Nuclearand ParticlePhysics Proceedings NuclearandParticlePhysicsProceedings00(2017)1–3 ALICE mesurements of heavy-flavour production in pp and p-Pb collisions at the LHC G.LuparellofortheALICECollaboration UniversityofTriesteandINFNTrieste,ViaA.Valerio2,Trieste,Italy 7 1 0 2 n Abstract a √ J The D meson yields as a function of charged-particle multiplicity in pp collisions at s = 7 TeV and in p-Pb √ 1 collisionsat s =5.02TeVarepresented. Themeasurementoftheyieldsofelectronsfromheavy-flavourhadron NN √ 1 decaysasafunctionofcharged-particlemultiplicityinp-Pbcollisionsat s = 5.02TeVareshownaswell. The NN √ measurementofazimuthalcorrelationsofpromptDmesonsandchargedhadronsinppcollisionsat s=7TeVand ] √ x inp-Pbcollisionsat s =5.02TeVarealsopresented. Theresultsarecomparedwithexpectationsfrommodels. NN e - Keywords: ALICE,heavy-flavour,correlations l c u n 1. Introduction sionsaresensitivetothedependenceofCNMeffectson [ the collision geometry and on the density of final-state 1 The study of the production of hadrons containing particles. The measurement of azimuthal correlations v 3 charm and beauty quarks in proton-proton (pp) colli- ofDmesonsandchargedparticlesinppcollisionspro- 6 sions at the LHC provides a way to test calculations videsawaytocharacterizecharmproductionandfrag- 0 basedonperturbativeQCDathighcollisionenergy. In mentationprocesses,whileinp-Pbcollisionstheycould 3 p-Pbcollisions,heavy-flavourhadronproductionissen- giveinsightsintopossiblecollectiveeffectsinsmallsys- 0 sitivetoColdNuclearMatter(CNM)effectssuchasthe tems. . 1 modificationofthepartondistributionsfunctionsinthe TheexcellentperformanceoftheALICEdetector[4] 0 nucleusatsmallBjorken-x(seee.g.[1]),thepartonen- allowsforopenheavy-flavourmeasurementsinseveral 7 ergylossintheinitialstagesofthecollisionviainitial- decaychannelsandinawiderapidityrange. Thiscon- 1 : stateradiation[2]andthetransversemomentumbroad- tribution focuses on the measurements at mid-rapidity v eningduetosoftscatteringsofthepartonsintheincom- where open heavy-flavour production is studied by i X ingnucleus[3]. means of fully reconstructed D mesons (in the decay channelsD0 →K−π+,D+ →K−π+π+,D∗+ →D0π+ → r Inadditiontotransversemomentumandrapiditydif- a K−π+π−,D+ → φπ+ → K−K+π+ andtheirchargecon- ferential distributions, measurements as a function of s jugates)andinthesemi-electronicdecaychannels. multiplicityandstudiesofangularcorrelationsprovide further constraints on the description of heavy-flavour productioninppandp-Pbcollisions. Themeasurement 2. Heavy-flavourproductionasafunctionofmulti- of heavy-flavour production in pp collisions as a func- plicity tion of the charged-particle multiplicity could provide insightsintotheroleofmulti-partoninteractions(MPI) The study of heavy-flavour production as a func- andtheinterplaybetweenhardandsoftmechanismsin tionofthecharged-particlemultiplicityispresentedvia particle production. The multiplicity-differential mea- the self-normalised yields, i.e. the corrected per-event surements of heavy-flavour production in p-Pb colli- yield in a given multiplicity interval normalised to the G.LuparellofortheALICECollaboration/NuclearandParticlePhysicsProceedings00(2017)1–3 2 count for the decay kinematics. The increasing trend 〉T p 