Open heavy flavour reconstruction in the ALICE central barrel

Open heavy flavour reconstruction in the ALICE central barrel

F. Prino for the ALICE collaboration INFN, Sezione di Torino
Abstract

The ALICE experiment will be able to detect open charm and beauty hadrons in proton-proton and heavy ion collisions in the new energy regime of the CERN Large Hadron Collider (LHC). Heavy flavours are a powerful tool to investigate the medium created in high energy nucleus–nucleus interactions because they are produced in the hard scatterings occurring at early times and, thanks to their long lifetime on the collision timescale, they probe all the stages of the system evolution. The detectors of the ALICE central barrel () will allow to track charged particles down to low transverse momentum ( 100 MeV/) and will provide hadron and electron identification as well as an accurate measurement of the positions of primary and secondary vertices. It will therefore be possible to measure the production of open heavy flavours in the central rapidity region down to low transverse momentum, exploiting the semi-electronic and the hadronic decay channels. Here we present a general overview of the ALICE perspectives for heavy flavour physics and some examples from the open charm and beauty analyses which have been developed and tested on detailed simulations of the experimental apparatus.

I Introduction

The measurement of the production of open charm and beauty hadrons is a powerful tool to investigate the properties of the dense and hot medium created in ultra-relativistic heavy ion collisions. Due to the large mass of and quarks, the production of and pairs can only occur in primary hard scatterings with large virtualities. Hence, the open heavy flavour production cross section in nucleon-nucleon collisions can be calculated in the framework of the factorization theorem starting from the DGLAP evoluted Parton Distribution Functions (PDF) and Fragmentation Functions and from the heavy quark production cross section at the partonic level. This last element can be calculated with perturbative QCD beyond the LO MNR (); FONLL (). In nucleus-nucleus collision, heavy flavour production can be evaluated starting from the nucleon-nucleon pQCD calculations and assuming scaling with the number of inelastic nucleon-nucleon collisions (binary scaling). In this framework, the heavy ion collision is modeled as a superposition of several independent nucleon-nucleon collisions: for central Pb-Pb collisions at the LHC (=5.5 TeV) the number of inelastic nucleon-nucleon collisions (N) will be 1800, leading to abundant heavy flavour production.

Such binary scaling is however broken by the presence of initial and final state effects. Initial state effects are modifications of the PDF inside the nuclei, parton saturation at small x, and k broadening due to Cronin effect. Final state effects could be due to the presence of the medium created in the heavy ion collisions. A coloured parton is predicted to lose energy while traversing a coloured medium (with deconfined quarks and gluons) both by radiative and collisional mechanisms Eloss (). The experimental observable that is used to study these effects is the nuclear modification factor R defined as

(1)

which describes the deviation with respect to binary scaling. Energy loss is expected to be different for quarks and gluons, thus leading to the expectation of different quenching for heavy flavoured hadrons (mostly coming from a quark jet) and light hadrons (mostly coming from gluon jets). Furthermore, due to their large mass, the energy loss for open beauty hadrons is expected to be reduced by the dead cone effect DC (). These features can be studied via the double ratios ADSW ():

(2)

which will be accessible at the LHC thanks to the abundant production of and quarks (see next section).

In case of substantial energy loss (as the one observed at RHIC and the larger one anticipated for the LHC), heavy quarks may result to be strongly coupled with the azimuthally asymmetric medium and participate in the collective motion (flow) which develops as a consequence of the re-scatterings among the produced particles. For non-central collisions, as a consequence of the geometrical anisotropy of the overlap region of the colliding nuclei, the heavy quark thermalization in the early stages of the system evolution gives rise to an anisotropic flow in the transverse plane. The development of such a collective motion generates a sizable value of the Fourier coefficient which describes an elliptic azimuthal anisotropy of the observed particles: , where is the reaction plane angle defined by the impact parameter vector in the transverse plane. A contribution to can also result from azimuthal dependent energy loss due to the initial geometrical anisotropy of the fireball.

Finally, the quenching due to energy loss may influence also the hadronization mechanisms at low/intermediate momenta. In this domain, the hadronization of the slowed down heavy quarks is expected to occur mainly through quark coalescence in the medium, thus modifying the relative abundances of particle species with respect to the case of hadronization via parton fragmentation in the vacuum. In particular, this would lead to an increased baryon/meson ratio as well as to an enhanced relative abundance of hadrons containing strange quarks.

