 ∆m12 19.81 ± 0.65 12.3 ± 2.6 ∆m12 world average 19.43 ± 0.37 13.5 ± 0.6 Table 2. Fitted values of the χb (nP ) (n = 1, 2) masses (in MeV/c2 ) from the χb (nP ) → Υ (1S)γ transitions, compared to the world average values. The uncertainties are statistical only. (3,1) (3,2) (3,1)+(3,2) m1 10509.0+5.0 −2.6 10518.5+1.9 −1.3 10515.7+2.2 −3.9 ∆m12 10.5 (fixed) 10.5 (fixed) 10.5 (fixed) N (χb ) 107 ± 19 41 ± 12 169 ± 25 Table 3. Fitted values of the χb (3P ) mass (in MeV/c2 ) for the χb (3P ) → Υ (mS)γ (m = 1, 2) transitions. The last column gives the result of the simultaneous fit to the two transitions. The values are corrected for the mass bias (−3 MeV/c2 and −0.5 MeV/c2 for the Υ (1S) and Υ (2S) transitions, respectively). The last row gives the total χb yields. The uncertainties are statistical only. To summarise, the value r12 = 0.47 × 0.9 = 0.42 is used in the fits to the mass distributions associated with the transitions of the χb (3P ) meson to Υ (1S) and Υ (2S) mesons. Table 3 gives the result of the fits to the mass distributions for the χb (3P ) → Υ (1S)γ and χb (3P ) → Υ (2S)γ transitions. A simultaneous fit to these two distributions is also performed and the result is reported in the last column of table 3. Figure 2 shows the results of these fits. The χb (3P ) → Υ (1S)γ and χb (3P ) → Υ (2S)γ decays are seen with a statistical significance, determined from the likelihood ratio of the fits with background only and with signal plus background hypotheses, of 6.0σ and 3.6σ respectively. The total statistical significance determined with the simultaneous fit is 6.9σ. 5.2 Systematic uncertainties The systematic uncertainties on the measurement of the χb (nP ) (n = 1, 2) mass splitting and of the χb (3P ) mass are detailed as follows. First the systematic uncertainties related to the signal parametrisation are considered. The χb0 contribution is expected to be small because its branching fraction to Υ (1S)γ is less than 2% for χb (1P ) and χb (2P ) mesons [19]. In order to estimate the systematic uncertainty due to the presence of a χb0 or another unknown state, a third CB function is added to the fit, with a peak position fixed to the world average value for the χb (nP ) for n = 1, 2 and left free for the χb (3P ). The resulting yield of χb0 mesons is compatible with zero. The Gaussian width of the CB function is varied within ±10% to cover possible differences between data and simulation. For these two fit variations, the differences between results of the nominal and alternative fits are taken as systematic uncertainties, added in quadrature and referred to as signal uncertainty in table 4. –7– JHEP10(2014)088 (n, m) Candidates / (5.0 MeV/c2) Candidates / (3.0 MeV/c2) 120 100 (a) χ b(1P )→Υ (1S )γ LHCb 80 60 40 90 LHCb (b) χ b(2P )→Υ (1S )γ 80 70 60 50 40 30 Candidates / (6.0 MeV/c2) 40 35 9800 9850 9900 0 9950 m(µ µ γ )-m(µ µ )+m(Υ (1S )) [MeV/c2] (c) χ b(3P )→Υ (1S )γ Candidates / (6.0 MeV/c2) 0 9750 10 LHCb 30 25 20 15 10 10100 25 10200 10300 10400 m(µ µ γ )-m(µ µ )+m(Υ (1S )) [MeV/c2] (d) χ b(3P )→Υ (2S )γ LHCb 20 15 10 5 5 10400 10500 10600 10700 m(µ µ γ )-m(µ µ )+m(Υ (1S )) 0 10800 [MeV/c2] 45 40 35 Candidates / (6.0 MeV/c2) Candidates / (6.0 MeV/c2) 0 (e) Simultaneous fit to χ (3P )→Υ (1S,2S )γ χ b(3P )→Υ (1S )γ b LHCb 30 25 20 15 10 10500 10600 10700 10800 m(µ µ γ )-m(µ µ )+m(Υ (2S )) [MeV/c2] 30 25 (f) Simultaneous fit to χ (3P )→Υ (1S,2S )γ b χ (3P )→Υ (2S )γ LHCb b 20 15 10 5 5 0 10400 10400 10500 10600 10700 m(µ µ γ )-m(µ µ )+m(Υ (1S )) 0 10800 [MeV/c2] 10400 10500 10600 10700 10800 m(µ µ γ )-m(µ µ )+m(Υ (2S )) [MeV/c2] Figure 2. Distribution of m∗ (µ+ µ− γ) ≡ m(µ+ µ− γ) − m(µ+ µ− ) + m(Υ ) for χb candidates with fit projections overlaid for (a) χb (1P ) → Υ (1S)γ, (b) χb (2P ) → Υ (1S)γ, (c,e) χb (3P ) → Υ (1S)γ and (d,f) χb (3P ) → Υ (2S)γ channels. The result of the simultaneous fit to the χb (3P ) → Υ (1S)γ and χb (3P ) → Υ (2S)γ mass distributions is shown in (e) and (f). The cyan dotted line shows the non-Υ background, the grey dashed line shows the combinatorial background, the red dashed line the χb1 contribution, the green dash-dotted line the χb2 contribution, and the blue full line the sum of all these contributions. –8– JHEP10(2014)088 20 20 6 6.1 Relative rate of χb2 (1P ) and χb1 (1P ) production Measurement of the relative rates The production cross-section ratio of the χb2 (1P ) and χb1 (1P ) mesons is measured in three pΥT ranges of different size (the bin limits are given in table 5) using Nχb2 εχb1 B(χb1 → Υ (1S)γ) σ(χb2 ) = , σ(χb1 ) Nχb1 εχb2 B(χb2 → Υ (1S)γ) (6.1) where σ(χbJ ) (J = 1, 2) is the χbJ (1P ) meson production cross-section; NχbJ is the χbJ (1P ) yield; εχbJ is the efficiency to trigger, detect, reconstruct and select a χbJ meson including the contribution from the approximately 20% probability for a photon to convert upstream –9– JHEP10(2014)088 Imperfect modelling of the background is also considered as a possible source of systematic uncertainty. The normalisation of the non-Υ background is varied within the uncertainty of the estimated number of background events under the Υ peak (typically 10%). Negligible variations are observed when the shape of this background is determined using only the low or the high mass sideband. Therefore no systematic uncertainty is