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Status of PPR 6.3, Momentum Correlations . Soft Physics Meeting, 03.05.2005, Jan Pluta, Warsaw University of Technology. The structure . - shifted by Mercedes. C. The structure (2). Mercedes changes in the text. Consistent notation
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Status of PPR 6.3, Momentum Correlations Soft Physics Meeting, 03.05.2005, Jan Pluta, Warsaw University of Technology
The structure - shifted by Mercedes C
Mercedes changes in the text • Consistent notation • New version of “Conclusion from experiments at AGS, SPS and RHIC” • Some changes in the structure, • Language corrections • New figures Jan’s comment: Keep “small relative velocities”.
added by Mercedes
...added by Mercedes ...but pleasse, suply the “oscillations in transverse radii” (M.Lisa et al.)
New Elements Nonidentical Particle Correlations
Nonidentical particle correlations(The idea: assymmetry analysis) Catching up • Effective interaction time larger • Stronger correlation Moving away • Effective interaction time smaller • Weaker correlation “Double” ratio • Sensitive to the space-time asymmetry in the emission process Kinematics selection R.Lednicky, V. L.Lyuboshitz, B.Erazmus, D.Nouais, Phys.Lett. B373 (1996) 30.
STAR: Correlation functions and ratios Good agreement for like- sign and unlike-sign pairs points to similar emission process for K+ and K- CF Out Clear sign of emission asymmetry Side Two other ratios done as a double check – expected to be flat Long Preliminary by Adam Kisiel
STAR: Hit merging in the TPC • Tracks can cross in the TPC for pairs with only one sign of k*Side • If the tracks cross – they can merge, if they merge at the outer part of the TPC, they are not tracked • Cut rejects from the denominator pairs, that would be merged if in the same event
ALICE: Nonidentical particles (pi+,K-) Assumed time shift by Emilia Lubańska
ALICE: Correlation functions (pi+,K-) by Emilia Lubańska
Double ratios: out,side,long (physics + merging) by Emilia Lubańska
HBT correlations in ITS stand alone
Stand alone ITS for HBT analysis (Alberto Pulvirenti) • Motivation: • some running time for a “high rate” data taking, e.g. for muon studies, • in this case the TPC (slow response) cannot be used, • is ITS capable to perform track reconstruction and perform HBT studies? • Tracking in the ITS stand alone: • the first attempt made in (1999) Alice-ITS-99-34, SUBATECH-99-09 • new version based on the Denby-Peterson Neural Tracking, • full C++ implementation into AliRoot, • SIMULATIONS • 160 events, HIJING param. 4000 particles/event • “good” track - 5 points sharing the same GEANT label, • efficiency - (70-80)%
Stand alone ITS for HBT analysis (Alberto Pulvirenti) • ANALYSIS: • only one dim. analysis with respect to Qinv • The method of “weights” by R.Lednicky used to create correlations • Perfect PID assumed ( realistic PID “under study”) • HBT analyser of P. Skowronski used to calculate correlation function
Stand alone ITS for HBT analysis (Alberto Pulvirenti) • RESULTS • Gaussian source distribution with (6, 8, 10, 12)fm assumed • Intercept parameter: lambda (0.5,0.75, 1.0) open points - no correlations full points - R=8fm corrected correlation function
Stand alone ITS for HBT analysis (Alberto Pulvirenti) • CONCLUSIONS • Correlation effect is clearly visible. • Linear correlations of the results with the simulated values. • Reconstructed values underestimate the simulated ones. • Works are in progress.
