Feasibility of hyperons study with ECAL

Feasibility of hyperons study with ECAL • Sergey Kiselev, ITEP Moscow, for the ECAL group • Introduction • Motivation • Input info and assumptions • Spectra • Acceptance • Multiplicity • Signal • Signal + Background • Conclusions and next steps Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Introduction • Hyperons with “neutral” decay modes: • Σ-(dds)  n- Br=99.8% c=4.4 cm • Σ+(uus)  p o Br=51.6% c=2.4 cm Σ+(uus)  n+ Br=48.3% • Σo (uds) Λ Br=100% c=2.2 10-9 cm • o(uss)  Λo Br=99.5% c=8.71 cm • p, -, +, Λ p -can be identified by TOF. • , n, o   can be identified by ECAL. • Measurements with the CBM (Compressed Baryonic Matter) detector will be analyzed. Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Introduction - the CBM detector Tracking: STS, TRD Vertexing: STS Hadron ID : TOF Electron ID: RICH, TRD, ECAL , neutral m, n: ECAL Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Motivation - 1 • The pronouncedkink structure in the K+/+ ratio has caused speculations on a possible deconfinement phase transitionaround 30 AGeV • Which part of Λ is from the channel Σo Λ? • How do Σ+ΣoΣ-excitation functions look like? Excitation function of strangeness production in central Au+Au and Pb+Pb collisions. Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Motivation - 2 • Hyperon-hyperon interactions: • to verify various ideas on baryon-baryon interactions such as the flavor SU(3) symmetry • to clarify the properties of dense nuclear matter like neutron stars, in which abundant hyperons are expected to exist • Experimental method – momentum correlations between strange baryons. baryon octet matrix Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Input info and assumptions • CbmRoot package (04.10.2004), Geant3 • 105 UrQMD Au+Au central events at 25 AGeV • TOF: • p, -: ideal tracking and PID, momentum resolution 1%, impact parameter cut b>0.1 cm, cross last 4 STS tracking stations (Zvtx < 40 cm) • ideal Λ p -reconstruction; • ECAL: • : ideal PID, energy resolution 3%/√E, 6%/√E, 9%/√E • n: ideal PID, momentum from ECAL time v=L/t, dp/p = (1+(p/m)2)dL/L, time resolution 0.2, 0.4, 0.6, 0.8 ns dp/p = (1+(p/m)2)dt/t • ideal o   reconstruction Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ- n-: spectra Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ- n-: acceptance Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ- n-: multiplicity Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ- n-: signal Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ- n-: signal+background Σ- n-: signal + background Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ+ po: spectra Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ+ po: acceptance Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ+ po: multiplicity Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ+ po: signal Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σ+ po: signal + background Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σo Λ: spectra Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σo Λ: acceptance Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σo Λ: multiplicity and cuts Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σo Λ: signal Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Σo Λ: signal + background Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Conclusions and next steps • Conclusions: • S/B=0.1 – 0.3 %, needed statistics >107 • Σ-, Σ+, Σo can be reconstructed with ECAL by the event-mixing technique • S/B(Σ+ p o) > S/B(Σ+ n +) • Next steps: • o Λo • More realistic simulations: tracking, PID, reconstruction Workshop of European Research Group on Ultrarelativistic Heavy Ion Physics. Dubna-ITEP S.Kiselev

Feasibility of hyperons study with ECAL

Feasibility of hyperons study with ECAL

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Feasibility Study

Feasibility study

Feasibility Study

Feasibility Study

Feasibility Study

Feasibility Study

Feasibility Study

Feasibility of   γγ study with ECAL

Feasibility Study

Feasibility of   γγ study with ECAL

Feasibility study

Feasibility Study

Feasibility study

Feasibility Study

Feasibility Study

Feasibility study

Feasibility Study

Feasibility Study

Feasibility study

Feasibility Study

Feasibility Study

Feasibility Study