assigned from the non-Υ background modelling. The shape of the combinatorial background is particularly sensitive to the m0 value, therefore this parameter is varied within twice its uncertainty. In the case of the χb (3P ) → Υ (2S)γ transition, where the value of m0 is left free in the fit, the value found in simulation is used in an alternative fit, leading to a change of 0.1 MeV/c2 on the χb (3P ) mass. The fit range is also varied by ±100 MeV/c2 on both sides. The differences between results of the nominal fit and these two alternative fits are taken as systematic uncertainties and added in quadrature. The resulting systematic uncertainty is referred to as background uncertainty. The uncertainty on the mass bias (2.0 and 0.5 MeV/c2 for the χb (3P ) mass measurement based on the transition to Υ (1S) and Υ (2S) respectively) is assigned as systematic uncertainty. For the simultaneous fit to the two χb (3P ) mass distributions, the two biases are varied independently within their uncertainties and the largest variation is taken as systematic uncertainty. A small bias is expected on the χb (1P ) mass splitting and is estimated to be at most 0.10 MeV/c2 , which is added as a systematic uncertainty. No significant bias on the χb (nP ) mass splitting is expected from the fit procedure. For the determination of the χb (3P ) mass, the ∆m12 and r12 parameters are fixed in the nominal fit. They are varied independently within their expected uncertainties in order to evaluate the associated systematic uncertainties. The mass splitting, ∆m12 , is varied between 9 and 12 MeV/c2 and the r12 parameter is varied by ±30%, which includes theoretical uncertainties and the precision on the χb (1P ) production ratio measured in this work and used to estimate r12 . Finally, the 0.3 MeV/c2 uncertainty on the world-average values of the Υ (1S) and Υ (2S) masses is added as a systematic uncertainty to the χb (3P ) mass. Table 4 lists the individual systematic uncertainties. The total systematic uncertainty is the quadratic sum of all individual uncertainties. ∆m12 (1P) ∆m12 (2P) m(χb1 (3P)) m(χb1 (3P)) m(χb1 (3P)) from Υ (1S) from Υ (2S) combined ±0.16 ±0.5 ±0.3 ±0.1 ±0.6 Background ±0.08 ±0.3 ±0.2 ±0.1 ±0.2 Bias ±0.10 ±0.1 ±2.0 ±0.5 r12 - - +0.7 −0.4 +0.1 −0.2 +1.2 −1.6 +0.6 −1.1 ∆m12 - - ±1.2 ±0.1 ±0.3 m(Υ ) - - ±0.3 ±0.3 ±0.3 Total ±0.20 ±0.6 +2.5 −2.4 ±0.6 +1.5 −2.1 Table 4. Summary of the systematic uncertainties on the χb (nP ) (n = 1, 2) mass splitting and on the χb1 (3P ) mass in MeV/c2 . The last column refers to the simultaneous fit to the two transitions. pΥT bin ( GeV/c) 5–10 10–15 15–25 N (χb2 )/N (χb1 ) 0.61 ± 0.15 0.57 ± 0.15 0.52 ± 0.15 ε(χb1 )/ε(χb2 ) 1.01 ± 0.03 0.90 ± 0.05 1.18 ± 0.11 Table 5. Relative rate of χb1 (1P ) and χb2 (1P ) production and ratio of total efficiency (in the three pΥT ranges). Uncertainties only refer to the statistical contributions. of the first tracking station; and B(χb1 (1P ) → Υ (1S)γ) = (33.9 ± 2.2)% and B(χb2 (1P ) → Υ (1S)γ) = (19.1 ± 1.2)% are the known branching fractions [19] . The inefficiency is dominated by the converted photon acceptance and reconstruction: low-energy photons produce low-energy electrons, which have a high chance to escape the detector due to the magnetic field. The efficiency of converted photon reconstruction and selection relative to non-converted photons is measured in ref. [13] and ranges from about 1% at pγT of 600 MeV/c to 3% at pγT of 2000 MeV/c. These numbers include the conversion probability. Due to the correlation between the pT of the photon and that of the Υ meson, the efficiency is lower for low pΥT . The ratio of efficiencies is given in table 5. This ratio differs from unity because the pΥT spectrum is different for χb1 and χb2 in Pythia 8, as expected [8]. The ratio of efficiencies is also calculated assuming equal pT spectra. It is still slightly different from unity due to the small difference in the χb1 and χb2 masses. The mass distribution of χb candidates in each pΥT bin is fitted using the signal and background functions described in section 4. In these fits the mass of the χb1 state and the mass splitting are fixed to the values found from the fit to the whole data set (see table 2) and then varied within their uncertainties for systematic studies. The result of the fit is shown in figure 3 and the ratio of yields is given in table 5 for each pΥT range. 6.2 Systematic uncertainties The same sources of systematic uncertainties as for the mass measurements (see section 5.2) are investigated and reported in table 6. Additional systematic checks relevant only for the relative rates of χb2 (1P ) and χb1 (1P ) are detailed as follows. – 10 – JHEP10(2014)088 Signal 70 60 (a) 5 < p TΥ < 10 GeV/ c Candidates / (4.0 MeV/c2) Candidates / (4.0 MeV/c2) 80 LHCb χ b(1P )→Υ (1S )γ 50 40 30 20 50 45 40 35 Candidates / (4.0 MeV/c2) χ b(1P )→Υ (1S )γ 25 20 15 10 5 9800 9850 9900 0 9950 m(µ µ γ )-m(µ µ )+m(Υ (1S )) [MeV/c2] 9750 9800 9850 9900 9950 m(µ µ γ )-m(µ µ )+m(Υ (1S )) [MeV/c2] 35 30 (c) 15 < p ΥT < 25 GeV/ c 25 χ b(1P )→Υ (1S )γ LHCb 20 15 10 5 0 9750 9800 9850 9900 9950 m(µ µ γ )-m(µ µ )+m(Υ (1S )) [MeV/c2] Figure 3. Distribution of m∗ (µ+ µ− γ) ≡ m(µ+ µ− γ) − m(µ+ µ− ) + m(Υ ) for χb (1P ) candidates with fit projections overlaid for each of the three