Direct photons interferometry
Direct photons interferometry with PHOS (by Dmitri Peressounko ) • Specific features of direct photons: • emitted in all stages of the collision, • keep information about the “beginning/hottest” stage of the collision, • Kt dependence select contribution from different stages, • do not suffer from FSI, direct interpretation of the correlation funct. • but most of photons are produced in decay of long living hadrons, • this contribution can be estimated and subtracted. • Registration of two photons by PHOS: • R=5fm => Q=50MeV • If Kt=1GeV, Q/Kt=0.05; 460cm*0.05=23cm - distance between photons in PHOS • One crystal unit =2.5cm • Two local maxima should be separated by one crystal unit • Size of the cluster increase logarithmically with energy
Direct photons interferometry with PHOS (by Dmitri Peressounko ) Unfolding algorithm • Resolution of: • relative distance - 0.4cm • energy: sig(E)/E - 4% • systematic - increasing • (small influence on correl.) Probability to unfolded (filed boxes) and find cluster separated (empty boxes) as a function of distance between them
Direct photons interferometry with PHOS (by Dmitri Peressounko ) Resolution: Qside Qout
Direct photons interferometry with PHOS (by Dmitri Peressounko ) Splitting of complicated clusters: p, p(bar), n, n(bar) Contribution much smaller than those of direct photons
Direct photons interferometry with PHOS (by Dmitri Peressounko ) Photon pairs in high multiplicity envirnment HILING, central Pb+Pb collisions photon conversion before PHOS, heavier resonances
Direct photons interferometry with PHOS (by Dmitri Peressounko ) CONCLUSION Possibility of measurement of two-photon correlations up to Kt=3MeV, even in central Pb+Pb collisions accessing space-time informatin about all major stages of the collisions.
Influence of Resonances
Resonance influence on particle correlations (Ludmila Malinina and Boris Batiounia) Motivation: 2/3 of pions comes from resonance decays, It makes the interpretation of correlation results more complicated • Simulation: • Thermal source with Boltzmann gas of resonances: • short lived: e.g. Rho - mean lifetime - 1.3 fm/c • moderatelylived: omega - mean lifetime - 23.4 fm/c, • long lived: etha’ - mean lifetime - 1000 fm/c • secondary interactions: sigma=400mb
Resonance influence on particle correlations (Ludmila Malinina and Boris Batiounia) Correlation function for different resonance sources
Resonance influence on particle correlations (Ludmila Malinina and Boris Batiounia) 3-dim. correlation function for omega source and rescattering
Correlations in (pp) collisions
Correlations in (pp) collisions (Piotr Skowroński) 1. The size expected ...1-2 fm (1fm assumed in simulations) 2. 105 events generated using PYTHIA (correlatins outside the interferometry region for very small multiplicities, Nch>5 taken) 3. Analysis the same as for Pb+Pb
Correlations in (pp) collisions (Piotr Skowroński)
Two Particle Resolution(Piotr Skowroński, Grzegorz Gałązka) pt range [MeV] Resolution (r.m.s) [MeV] Qout Qside Qlong PDC04 TP PDC04 TP PDC04 TP pt < 300 2.7 3.4 0.4 0.4 0.9 0.8 300< pt < 600 4.2 6.4 0.4 0.4 1.1 0.8 600 < pt 6.3 11 0.6 0.5 1.3 1 • Resolution values are very close to the ones in Technical Proposal • Improvement in Qout is connected to better pt resolution and higher magnetic field
Track Merging – ident. (1) • Anti-Merging cut as implemented by STAR • Cutting on average distance between two tracks in TPC • Space coordinates of tracks are calculated assuming helix shape using track parameters as reconstructed in the inner part of TPC
CorrFit • CorrFit is a tool developed in STAR by Adam Kisiel • CorrFit is able to find parameters that fits correlation function taking to the account: • Final State Interaction (Coulomb and strong) • They are not corrected for but treated as a source of correlations! • Detector resolution • Can work with any model of the freeze-out distribution • Not limited to Gaussian source distribution ! • Is able to fit non-identical particles correlation functions
...to do • Finish the text of PPR (2-4 weeks) • Continue works with resoltion, PID, mergind etc. • Finish works with CORFIT • Cooperate with other groups of Soft Physics at ALICE (asHBT, strange particles etc.) • Cooperate with theorists; EPOS+Hydro, etc. • Be ready for data taking!!! (2007)