25 ALICE ofDmesonsandelectronsfromdecayofheavyflavour dyd Average D0, D+, D*+ meson hadrons is compatible within uncertainties. No depen- / 2<p <4 GeV/c, |y |<0.5 N 20 T lab denceontheelectrontransversemomentumisobserved 2d〈 pp, s = 7 TeV also for p >∼4 GeV/c where a strong contribution ) / T15 p Pb, sNN = 5.02 TeV from beautTy-hadron decays has to be considered. The p d measurement gives a hint that the production mecha- y /d 10 nisms of charm and beauty as a function of the multi- N 2d plicity are similar in p-Pb collisions. The results from ( 5 +6%/ 3% (3.1%) in pp (p Pb) modelcalculationsusingEPOS3eventgenerator[7]for normalisation unc. not shown ± 6% (6.3%) unc. in pp (p Pb) D mesons considering two approaches, i.e. with and on (dNch/dη)/〈dNch/dη〉 not shown nc. 0.4 B fraction hypothesis in pp and p Pb: × 1/2 (2) at low (high) multiplicity withouthydrodynamicalevolutionofthesimulatedini- n u 0.2 tial conditions, are also shown. The calculations using dow 0 ahydrodynamicevolutionareinbetteragreementwith d −0.2 ee−0.4 thefaster-than-linearincreaseoftheD-mesonmeasure- B f 0 1 2 3 4 5(dN 6/dη) /7 〈dN8/dη〉9 ment,suggestingthatcollectiveeffectscouldplayarole ALI−PUB−105454 ch ch in particle production in high-multiplicity p-Pb colli- Figure 1: Self-normalised yields of D mesons as a function of the sions. charged-particlemultiplicityestimatedatmid-rapidityinpp(red)and p-Pb(green)collisions. 3. Azimuthalcorrelations Theazimuthalcorrelationsarebuiltbycalculatingthe multiplicity-integrated value. Multiplicity intervals at differencein∆ηand∆φbetweenareconstructedDme- mid-rapidity are defined by measuring the number of son (trigger particle) andthe primary charged particles tracklets(tracksegmentsjoiningapairofparticlehitsin (associated particles) [8]. Corrections for limited de- thetwolayersoftheSiliconPixelDetectorandaligned tector acceptance, spatial inhomogeneities, trigger and with the reconstructed primary vertex) in the pseudo- associated particle selection efficiency, as well as sec- rapidity interval |η| < 1. The number of tracklets is ondary track contamination are applied. The contri- converted to the charged-particle multiplicity at mid- bution due to the azimuthal correlations of D mesons rapidity (dN /dη) by means of a Monte Carlo simula- ch frombeauty-hadrondecaysandchargedparticlesisob- tion.D0,D+andD∗+self-normalisedyieldsarecompat- tained with PYTHIA simulations and subtracted. Dif- iblewitheachotherwithinuncertaintiesintheanalyzed ferent ranges of the D-meson (3 < pD < 16 GeV/c multiplicity and pT intervals. The average D0, D+ and in pp, 5 < pD < 16 GeV/c in p-Pb)Tand associated D∗+self-normalisedyieldsasafunctionofthecharged- particle p (staTrtingfrom passoc > 0.3GeV/c)arestud- particlemultiplicityatmid-rapidityinppcollisionsand T T ied. Theazimuthalcorrelationdistributionisfittedwith inp-PbcollisionsareshowninFig.1. Asimilarfaster- twoGaussianfunctions(oneforthenear-sidepeakcen- than-linear increasing trend with charged-particle mul- tred at ∆φ = 0 and one for the away-side peak cen- tiplicity is observed in the two colliding systems. In tred at ∆φ = π) on top of the baseline. The base- Ref. [5] it is reported that the measurement in pp col- line is calculated from the region π/4 < |∆φ| < π/2, lisions is qualitatively described by model calculations and its variation upon redefinition of this interval is takingintoaccounttheinfluenceoftheinteractionsbe- treated as a systematic uncertainty. Figure 3 compares tweencoloursourcesinthepercolationmodel[6], and the baseline-subtracted D meson-charged particle az- thecontributionofMPI,throughthePYTHIA8[10]as imuthal correlation distributions extracted in pp colli- wellastheEPOS3eventgenerators[7]. sionswithpredictionsbyPYTHIA6[9],PYTHIA8[10] Figure 2 reports the self-normalised yields of elec- and POWHEG+PYTHIA6 [11, 12] simulations, as a trons from semi-leptonic heavy-flavour hadron decays function of the D-meson p , for different associated T as a function of the charged-particle multiplicity esti- particle p ranges. The simulations reproduce the az- T matedatmid-rapidity,comparedwiththeDmesonmea- imuthal correlation distributions within uncertainties, surement. The different kinematic ranges for the two though a hint for a more pronounced near-side peak observables in each panel approximately account for in data than in models is visible in the 8 < pD < 16 T the effect of the decay kinematics. in each panel ac- GeV/c range. The parameters extracted from the fit to G.LuparellofortheALICECollaboration/NuclearandParticlePhysicsProceedings00(2017)1–3 3 pd〉T10 ALICE p−Pb, sNN = 5.02 TeV10 Electron: 0.5 < p < 2.0 GeV/c 2y/dNd 8 Ac,LbI C→E (Pe+re +li me i)n/2a,r y|ylab| < 0.6 8 D meson: 2.0 < pTT < 4.0 GeV/c ) / p〈T 6 aArvXeirva:1g6e0 D20.0, 7D2+,4 D0*+ meson, |ylab| < 0.5 6 d yd 3.1% normalization unc. not shown 2/Nd 4 6.3% unc. on (dNch/dη) / 〈dNch/dη〉 not shown4 ( EPOS 3.116 (D meson) 2 with hydro 2 without hydro 〉T10 10 pdy DEl emcetrsoonn: :2 4.0.0 < < p pT < < 4 8.0.0 G GeeVV//cc EDl emcetrsoonn: :4 8.0.0 < < p pT < < 8 1.02 .G0 eGVe/Vc/c d T T /N 8 8 2d ) / 〈T 6 6 p d yd 4 4 /N 2d ( 2 2 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 (dN /dη) / 〈dN /dη〉 (dN /dη) / 〈dN /dη〉 ALI−PREL−107478 ch ch ch ch Figure2:Self-normalisedyieldsofDmesonsandofelectronsfromheavy-flavourhadrondecaysasafunctionofthecharged-particlemultiplicity estimatedatmid-rapiditymeasuredinp-Pbcollisions.TheresultsofEPOS3modelcalculations[7]arealsoshown. the correlation distributions allow for a more quantita- correlation distributions of D mesons and charged par- tive comparison of the near-side peak properties. Fig- ticles, measured in pp and p-Pb collisions, as well as ure 4 compares the near-side associated yields and the observables describing near-side peak properties, are near-side peak widths extracted in pp and p-Pb colli- in agreement between each other within uncertainties. sions. Compatible values of the near-side observables TheseobservablesarealsowelldescribedbyPYTHIA areobtainedinppandp-Pbcollisions.Nomodifications andPOWHEG+PYTHIA6MonteCarlosimulations. ofthenear-sidepeaksduetocoldnuclearmattereffects are observed in p-Pb collisions with the current uncer- References tainties. Predictions by POWHEG+PYTHIA6 simula- tions, including nuclear shadowing effects for the nu- [1] K.J.Eskola,H.PaukkunenandC.A.Salgado,JHEP0904,065 cleon parton distribution functions, are also in agree- (2009) mentwiththemeasurements. [2] I.Vitev,Phys.Rev.C75(2007)064906 [3] M. Lev and B. Petersson, Z. Phys. C 21, 155 (1983). doi:10.1007/BF01648792 [4] B.B.Abelevetal.