ranges in pΥT : (a) 5–10 GeV/c, (b) 10–15 GeV/c and (c) 15–25 GeV/c. The cyan dotted line show the non-Υ background, the grey dashed line shows the combinatorial background, the red dashed line the χb1 contribution, the green dash-dotted line the χb2 contribution and the blue full line the sum of all these contributions. The dominant uncertainty on the ratio of efficiencies is due to the limited knowledge of the efficiency for reconstructing converted photons, which is estimated following ref. [13] and amounts to 4% on the relative rates. This uncertainty is added in quadrature to the uncertainty due to the limited size of the simulated sample. Due to the large size of the pT bins, the efficiency depends on the choice of the pT spectrum of χb production as discussed in section 6.1. In order to assess the uncertainty due to the shape of the pT spectrum, the simulated χb2 (χb1 ) spectrum is changed to be identical to the simulated χb1 (χb2 ) spectrum. The relative difference in the ratio of efficiencies is taken as a systematic uncertainty. The fit is also performed on simulated data and a mean bias of (−4 ± 4)% is observed on the relative yields. A systematic uncertainty of ±4% is added to take the possible bias into account. The values of the χb1 (1P ) mass m1 and of the mass splitting ∆m12 are also varied within their uncertainties from table 2. The variation of the result is taken as systematic uncertainty and is added in quadrature to the uncertainty referred to as signal. – 11 – JHEP10(2014)088 9750 LHCb 30 10 0 (b) 10 < p ΥT < 15 GeV/ c pΥT bin ( GeV/c) 5–10 10–15 15–25 Signal ±0.05 ±0.08 ±0.08 Background ±0.06 ±0.04 ±0.03 Fit bias ±0.04 ±0.04 ±0.04 Efficiency ±0.05 ±0.06 ±0.10 pT model −0.13 −0.05 −0.04 +0.10 −0.16 +0.12 −0.13 +0.13 −0.14 Total Table 6 lists the systematic uncertainties on the relative rates. The total systematic uncertainty is the quadratic sum of all individual uncertainties. The ratio of cross-sections is also affected by the uncertainties on the branching fraction of χb (1P ) → Υ (1S)γ, leading to an additional systematic uncertainty of 9.0% [19]. 7 Results The results for the χb (1, 2P ) mass splittings between the J = 1 and J = 2 states ∆m12 (1P ) = 19.81 ± 0.65(stat) ± 0.20(syst) MeV/c2 ∆m12 (2P ) = 12.3 ± 2.6(stat) ± 0.6(syst) MeV/c2 are in agreement with the world average values, ∆m12 (1P ) = 19.43 ± 0.37 MeV/c2 and ∆m12 (2P ) = 13.5 ± 0.6 MeV/c2 [19]. A measurement of the χb1 (3P ) mass, +2.5 2 m(χb1 (3P )) = 10509.0+5.0 −2.6 (stat)−2.4 (syst) MeV/c , is derived from the radiative transition to the Υ (1S) meson, where the χb (3P ) is observed with a statistical significance of 6.0σ. Another measurement, 2 m(χb1 (3P )) = 10518.5+1.9 −1.3 (stat) ± 0.6(syst) MeV/c , is derived from the radiative transition to the Υ (2S) transition, where evidence is found for the χb (3P ) with a statistical significance of 3.6σ. The systematic uncertainty related to r12 is largely uncorrelated between the Υ (2S) and Υ (1S) channels as the branching fractions of χbi to final states involving Υ (1S) and to Υ (2S) mesons can be different. By treating the systematic uncertainties related to the mass splitting and to the mass bias as fully correlated and all other uncertainties as uncorrelated, the two results for the χb1 (3P ) mass 2 differ by 9.3+3.2 −5.2 (stat) ± 2.0(syst) MeV/c . A combined fit is performed leading to +1.5 2 m(χb1 (3P )) = 10515.7+2.2 −3.9 (stat)−2.1 (syst) MeV/c . In these measurements, the relative rate of χb2 to χb1 , is assumed to be r12 = 0.42 for the two transitions. The χb1 (3P ) mass result exhibits a linear dependence on the assumed – 12 – JHEP10(2014)088 Table 6. Summary of the systematic uncertainties on the χb (1P ) relative rates, expressed as fractions of the relative rate. pΥT bin ( GeV/c) σ(χb2 )/σ(χb1 ) 5–10 1.09 ± 0.27(stat)+0.11 −0.18 (syst) ± 0.10 (B) 10–15 0.91 ± 0.24(stat)+0.10 −0.12 (syst) ± 0.08 (B) 15–25 1.09 ± 0.31(stat)+0.14 −0.15 (syst) ± 0.10 (B) Table 7. Relative production cross section of χb1 to χb2 mesons for the 1P state for each pΥT bin. The first uncertainty is statistical, the second is the systematic uncertainty and the third is due to the uncertainty on the branching fractions. 8 Conclusion The radiative decays of χb mesons to Υ mesons are reconstructed with photons converting in the detector material. Owing to the good energy resolution obtained with converted photons, the χb (1P ) states are separated and the mass splitting between the χb1 (1P ) and χb2 (1P ) is measured. The χb (3P ) mass is measured using its radiative decays to the Υ (1S) and Υ (2S) mesons yielding, +1.5 2 m(χb1 (3P )) = 10515.7+2.2 −3.9 (stat)−2.1 (syst) MeV/c . This result is compatible with the measurement performed by LHCb with the radiative decays to the Υ (3S) meson that uses non-converted photons [31], m(χb1 (3P )) = 10511.3 ± 1.7(stat) ± 2.5(syst) MeV/c2 . Since the photon reconstruction is based on different subdetectors, the experimental systematic uncertainties are uncorrelated, while the – 13 – JHEP10(2014)088 fraction of χb1 decays and varies from 10517.6 to 10515.2 when the χb2 /χb1 yield ratio changes from zero to 0.5. This result is compatible with and significantly more precise than that reported by the ATLAS experiment, m(χb (3P )) = 10530 ± 5(stat) ± 9(syst) MeV/c2 