Ii Charm and Beauty at the Lhc

At LHC energies (= 14 TeV for p-p and =5.5 TeV for Pb-Pb collisions), charm and beauty production will be abundant: the cross section increases by about a factor 10 for charm and 100 for beauty with respect to RHIC top energy. The charm and beauty cross-sections used in simulations of p-p collisions at = 14 TeV are obtained from NLO pQCD calculations resulting in 0.16 and 0.007 pairs per event PPR2 (). For nucleus-nucleus interactions, binary scaling is assumed and the nuclear modification of the PDF due to shadowing are taken into account, obtaining 115 and 4.6 pairs per central (0-5%) Pb-Pb event. The large yields of and quarks will allow detailed studies on the heavy flavour energy loss as well as on the possible charm and beauty thermalization in the QCD medium. On this respect, in order to constrain theoretical models, it is of crucial importance to have an experimental apparatus capable of measuring separately open charm and beauty hadrons.

The large collision energy will allow also to explore unprecedentedly small values of Bjorken x. By reconstructing open charm hadrons at low p, it is possible to reach x values as small as 10 at mid-rapidity, thus opening the possibility of investigating saturation effects which are expected to play a crucial role in this x region.

Iii Alice Potential for Open Heavy Flavours

The ALICE apparatus TPAP () has excellent capabilities for heavy flavour measurements, for both open heavy flavoured hadrons and quarkonia. In this paper, we will limit the discussion to the detection of open charm and beauty in the central barrel and therefore only the detectors involved in these analyses are described in the following.

The ALICE central barrel covers the pseudo-rapidity region and is equipped with tracking detectors and particle identification systems embedded in a magnetic field B=0.5 T. The combined information from the central barrel detectors allows to track charged particles down to low transverse momenta (low p cut-off 100 MeV/c) and provides hadron and electron identification as well as an accurate measurement of the positions of the primary (interaction) vertex and of the secondary (decay) vertices. The main tracking detector is the Time Projection Chamber (TPC) which provides track reconstruction and particle identification via dE/dx. The Inner Tracking System (ITS) is the central barrel detector closer to the beam axis and is composed of six cylindrical layers of silicon detectors. The two innermost layers (at radii of 4 and 7 cm) are equipped with pixel detectors, the two intermediate layers (radii 15 and 24 cm) are made of drift detectors, while strip detectors are used for the two outermost layers (radii 39 and 44 cm). The ITS is a key detector for open heavy flavour studies because it allows to measure the track impact parameter (i.e. the distance of closest approach of the track to the primary vertex) with a resolution better than 50 m for 1.3 GeV/, thus providing the capability to detect the secondary vertices originating from heavy flavour decays. Two other systems play an important role in the heavy flavour analyses as far as particle identification is concerned. They are the Transition Radiation Detector (TRD) for high-momentum electron identification and the Time-Of-Flight (TOF) for pion, kaon and proton separation on the basis of their time of flight to the TOF. All these four detectors have full azimuthal coverage.

In the Monte Carlo studies reported here, charm and beauty hadrons have been generated with PYTHIA PYTHIA () tuned to reproduce the heavy quark abundances and spectra predicted by NLO pQCD MNR (); PPR2 (). For Pb-Pb collisions, the underlying event has been simulated assuming dN/dy=6000 in the central rapidity region. The generated particles are propagated through the ALICE apparatus using a detailed description of the response of the various detectors.

iii.1 Open charm reconstruction

The exclusive reconstruction of D mesons from hadronic decays has been studied with detailed simulations of the ALICE apparatus for the channels  PPR2 () and  Bruna (). The reconstruction of other channels, namely , and , is also under investigation. It is important to extract the total charm cross-section from the largest possible number of independent channels in order to minimize the systematics. Furthermore, ratios of abundances of different D mesons, like , are expected to be sensitive to the different hadronization mechanisms at work (e.g. string fragmentation vs. coalescence).

Figure 1: Expected relative statistical error in 1 year of data taking for (left) and (right).