[ALICECollaboration],Int.J.Mod.Phys.A 4. Conclusions 29,1430044(2014) [5] J.Adametal.[ALICECollaboration],JHEP1509,148(2015) [6] E.G.FerreiroandC.Pajares,Phys.Rev.C86,034903(2012) The D mesons self-normalised yields are measured [7] K.Werner,B.Guiot,I.KarpenkoandT.Pierog,Phys.Rev.C as a function of the charged-particle multiplicity esti- 89,no.6,064903(2014) mated at mid-rapidity and the trend can be explained [8] J.Adametal.[ALICECollaboration],arXiv:1605.06963[nucl- ex]. by model calculations with MPI in pp collisions [5]. [9] T. Sjostrand, S. Mrenna and P. Z. Skands, JHEP 0605, 026 In p-Pb collisions a faster-than-linear increase of the (2006) self-normalised yields of D mesons and of electrons [10] T.Sjostrand,S.MrennaandP.Z.Skands,Comput.Phys.Com- from heavy-flavour hadron decays as a function of the mun.178,852(2008) [11] P.Nason,JHEP0411,040(2004) charged-particle multiplicity estimated at mid-rapidity [12] S.Frixione,P.NasonandC.Oleari,JHEP0711,070(2007) isobserved. Thefaster-than-linearincreasesuggestsan interplay between MPIs and multiple binary nucleon- nucleon collisions in p-Pb interactions. The azimuthal G.LuparellofortheALICECollaboration/NuclearandParticlePhysicsProceedings00(2017)1–3 4 1)d 5 Average D0,D+,D*+ALICE 5 < pDT < 8 GeV/c, paTssoc > 0.3 GeV/c 8 < pDT < 16 GeV/c, paTssoc > 0.3 GeV/c aseline (ra 34 3| y<cD pmppsDT|, << 5s0 .G=5 ,e7 |V∆ T/ηce|, V p< aT1ssoc > 0.3 GeV/c SimulaPPPtYYYioTTTnHHHs,III AAAp666p,,,, PPPseee rrr=uuu ggg7iii aaaT 022e00V1101 PPEYOPTOWHSHI A3E8.G1, 1+T7PuYneT H4ICA6 b baseline subtraction uncertainty assocN dϕ∆ 21 −+1103%% scale uncertainty −+1103%% scale uncertainty −+1114%% scale uncertainty d 1 ND 0 1)ad 1.5 3 < pDT < 5 GeV/c, 0.3 < paTssoc < 1 GeV/c 5 < pDT < 8 GeV/c, 0.3 < paTssoc < 1 GeV/c 8 < pDT < 16 GeV/c, 0.3 < paTssoc < 1 GeV/c eline (r 1 −+1103%% scale uncertainty −+1103%% scale uncertainty −+1114%% scale uncertainty as b assocN dϕ∆0.05 d 1 ND−0.5 1)d 2 3 < pDT < 5 GeV/c, paTssoc > 1 GeV/c 5 < pDT < 8 GeV/c, paTssoc > 1 GeV/c 8 < pDT < 16 GeV/c, paTssoc > 1 GeV/c a eline (r 1.5 −+1103%% scale uncertainty −+1103%% scale uncertainty −+1114%% scale uncertainty bas 1 assocN dϕ∆0.5 d 1 ND 0 0 0.5 1 1.5 2 2.5 3 0 0.5 1 1.5 2 2.5 3 0 0.5 1 1.5 2 2.5 3 ∆ϕ (rad) ∆ϕ (rad) ∆ϕ (rad) ALI−PUB−106084 √ Figure3: Azimuthal-correlationdistributionsofpromptDmesonswithchargedparticlesmeasuredinppcollisionsat s=7TeVcomparedto expectationsfromMonteCarlogeneratorsafterthesubtractionofthebaseline. 3 Near side ALICE pp, s = 7 TeV, |yD | < 0.5 cms ed yield 2.25 paTssoc > 0.3 GeV/c, |∆η| < 1 e<n7e%rg p vy0a arP.ni9adbt6i o,r a n<p e sidyxNiptcDyNem c(=sPt ey <d5th .f0ir0ao.,2m 0P 4 eTdrifuefegVriae, n2t011) PsO =W 5H.0E2G T+ePVY,T wHitIhA 6E PppS 0s9im nuPlaDtiFon ociat 1.5 0.3 < paTssoc < 1 GeV/c, |∆η| < 1 paTssoc > 1 GeV/c, |∆η| < 1 ss 1 A 0.5 0 0.6 0.5 d) 0.4 a (rNS 0.3 σfit, 0.2 0.1 0 0 2 4 6 8 10 12 14 160 2 4 6 8 10 12 14 160 2 4 6 8 10 12 14 16 ALI−DER−106D2 m41eson p (GeV/c) D meson p (GeV/c) D meson p (GeV/c) T T T Figure4: Comparisonofthenear-sidepeakassociatedyield(toprow)andpeakwidth(bottomrow)inppandp-Pbcollisionswithexpectations fromPOWHEG+PYTHIA6MonteCarlogenerator.