for r12 = 1 and ∆m12 = 12 MeV/c2 , where m(χb (3P )) is the average mass of χb1 and χb2 states [14]. The LHCb result is also compatible with the D0 measurement, m(χb (3P )) = 10551 ± 14(stat) ± 17(syst) MeV/c2 [15]. The ratio of the χb2 to χb1 production cross-sections is measured in three pΥT ranges using eq. (6.1). The results are given in table 7. Figure 4 (a) shows a comparison of the measured values with LO NRQCD predictions from ref. [8]. The common systematic uncertainty (9.0%) due to the branching fraction of χb → Υ (1S)γ is not shown. Theory predicts the χc and χb ratio of production cross-section to be the same when the χc pT value is scaled by the ratio of the χb and χc masses [8]. As the χb (χc ) and Υ (J/ψ ) pT are strongly correlated, this is assumed to be valid when replacing the χb (χc ) by the Υ (J/ψ ) pT . The measurement obtained by LHCb for the χc production ratio [13] with the pT axis scaled accordingly is also shown for comparison. The χb results are in good agreement with the scaled χc results. These results are not precise enough to establish the deviation from unity predicted by theory at low pT , but the agreement is better with a flat dependence. Our results are also in agreement with the CMS results [30] as shown on figure 4 (b). 2.5 LHCb χ b (a) LHCb χc scaled LO NRQCD 2 σ(χb2) / σ(χb1) σ(χb2) / σ(χb1) 3 b LHCb χc scaled CMS χ b 1 1 0 LHCb χ (b) 1.5 1.5 0.5 2 0.5 2.0<y <4.5 8 10 12 14 16 18 20 22 24 p Υ [GeV/c] χb unpolarised 10 15 20 25 T 30 35 40 p Υ [GeV/c] T Figure 4. Relative production cross-sections of χb1 to χb2 mesons as a function of pΥT . Panel (a) shows the comparison of this measurement (the hatched rectangles show the statistical uncertainties and the red crosses the total experimental uncertainty) to the LO NRQCD prediction [8] (green band), and to the LHCb χc result (blue crosses), where the pT axis has been scaled by m(χb )/m(χc ) = 2.8. Panel (b) compares this measurement (empty squares) to CMS results [30] (filled squares) and to the scaled LHCb χc results (empty circles). The error bars are the total experimental uncertainties and do not include the uncertainties on the branching fractions. uncertainty related to the model used for summing the J = 1 and J = 2 contributions (parametrised with the mass splitting ∆m12 and the relative rates r12 ) are fully correlated. The combined value is m(χb1 (3P )) = 10512.1 ± 2.1(exp) ± 0.9(model) MeV/c2 , where the first uncertainty is experimental (statistical and systematic) and the second accounts for varying ∆m12 from 9.0 to 12.0 MeV/c2 and r12 by ±30%. This result is in agreement with the theoretical prediction of ref. [17], m(χb1 (3P )) = 10516 MeV/c2 . The first measurement of the relative ratio of χb1 to χb2 cross-sections is performed for the χb (1P ) state in the rapidity range 2.0 < y < 4.5 for pΥT from 5 to 25 GeV/c. The results agree with CMS results [30] and with theory expectation based on LHCb χc measurements [13]. The data indicate a deviation from the rise predicted by the LO NRQCD model at low pT and show a better agreement with a flat dependence. Acknowledgments We thank A. Luchinsky and A. Likhoded for providing the LO NRQCD predictions. We express our gratitude to our colleagues in the CERN accelerator departments for the excellent performance of the LHC. We thank the technical and administrative staff at the LHCb institutes. We acknowledge support from CERN and from the national agencies: CAPES, CNPq, FAPERJ and FINEP (Brazil); NSFC (China); CNRS/IN2P3 (France); BMBF, DFG, HGF and MPG (Germany); SFI (Ireland); INFN (Italy); FOM and NWO (The Netherlands); MNiSW and NCN (Poland); MEN/IFA (Romania); MinES and FANO (Russia); MinECo (Spain); SNSF and SER (Switzerland); NASU (Ukraine); STFC (United – 14 – JHEP10(2014)088 6 0 5 Kingdom); NSF (U.S.A.). The Tier1 computing centres are supported by IN2P3 (France), KIT and BMBF (Germany), INFN (Italy), NWO and SURF (The Netherlands), PIC (Spain), GridPP (United Kingdom). We are indebted to the communities behind the multiple open source software packages on which we depend. We are also thankful for the computing resources and the access to software R&D tools provided by Yandex LLC (Russia). Individual groups or members have received support from EPLANET, Marie SklodowskaCurie Actions and ERC (European Union), Conseil général de Haute-Savoie, Labex ENIGMASS and OCEVU, Région Auvergne (France), RFBR (Russia), XuntaGal and GENCAT (Spain), Royal Society and Royal Commission for the Exhibition of 1851 (United Kingdom). References [1] R. Baier and R. Ruckl, Hadronic collisions: a quarkonium factory, Z. Phys. C 19 (1983) 251 [INSPIRE]. [2] V.G. Kartvelishvili, A.K. Likhoded and S.R. Slabospitsky, D meson and ψ meson production in hadronic interactions, Sov. J. Nucl. Phys. 28 (1978) 678 [Yad. Fiz. 28 (1978) 1315] [INSPIRE]. [3] E.L. Berger and D.L. Jones, Inelastic photoproduction of J/ψ and Υ by gluons, Phys. Rev. D 23 (1981) 1521 [INSPIRE]. [4] G.T. Bodwin, E. Braaten and G.P. Lepage, Rigorous QCD analysis of inclusive annihilation and production of heavy quarkonium, Phys. Rev. D 51 (1995) 1125 [Erratum ibid. D 55 (1997) 5853] [hep-ph/9407339] [INSPIRE]. [5] Y.-Q. Ma, K. Wang and K.-T. Chao, QCD radiative corrections to χcJ production at hadron colliders, Phys. Rev. D 83 (2011) 111503 [arXiv:1002.3987] [INSPIRE]. [6] J.