NA57 Strange particle production from 40 GeV data at the NA57 experiment Paul Norman of the University of Birmingham, United Kingdom on behalf of the CERN.

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Presentation transcript:

NA57 Strange particle production from 40 GeV data at the NA57 experiment Paul Norman of the University of Birmingham, United Kingdom on behalf of the CERN collaboration NA57 SQM 2003, Atlantic Beach 12th-17th March 2003

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Talk contents Underlying physics and motivation. Reminder of NA57 layout and previous results. Yields for Pb-Pb 40 A GeV/c.  (new), ,  Signals for p-Be 40 A GeV/c.  (new) Energy dependence of results. 40 GeV and 160 GeV, comparison with STAR Conclusions and outlook.

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Underlying physics and motivation As one of the main pieces of evidence for deconfinement at the SPS, WA97 showed strangeness enhancements for the strange hyperons, up to a factor of 15 for the . Aim of NA57 – to study strangeness enhancement in more peripheral collisions and as a function of energy. Low energy 40 GeV/c data gives us yields of even triply strange particles in Pb-Pb collisions, and doubly strange in p-Be.  More general concepts of NA57 discussed in the plenary talk of L. Sandor. This talk will focus on the 40 GeV/c results.

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom The NA57 experimental layout Target: 1% Pb 8% Be Scintillator Petals: centrality trigger MSD: Multiplicity Silicon Detector Tracking device: silicon pixel planes (y-z = 5 x 5 cm 2 ) Lever arm: double side  strips

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Strange particle decays  p   BR = 63.9%     BR = 99.9%     BR = 67.8%       BR = 68.6%   Get strange particles and anti-particles from weak decay topologies. 30 cm 5 cm    B Silicon Pixel Tracker

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Yields and inverse slopes in NA57  Inverse slopes are obtained using the formula:  Yield = Yields are extrapolated so that they are integrated over p T, and over 0.5 units of rapidity either side of mid-rapidity.

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom  and  signals at 40 GeV/c 40 A GeV/c 40 A GeV/c  

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Centrality 40 GeV  Results on the following plots are for the integrated centrality classes I-IV unless stated otherwise.  For comparison with RHIC data, only classes III+IV are considered, although  results are for most central 5% NA57/STAR (our bin IV).

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Energy dependence:  and  40 and 160 GeV   from 40 GeV to 160 GeV:  and     about same,   up by a factor 3, anti-particles up by a factor 5  Larger baryon density at 40 GeV/c p T > 0,  y-y cm  < 0.5 Black bars are systematic errors

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom  and  yields from SPS to RHIC  from NA57 40 GeV to 160 GeV, and confirmed by STAR: ,   and    yields increase slower than their anti-particles   at RHIC about same production rate for hyperon and anti-hyperon STAR results from: - C. Adler et al. Phys. Rev. Lett. 89: (2002) for  - J. Castillo from QM2002 nucl-ex/ for  - C. Suire from QM2002 nucl-ex/ for  Most central events:  12% for NA57 (bins III+IV)  14% for STAR

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Y/Y ratios from SPS to RHIC STARNA57  Ratio Y/Y approaches 1 as energy increases. Energy dependence weaker for higher strangeness (and thus lower light quark) content. Most central events:  12% for NA57  14% for STAR STAR results from: - C. Adler et al. Phys. Rev. Lett. 89: (2002) for  - J. Castillo from QM2002 nucl-ex/ for  - C. Suire from QM2002 nucl-ex/ for 

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Conclusions Yields: From 40 GeV/c data to 160 GeV/c there is an increase in anti-particle yields (by about a factor 5), while the corresponding particle yields remain almost constant. As could be expected, the  and  yields with respect to their anti-particles indicates a larger baryon 40 w.r.t. 160 GeV/c. RHIC data confirms this trend. Baryon yields show a weak dependence on energy, while anti-baryon yields are strongly dependent from 40 GeV to 160 GeV. RHIC data shows this effect continues.

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom Outlook 40 A GeV/c:  and  yields  Enhancements in Pb-Pb relative to 40 GeV/c. Negatives, K 0 40 A GeV/c: Negatives, K 0

NA57 SQM 2003, Atlantic Beach P.Norman, University of Birmingham, United Kingdom The NA57 Collaboration Athens University, Athens, Greece; Università di Bari and INFN, Bari, Italy; Universitetet i Bergen, Bergen, Norway; Høgskolen i Bergen, Bergen, Norway; University of Birmingham, Birmingham, UK; Comenius University, Bratislava, Slovakia; Università di Catania and INFN, Catania, Italy; CERN, Geneva, Switzerland; Institute of Experimental Physics SAS, Kosice, Slovakia; P.J. Safárik University, Kosice, Slovakia; Universitetet i Oslo, Oslo, Norway; Università di Padova and INFN, Padua, Italy; Collège de France and IN2P3, Paris, France; Academy of Sciences, Prague, Czech Republic; Università "La Sapienza“ di Roma and INFN, Rome, Italy; Università di Salerno and INFN, Salerno, Italy; State University of St. Petersburg, St. Petersburg, Russia; Insitut de Recherches Subatomiques, IN2P3/ULP, Strasbourg, France; Utrecht University and NIKHEF, Utrecht, The Netherlands.