The analysis strategy is based on an invariant mass analysis of fully reconstructed decay topologies originating from displaced vertices. The aim is to identify the tracks coming from open charm decays within the full sample of reconstructed tracks. These tracks are originating from secondary vertices which, given the relatively long lifetime of these hadrons ( 0.5-1 ps) are displaced by typically hundreds of microns from the primary vertex. Due to the large combinatorial background, selection cuts are quite severe and have been tuned in order to maximize the statistical significance. Tracks are first selected according to their transverse momentum and their impact parameter. Then all track combinations with proper charge are considered and further selection cuts are applied. In the case of the , the main selections are based on the product of the impact parameters of the K and candidates and on the request that the reconstructed D meson flight line point to the primary vertex, i.e. cosine of the pointing angle close to 1. For the , the longer lifetime (c= 310 m) can be exploited and the crucial selection variables are the distance between the reconstructed primary and secondary vertices and the cosine of the pointing angle as well. Particle identification information will also be used in the selection, at least in Pb-Pb collisions. The relative statistical error (corresponding to the inverse of the significance) on the and measured yields expected in 1 year of data taking (i.e. 10 central Pb-Pb and 10 p-p collisions) is shown in fig. 1 as a function of the D meson p. For the also the case of p-Pb collisions at TeV is shown. The results prove the feasibility, with good performance, of exclusive and reconstruction in a wide range of transverse momentum (1p20 GeV/).

iii.2 Open beauty reconstruction

A detailed Monte Carlo study of inclusive B meson reconstruction from semi-electronic decays has been performed PPR2 (). The selection strategy exploits the different shapes of the p and track impact parameter distributions of the different electron sources (beauty, charm and the various background contributions). The crucial quantities for this analysis are the efficiency and the purity of electron identification in the TPC and in the TRD as well as the resolution on the track impact parameter used to select particles displaced from the primary vertex. The contamination from charm semi-electronic decays (which is significantly reduced by the impact parameter cut thanks to the larger c of B mesons) will be subtracted using the direct measurement of the charm cross-section as obtained from exclusive reconstruction of D mesons. After the selection cuts (in the Monte Carlo studies we have required p GeV/ and track impact parameter m), the expected statistics for 10 central Pb-Pb events is 80000 e with a purity of about 80%. The expected relative statistical error for 1 year of data taking (10 central Pb-Pb and 10 p-p events) is shown in fig. 2.

Figure 2: Expected relative statistical error in 1 year of data taking for beauty reconstruction from displaced electrons.

The p spectra of B mesons down to p GeV/ can also be obtained from the secondary J/ originating from B decays, as done for instance by CDF CDF (). J/ mesons can be detected in the central barrel via their ee decay exploiting tracking and particle identification in ITS, TPC and TRD. The ITS resolution for the secondary vertices allow to separate the prompt J/ from the ones coming from B decays. Finally, a promising approach, presently under investigation, is the topological reconstruction of beauty hadrons from unbalanced displaced vertices with large number of prongs Faivre ().

References

  • (1) M. Mangano, P. Nason and G. Ridolfi, Nucl. Phys. B373 (1992) 295.
  • (2) M. Cacciari, M. Greco and P. Nason, JHEP 9805 (1998) 007.
  • (3) A. Majumder, J. Phys. G34 (2007) S377. See also I. Vitev, arXiv:0806.0003 [hep-ph].
  • (4) Y. L. Dokshitzer and D.E. Kharzeev Phys. Lett. B519 (2001) 199.
  • (5) N. Armesto et al., Phys. Rev. D71 (2005) 054027.
  • (6) ALICE collaboration, J. Phys. G: Nucl. Part. Phys. 32 (2006) 1295.
  • (7) ALICE collaboration, JINST 3 (2008) S08002.
  • (8) T. Sjostrand et al., arXiv:hep-ph/0308153.
  • (9) E. Bruna, PhD thesis, University of Turin (2007). See also arXiv:nucl-ex/0703005v2.
  • (10) D. Acosta et al., Phys. Rev. D71 (2005) 032001.
  • (11) J. Faivre et al, J. Phys. G: Nucl. Part. Phys. 35 (2008) 044047.
Comments 0
Request Comment
You are adding the first comment!
How to quickly get a good reply:
  • Give credit where it’s due by listing out the positive aspects of a paper before getting into which changes should be made.
  • Be specific in your critique, and provide supporting evidence with appropriate references to substantiate general statements.
  • Your comment should inspire ideas to flow and help the author improves the paper.

The better we are at sharing our knowledge with each other, the faster we move forward.
""
The feedback must be of minimum 40 characters and the title a minimum of 5 characters
   
Add comment
Cancel
Loading ...
151114
This is a comment super asjknd jkasnjk adsnkj
Upvote
Downvote
""
The feedback must be of minumum 40 characters
The feedback must be of minumum 40 characters
Submit
Cancel

You are asking your first question!
How to quickly get a good answer:
  • Keep your question short and to the point
  • Check for grammar or spelling errors.
  • Phrase it like a question
Test
Test description