-P. Lansberg, On the mechanisms of heavy-quarkonium hadroproduction, Eur. Phys. J. C 61 (2009) 693 [arXiv:0811.4005] [INSPIRE]. [7] J.M. Campbell, F. Maltoni and F. Tramontano, QCD corrections to J/ψ and Υ production at hadron colliders, Phys. Rev. Lett. 98 (2007) 252002 [hep-ph/0703113] [INSPIRE]. [8] A.K. Likhoded, A.V. Luchinsky and S.V. Poslavsky, Production of χb -mesons at LHC, Phys. Rev. D 86 (2012) 074027 [arXiv:1203.4893] [INSPIRE]. [9] WA11 collaboration, Y. Lemoigne et al., Measurement of hadronic production of the ++ χ++ 1 (3507) and the χ2 (3553) through their radiative decay to J/ψ, Phys. Lett. B 113 (1982) 509 [Erratum ibid. B 116 (1982) 470] [INSPIRE]. [10] HERA-B collaboration, I. Abt et al., Production of the charmonium states χc1 and χc2 in √ proton nucleus interactions at s = 41.6 GeV, Phys. Rev. D 79 (2009) 012001 [arXiv:0807.2167] [INSPIRE]. [11] CDF collaboration, A. Abulencia et al., Measurement of √ σχc2 B(χc2 → J/ψγ)/σχc1 B(χc1 → J/ψγ) in pp̄ collisions at s = 1.96 TeV, Phys. Rev. Lett. 98 (2007) 232001 [hep-ex/0703028] [INSPIRE]. – 15 – JHEP10(2014)088 Open Access. This article is distributed under the terms of the Creative Commons Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in any medium, provided the original author(s) and source are credited. [12] CMS collaboration, Measurement of the relative prompt production rate of χc2 and χc1 in pp √ collisions at s = 7 TeV, Eur. Phys. J. C 72 (2012) 2251 [arXiv:1210.0875] [INSPIRE]. [13] LHCb collaboration, Measurement of the relative rate of prompt χc0 , χc1 and χc2 production √ at s = 7 TeV, JHEP 10 (2013) 115 [arXiv:1307.4285] [INSPIRE]. [14] ATLAS collaboration, Observation of a new χb state in radiative transitions to Υ(1S) and Υ(2S) at ATLAS, Phys. Rev. Lett. 108 (2012) 152001 [arXiv:1112.5154] [INSPIRE]. [15] D0 collaboration, V.M. Abazov et al., Observation of a narrow mass state decaying into √ Υ(1S) + γ in pp̄ collisions at s = 1.96 TeV, Phys. Rev. D 86 (2012) 031103 [arXiv:1203.6034] [INSPIRE]. [17] W. Kwong and J.L. Rosner, D wave quarkonium levels of the Υ family, Phys. Rev. D 38 (1988) 279 [INSPIRE]. [18] J. Ferretti, G. Galatà and E. Santopinto, Quark structure of the X(3872) and χb (3P ) resonances, arXiv:1401.4431 [INSPIRE]. [19] Particle Data Group collaboration, J. Beringer et al., Review of particle physics (RPP), Phys. Rev. D 86 (2012) 010001 [INSPIRE] and 2013 partial update for the 2014 edition. [20] LHCb collaboration, The LHCb detector at the LHC, 2008 JINST 3 S08005 [INSPIRE]. [21] T. Sjöstrand, S. Mrenna and P.Z. Skands, PYTHIA 6.4 physics and manual, JHEP 05 (2006) 026 [hep-ph/0603175] [INSPIRE]. [22] T. Sjöstrand, S. Mrenna and P.Z. Skands, A brief introduction to PYTHIA 8.1, Comput. Phys. Commun. 178 (2008) 852 [arXiv:0710.3820] [INSPIRE]. [23] I. Belyaev et al., Handling of the generation of primary events in Gauss, the LHCb simulation framework, IEEE Nucl. Sci. Symp. Conf. Rec. (2010) 1155 [INSPIRE]. [24] D.J. Lange, The EvtGen particle decay simulation package, Nucl. Instrum. Meth. A 462 (2001) 152 [INSPIRE]. [25] P. Golonka and Z. Was, PHOTOS Monte Carlo: a precision tool for QED corrections in Z and W decays, Eur. Phys. J. C 45 (2006) 97 [hep-ph/0506026] [INSPIRE]. [26] Geant4 collaboration, GEANT4 developments and applications, IEEE Trans. Nucl. Sci. 53 (2006) 270 [INSPIRE]. [27] Geant4 collaboration, S. Agostinelli et al., GEANT4: a simulation toolkit, Nucl. Instrum. Meth. A 506 (2003) 250 [INSPIRE]. [28] M. Clemencic et al., The LHCb simulation application, Gauss: design, evolution and experience, J. Phys. Conf. Ser. 331 (2011) 032023 [INSPIRE]. [29] T. Skwarnicki, A study of the radiative CASCADE transitions between the Υ0 and Υ resonances, Ph.D. thesis, Institute of Nuclear Physics, Krakow Poland (1986) [DESY-F31-86-02] [INSPIRE]. [30] CMS collaboration, Measurement of the production cross section ratio √ σ(χb2 (1P ))/σ(χb1 (1P )) in pp collisions at s = 8 TeV, arXiv:1409.5761 [INSPIRE]. √ [31] LHCb collaboration, Study of χb meson production in pp collisions at s = 7 and 8 TeV and observation of the decay χb (3P ) → Υ(3S)γ, submitted to Eur. Phys. J. C [arXiv:1407.7734] [INSPIRE]. – 16 – JHEP10(2014)088 [16] L. Motyka and K. Zalewski, Mass spectra and leptonic decay widths of heavy quarkonia, Eur. Phys. J. C 4 (1998) 107 [hep-ph/9709254] [INSPIRE]. The LHCb collaboration – 17 – JHEP10(2014)088 R. Aaij41 , B. Adeva37 , M. Adinolfi46 , A. Affolder52 , Z. Ajaltouni5 , S. Akar6 , J. Albrecht9 , F. Alessio38 , M. Alexander51 , S. Ali41 , G. Alkhazov30 , P. Alvarez Cartelle37 , A.A. Alves Jr25,38 , S. Amato2 , S. Amerio22 , Y. Amhis7 , L. An3 , L. Anderlini17,g , J. Anderson40 , R. Andreassen57 , M. Andreotti16,f , J.E. Andrews58 , R.B. Appleby54 , O. Aquines Gutierrez10 , F. Archilli38 , A. Artamonov35 , M. Artuso59 , E. Aslanides6 , G. Auriemma25,n , M. Baalouch5 , S. Bachmann11 , J.J. Back48 , A. Badalov36 , C. Baesso60 , W. Baldini16 , R.J. Barlow54 , C. Barschel38 , S. Barsuk7 , W. Barter47 , V. Batozskaya28 , V. Battista39 , A. Bay39 , L. Beaucourt4 , J. Beddow51 , F. Bedeschi23 , I. Bediaga1 , S. Belogurov31 , K. Belous35 , I. Belyaev31 , E. Ben-Haim8 , G. Bencivenni18 , S. Benson38 , J. Benton46 , A. Berezhnoy32 , R. Bernet40 , M.-O. Bettler47 , M. van Beuzekom41 , A. Bien11 , S. Bifani45 , T. Bird54 , A. Bizzeti17,i , P.M. Bjørnstad54 , T. Blake48 , F. Blanc39 , J. Blouw10 , S. Blusk59 , V. Bocci25 , A. Bondar34 , N. Bondar30,38 , W. Bonivento15,38 , S. Borghi54 , A. Borgia59 , M. Borsato7 , T.J.V. Bowcock52 , E. Bowen40 , C. Bozzi16 , T. Brambach9 , J. van den Brand42 , J. Bressieux39 , D. Brett54 , M. Britsch10 , T. Britton59 , J. Brodzicka54 , N.H. Brook46 , H. Brown52 , A. Bursche40 , G. Busetto22,r , J. Buytaert38 , S. Cadeddu15 , R. Calabrese16,f , M. Calvi20,k , M. Calvo Gomez36,p , P. Campana18,38 , D. Campora Perez38 , A. Carbone14,d , G. Carboni24,l , R. Cardinale19,38,j , A. Cardini15 , L. Carson50 , K. Carvalho Akiba2 , G. Casse52 , L. Cassina20 , L. Castillo Garcia38 , M. Cattaneo38 , Ch. Cauet9 , R. Cenci58 , M. Charles8 , Ph. Charpentier38 , M. Chefdeville4 , S. Chen54 , S.-F. Cheung55 , N. Chiapolini40 , M. Chrzaszcz40,26 , K. Ciba38 , X. Cid Vidal38 , G. Ciezarek53 , P.E.L. Clarke50 , M. Clemencic38 , H.V. Cliff47 , J. Closier38 , V. Coco38 , J. Cogan6 , E. Cogneras5 , L. Cojocariu29 , P. Collins38 , A. Comerma-Montells11 , A. Contu15 , A. Cook46 , M. Coombes46 , S. Coquereau8 , G. Corti38 , M. Corvo16,f , I. Counts56 , B. Couturier38 , G.A. Cowan50 , D.C. Craik48 , M. Cruz Torres60 , S. Cunliffe53 , R. Currie50 , C. D’Ambrosio38 , J. Dalseno46 , P. David8 , P.N.Y. David41 , A. Davis57 , K. De Bruyn41 , S. De Capua54 , M. De Cian11 , J.M. De Miranda1 , L. De Paula2 , W. De Silva57 , P. De Simone18 , D. Decamp4 , M. Deckenhoff9 , L. Del Buono8 , N. Déléage4 , D. Derkach55 , O. Deschamps5 , F. Dettori38 , A. Di Canto38 , H. Dijkstra38 , S. Donleavy52 , F. Dordei11 , M. Dorigo39 , A. Dosil Suárez37 , D. Dossett48 , A. Dovbnya43 , K. Dreimanis52 , G. Dujany54 , F. Dupertuis39 , P. Durante38 , R. Dzhelyadin35 , A. Dziurda26 , A. Dzyuba30 , S. Easo49,38 , U. Egede53 , V. Egorychev31 , S. Eidelman34 , S. Eisenhardt50 , U. Eitschberger9 , R. Ekelhof9 , L. Eklund51 , I. El Rifai5 , Ch. Elsasser40 , S. Ely59 , S. Esen11 , H.-M. Evans47 , T. Evans55 , A. Falabella14 , C. Färber11 , C. Farinelli41 , N. Farley45 , S. Farry52 , RF Fay52 , D. Ferguson50 , V. Fernandez Albor37 , F. Ferreira Rodrigues1 , M. Ferro-Luzzi38 , S. Filippov33 , M. Fiore16,f , M. Fiorini16,f , M. Firlej27 , C. Fitzpatrick39 , T. Fiutowski27 , M. Fontana10 , F. Fontanelli19,j , R. Forty38 , O. Francisco2 , M. Frank38 , C. Frei38 , M. Frosini17,38,g , J. Fu21,38 , E. Furfaro24,l , A. Gallas Torreira37 , D. Galli14,d , S. Gallorini22 , S. Gambetta19,j , M. Gandelman2 , P. Gandini59 , Y. Gao3 , J. Garcı́a Pardiñas37 , J. Garofoli59 , J. Garra Tico47 , L. Garrido36 , C. Gaspar38 , R. Gauld55 , L. Gavardi9 , G. Gavrilov30 , A. Geraci21,v , E. Gersabeck11 , M. Gersabeck54 , T. Gershon48 , Ph. Ghez4 , A. Gianelle22 , S. Gianı̀39 , V. Gibson47 , L. Giubega29 , V.V. Gligorov38 , C. Göbel60 , D. Golubkov31 , A. Golutvin53,31,38 , A. Gomes1,a , C. Gotti20 , M. Grabalosa Gándara5 , R. Graciani Diaz36 , L.A. Granado Cardoso38 , E. Graugés36 , G. Graziani17 , A. Grecu29 , E. Greening55 , S. Gregson47 , P. Griffith45 , L. Grillo11 , O. Grünberg62 , B. Gui59 , E. Gushchin33 , Yu. Guz35,38 , T. Gys38 , C. Hadjivasiliou59 , G. Haefeli39 , C. Haen38 , S.C. Haines47 , S. Hall53 , B. Hamilton58 , T. Hampson46 , X. Han11 , S. Hansmann-Menzemer11 , N. Harnew55 , S.T. Harnew46 , J. Harrison54 , J. He38 , T. Head38 , V. Heijne41 , K. Hennessy52 , P. Henrard5 , L. Henry8 , J.A. Hernando Morata37 , E. van Herwijnen38 , M. Heß62 , A. Hicheur1 , D. Hill55 , M. Hoballah5 , C. Hombach54 , W. Hulsbergen41 , P. Hunt55 , N. Hussain55 , – 18 – JHEP10(2014)088 D. Hutchcroft52 , D. Hynds51 , M. Idzik27 , P. Ilten56 , R. Jacobsson38 , A. Jaeger11 , J. Jalocha55 , E. Jans41 , P. Jaton39 , A. Jawahery58 , F. Jing3 , M. John55 , D. Johnson38 , C.R. Jones47 , C. Joram38 , B. Jost38 , N. Jurik59 , S. Kandybei43 , W. Kanso6 , M. Karacson38 , T.M. Karbach38 , S. Karodia51 , M. Kelsey59 , I.R. Kenyon45 , T. Ketel42 , B. Khanji20 , C. Khurewathanakul39 , S. Klaver54 , K. Klimaszewski28 , O. Kochebina7 , M. Kolpin11 , I. Komarov39 , R.F. Koopman42 , P. Koppenburg41,38 , M. Korolev32 , A. Kozlinskiy41 , L. Kravchuk33 , K. Kreplin11 , M. Kreps48 , G. Krocker11 , P. Krokovny34 , F. Kruse9 , W. Kucewicz26,o , M. Kucharczyk20,26,38,k , V. Kudryavtsev34 , K. Kurek28 , T. Kvaratskheliya31 , V.N. La Thi39 , D. Lacarrere38 , G. Lafferty54 , A. Lai15 , D. Lambert50 , R.W. Lambert42 , G. Lanfranchi18 , C. Langenbruch48 , B. Langhans38 , T. Latham48 , C. Lazzeroni45 , R. Le Gac6 , J. van Leerdam41 , J.-P. Lees4 , R. Lefèvre5 , A. Leflat32 , J. Lefrançois7 , S. Leo23 , O. Leroy6 , T. Lesiak26 , M. Lespinasse4 , B. Leverington11 , Y. Li3 , T. Likhomanenko63 , M. Liles52 , R. Lindner38 , C. Linn38 , F. Lionetto40 , B. Liu15 , S. Lohn38 , I. Longstaff51 , J.H. Lopes2 , N. Lopez-March39 , P. Lowdon40 , H. Lu3 , D. Lucchesi22,r , H. Luo50 , A. Lupato22 , E. Luppi16,f , O. Lupton55 , F. Machefert7 , I.V. Machikhiliyan31 , F. Maciuc29 , O. Maev30 , S. Malde55 , A. Malinin63 , G. Manca15,e , G. Mancinelli6 , A. Mapelli38 , J. Maratas5 , J.F. Marchand4 , U. Marconi14 , C. Marin Benito36 , P. Marino23,t , R. Märki39 , J. Marks11 , G. Martellotti25 , A. Martens8 , A. Martı́n Sánchez7 , M. Martinelli39 , D. Martinez Santos42 , F. Martinez Vidal64 , D. Martins Tostes2 , A. Massafferri1 , R. Matev38 , Z. Mathe38 , C. Matteuzzi20 , A. Mazurov16,f , M. McCann53 , J. McCarthy45 , A. McNab54 , R. McNulty12 , B. McSkelly52 , B. Meadows57 , F. Meier9 , M. Meissner11 , M. Merk41 , D.A. Milanes8 , M.-N. Minard4 , N. Moggi14 , J. Molina Rodriguez60 , S. Monteil5 , M. Morandin22 , P. Morawski27 , A. Mordà6 , M.J. Morello23,t , J. Moron27 , A.-B. Morris50 , R. Mountain59 , F. Muheim50 , K. Müller40 , M. Mussini14 , B. Muster39 , P. Naik46 , T. Nakada39 , R. Nandakumar49 , I. Nasteva2 , M. Needham50 , N. Neri21 , S. Neubert38 , N. Neufeld38 , M. Neuner11 , A.D. Nguyen39 , T.D. Nguyen39 , C. Nguyen-Mau39,q , M. Nicol7 , V. Niess5 , R. Niet9 , N. Nikitin32 , T. Nikodem11 , A. Novoselov35 , D.P. O’Hanlon48 , A. Oblakowska-Mucha27 , V. Obraztsov35 , S. Oggero41 , S. Ogilvy51 , O. Okhrimenko44 , R. Oldeman15,e , C.J.G. Onderwater65 , M. Orlandea29 , J.M. Otalora Goicochea2 , P. Owen53 , A. Oyanguren64 , B.K. Pal59 , A. Palano13,c , F. Palombo21,u , M. Palutan18 , J. Panman38 , A. Papanestis49,38 , M. Pappagallo51 , L.L. Pappalardo16,f , C. Parkes54 , C.J. Parkinson9,45 , G. Passaleva17 , G.D. Patel52 , M. Patel53 , C. Patrignani19,j , A. Pearce54 , A. Pellegrino41 , M. Pepe Altarelli38 , S. Perazzini14,d , P. Perret5 , M. Perrin-Terrin6 , L. Pescatore45 , E. Pesen66 , K. Petridis53 , A. Petrolini19,j , E. Picatoste Olloqui36 , B. Pietrzyk4 , T. Pilař48 , D. Pinci25 , A. Pistone19 , S. Playfer50 , M. Plo Casasus37 , F. Polci8 , A. Poluektov48,34 , E. Polycarpo2 , A. Popov35 , D. Popov10 , B. Popovici29 , C. Potterat2 , E. Price46 , J. Prisciandaro39 , A. Pritchard52 , C. Prouve46 , V. Pugatch44 , A. Puig Navarro39 , G. Punzi23,s , W. Qian4 , B. Rachwal26 , J.H. Rademacker46 , B. Rakotomiaramanana39 , M. Rama18 , M.S. Rangel2 , I. Raniuk43 , N. Rauschmayr38 , G. Raven42 , S. Reichert54 , M.M. Reid48 , A.C. dos Reis1 , S. Ricciardi49 , S. Richards46 , M. Rihl38 , K. Rinnert52 , V. Rives Molina36 , D.A. Roa Romero5 , P. Robbe7 , A.B. Rodrigues1 , E. Rodrigues54 , P. Rodriguez Perez54 , S. Roiser38 , V. Romanovsky35 , A. Romero Vidal37 , M. Rotondo22 , J. Rouvinet39 , T. Ruf38 , H. Ruiz36 , P. Ruiz Valls64 , J.J. Saborido Silva37 , N. Sagidova30 , P. Sail51 , B. Saitta15,e , V. Salustino Guimaraes2 , C. Sanchez Mayordomo64 , B. Sanmartin Sedes37 , R. Santacesaria25 , C. Santamarina Rios37 , E. Santovetti24,l , A. Sarti18,m , C. Satriano25,n , A. Satta24 , D.M. Saunders46 , D. Savrina31,32 , M. Schiller42 , H. Schindler38 , M. Schlupp9 , M. Schmelling10 , B. Schmidt38 , O. Schneider39 , A. Schopper38 , M.-H. Schune7 , R. Schwemmer38 , B. Sciascia18 , A. Sciubba25 , A. Semennikov31 , I. Sepp53 , N. Serra40 , J. Serrano6 , L. Sestini22 , P. Seyfert11 , M. Shapkin35 , I. Shapoval16,43,f , Y. Shcheglov30 , T. Shears52 , L. Shekhtman34 , V. Shevchenko63 , A. Shires9 , R. Silva Coutinho48 , G. Simi22 , M. Sirendi47 , N. Skidmore46 , T. Skwarnicki59 , N.A. Smith52 , E. Smith55,49 , E. Smith53 , 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 Centro Brasileiro de Pesquisas Fı́sicas (CBPF), Rio de Janeiro, Brazil Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, Brazil Center for High Energy Physics, Tsinghua University, Beijing, China LAPP, Université de Savoie, CNRS/IN2P3, Annecy-Le-Vieux, France Clermont Université, Université Blaise Pascal, CNRS/IN2P3, LPC, Clermont-Ferrand, France CPPM, Aix-Marseille Université, CNRS/IN2P3, Marseille, France LAL, Université Paris-Sud, CNRS/IN2P3, Orsay, France LPNHE, Université Pierre et Marie Curie, Université Paris Diderot, CNRS/IN2P3, Paris, France Fakultät Physik, Technische Universität Dortmund, Dortmund, Germany Max-Planck-Institut für Kernphysik (MPIK), Heidelberg, Germany Physikalisches Institut, Ruprecht-Karls-Universität Heidelberg, Heidelberg, Germany School of Physics, University College Dublin, Dublin, Ireland Sezione INFN di Bari, Bari, Italy Sezione INFN di Bologna, Bologna, Italy Sezione INFN di Cagliari, Cagliari, Italy Sezione INFN di Ferrara, Ferrara, Italy Sezione INFN di Firenze, Firenze, Italy Laboratori Nazionali dell’INFN di Frascati, Frascati, Italy Sezione INFN di Genova, Genova, Italy Sezione INFN di Milano Bicocca, Milano, Italy Sezione INFN di Milano, Milano, Italy Sezione INFN di Padova, Padova, Italy Sezione INFN di Pisa, Pisa, Italy Sezione INFN di Roma Tor Vergata, Roma, Italy Sezione INFN di Roma La Sapienza, Roma, Italy Henryk Niewodniczanski Institute of Nuclear Physics Polish Academy of Sciences, Kraków, Poland AGH - University of Science and Technology, Faculty of Physics and Applied Computer Science, Kraków, Poland National Center for Nuclear Research (NCBJ), Warsaw, Poland – 19 – JHEP10(2014)088 J. Smith47 , M. Smith54 , H. Snoek41 , M.D. Sokoloff57 , F.J.P. Soler51 , F. Soomro39 , D. Souza46 , B. Souza De Paula2 , B. Spaan9 , A. Sparkes50 , P. Spradlin51 , S. Sridharan38 , F. Stagni38 , M. Stahl11 , S. Stahl11 , O. Steinkamp40 , O. Stenyakin35 , S. Stevenson55 , S. Stoica29 , S. Stone59 , B. Storaci40 , S. Stracka23,38 , M. Straticiuc29 , U. Straumann40 , R. Stroili22 , V.K. Subbiah38 , L. Sun57 , W. Sutcliffe53 , K. Swientek27 , S. Swientek9 , V. Syropoulos42 , M. Szczekowski28 , P. Szczypka39,38 , T. Szumlak27 , S. T’Jampens4 , M. Teklishyn7 , G. Tellarini16,f , F. Teubert38 , C. Thomas55 , E. Thomas38 , J. van Tilburg41 , V. Tisserand4 , M. Tobin39 , S. Tolk42 , L. Tomassetti16,f , D. Tonelli38 , S. Topp-Joergensen55 , N. Torr55 , E. Tournefier4 , S. Tourneur39 , M.T. Tran39 , M. Tresch40 , A. Trisovic38 , A. Tsaregorodtsev6 , P. Tsopelas41 , N. Tuning41 , M. Ubeda Garcia38 , A. Ukleja28 , A. Ustyuzhanin63 , U. Uwer11 , V. Vagnoni14 , G. Valenti14 , A. Vallier7 , R. Vazquez Gomez18 , P. Vazquez Regueiro37 , C. Vázquez Sierra37 , S. Vecchi16 , J.J. Velthuis46 , M. Veltri17,h , G. Veneziano39 , M. Vesterinen11 , B. Viaud7 , D. Vieira2 , M. Vieites Diaz37 , X. Vilasis-Cardona36,p , A. Vollhardt40 , D. Volyanskyy10 , D. Voong46 , A. Vorobyev30 , V. Vorobyev34 , C. Voß62 , J.A. de Vries41 , R. Waldi62 , C. Wallace48 , R. Wallace12 , J. Walsh23 , S. Wandernoth11 , J. Wang59 , D.R. Ward47 , N.K. Watson45 , D. Websdale53 , M. Whitehead48 , J. Wicht38 , D. Wiedner11 , G. Wilkinson55 , M.P. Williams45 , M. Williams56 , F.F. Wilson49 , J. Wimberley58 , J. Wishahi9 , W. Wislicki28 , M. Witek26 , G. Wormser7 , S.A. Wotton47 , S. Wright47 , S. Wu3 , K. Wyllie38 , Y. Xie61 , Z. Xing59 , Z. Xu39 , Z. Yang3 , X. Yuan3 , O. Yushchenko35 , M. Zangoli14 , M. Zavertyaev10,b , L. Zhang59 , W.C. Zhang12 , Y. Zhang3 , A. Zhelezov11 , A. Zhokhov31 , L. Zhong3 and A. Zvyagin38 . 29 30 31 32 33 34 35 36 37 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 a b c d e f g h – 20 – JHEP10(2014)088 38 Horia Hulubei National Institute of Physics and Nuclear Engineering, Bucharest-Magurele, Romania Petersburg Nuclear Physics Institute (PNPI), Gatchina, Russia Institute of Theoretical and Experimental Physics (ITEP), Moscow, Russia Institute of Nuclear Physics, Moscow State University (SINP MSU), Moscow, Russia Institute for Nuclear Research of the Russian Academy of Sciences (INR RAN), Moscow, Russia Budker Institute of Nuclear Physics (SB RAS) and Novosibirsk State University, Novosibirsk, Russia Institute for High Energy Physics (IHEP), Protvino, Russia Universitat de Barcelona, Barcelona, Spain Universidad de Santiago de Compostela, Santiago de Compostela, Spain European Organization for Nuclear Research (CERN), Geneva, Switzerland Ecole Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland Physik-Institut, Universität Zürich, Zürich, Switzerland Nikhef National Institute for Subatomic Physics, Amsterdam, The Netherlands Nikhef National Institute for Subatomic Physics and VU University Amsterdam, Amsterdam, The Netherlands NSC Kharkiv Institute of Physics and Technology (NSC KIPT), Kharkiv, Ukraine Institute for Nuclear Research of the National Academy of Sciences (KINR), Kyiv, Ukraine University of Birmingham, Birmingham, United Kingdom H.H. Wills Physics Laboratory, University of Bristol, Bristol, United Kingdom Cavendish Laboratory, University of Cambridge, Cambridge, United Kingdom Department of Physics, University of Warwick, Coventry, United Kingdom STFC Rutherford Appleton Laboratory, Didcot, United Kingdom School of Physics and Astronomy, University of Edinburgh, Edinburgh, United Kingdom School of Physics and Astronomy, University of Glasgow, Glasgow, United Kingdom Oliver Lodge Laboratory, University of Liverpool, Liverpool, United Kingdom Imperial College London, London, United Kingdom School of Physics and Astronomy, University of Manchester, Manchester, United Kingdom Department of Physics, University of Oxford, Oxford, United Kingdom Massachusetts Institute of Technology, Cambridge, MA, United States University of Cincinnati, Cincinnati, OH, United States University of Maryland, College Park, MD, United States Syracuse University, Syracuse, NY, United States Pontifı́cia Universidade Católica do Rio de Janeiro (PUC-Rio), Rio de Janeiro, Brazil, associated to 2 Institute of Particle Physics, Central China Normal University, Wuhan, Hubei, China, associated to 3 Institut für Physik, Universität Rostock, Rostock, Germany, associated to 11 National Research Centre Kurchatov Institute, Moscow, Russia, associated to 31 Instituto de Fisica Corpuscular (IFIC), Universitat de Valencia-CSIC, Valencia, Spain, associated to 36 Van Swinderen Institute, University of Groningen, Groningen, The Netherlands, associated to 41 Celal Bayar University, Manisa, Turkey, associated to 38 Universidade Federal do Triângulo Mineiro (UFTM), Uberaba-MG, Brazil P.N. Lebedev Physical Institute, Russian Academy of Science (LPI RAS), Moscow, Russia Università di Bari, Bari, Italy Università di Bologna, Bologna, Italy Università di Cagliari, Cagliari, Italy Università di Ferrara, Ferrara, Italy Università di Firenze, Firenze, Italy Università di Urbino, Urbino, Italy i j k l m n o p q r t u v – 21 – JHEP10(2014)088 s Università di Modena e Reggio Emilia, Modena, Italy Università di Genova, Genova, Italy Università di Milano Bicocca, Milano, Italy Università di Roma Tor Vergata, Roma, Italy Università di Roma La Sapienza, Roma, Italy Università della Basilicata, Potenza, Italy AGH - University of Science and Technology, Faculty of Computer Science, Electronics and Telecommunications, Kraków, Poland LIFAELS, La Salle, Universitat Ramon Llull, Barcelona, Spain Hanoi University of Science, Hanoi, Viet Nam Università di Padova, Padova, Italy Università di Pisa, Pisa, Italy Scuola Normale Superiore, Pisa, Italy Università degli Studi di Milano, Milano, Italy Politecnico di Milano, Milano, Italy