Transcript About Fluka

FLUKA simulations for particle
emission in Au-Au collisions at
FAIR GSI energies
Alexandru JIPA, Ionel LAZANU, Marius CĂLIN, Tiberiu EŞANU,
Adrian SCURTU, Adam JINARU, Cornel BADEA, Remus PĂUN
Atomic and Nuclear Physics Chair, Faculty of Physics,
University of Bucharest, Romania,
FAIR = Facility for Antiproton and Ion Research
FAIR = Facility for Antiproton and Ion Research
FLUKA Simulation Code
• FLUKA is a Particle Physics Monte Carlo
simulation code, written entirely in FORTRAN,
used here to calculate the ambient dose and
absorbed dose in the CBM cave.
• Other usage: proton and electron accelerator
shielding, target design, calorimetry, activation,
detector design, cosmic rays, neutrino physics,
radiotherapy, Accelerator Driven Systems
• FLUKA – complex code; can be used introducing
simple cards explained in the Fluka manual.
General presentation
of the FLUKA code
• Physical information is tailored to specific usage by a set
of FORTRAN routines. We use here the fluscw.f and
comscw.f routines, called the USERWEIG card to
amplify some chosen scored quantities (fluencies and
deposited energy) by certain coefficients (we obtain thus
ambient dose, respectively, absorbed dose).
• iFluka it’s an adapted GSI version of FLUKA, which
already embodies the two routines and many more, plus
the CBM geometry, being thus a good interface between
C++ and FairRoot system. We used it to run the
considered examples on the GSI machines and detectors.
• For describing the nucleus-nucleus interactions, FLUKA
code uses the Dual Parton Model (DPM) for energies
greater than 5 GeV/nucleon, the Relativistic Quantum
Molecular Dynamics (RQMD) for energies between 0.1
GeV/nucleon and 5 GeV/nucleon
• For energies lower than 0.1 GeV/nucleon, in the FLUKA
code the Boltzmann Master Equation (BME) theory must
be introduced (after 2005 versions of the code)
Absorbed and ambient doses
• Absorbed dose = The energy lost by ionizing radiation per
unit mass of irradiated material ([Dabs] = 1Gy)
• Ambient dose = the dose equivalent which would be
generated in the associated oriented and expanded
radiation field at a depth of 10 mm on the radius of the
ICRU sphere (30 cm diameter tissue equivalent) which is
oriented opposite to the direction of the incident energy
• Effective dose = f(equivalent dose, weight factor for
different tissues)
• Equivalent dose =g(average absorbed dose in a given
tissue, for a given radiation, weight factor for the
radiation in selected tissue)
Deq.f routine in FLUKA
– 3 irradiation geometries, namely: Anterior-Posterior (AP),
Irradiation Rotational (IR), WORST (WT)= Working Out Radiation Shielding
Thickness
- Coefficients – ICRP74, M.Pellicioni
- DT,R – phantom in FLUKA
- 2 sets of coefficients – there are some differences (up tp 2-3 times)
- uses spline fits to coefficients
- 2 routines – fluscw, comscw
- selection of the weight factors and conversion coefficients for E > Emax and E < Emin
- particle included – protons, antiprotons, electrons, positrons, neutron, antineutrons,
photons, charged muons, charged, pions, charged kaons, , lambda, charged sigma
Calculations – for Au-Au at 15A GeV
Conclusions – results similar with those obtained by the other members of the
collaborations (Problems of the Atomic Science and Technology 5(2007)52-56 (Nuclear
Physics Investigation Series)
References
• Stefan Roesler and Graham R. Stevenson - deq99.f - A
FLUKA user-routine converting fluence into effective dose
and ambient dose equivalent
• www.fluka.org
• http://lxmi.mi.infn.it/~battist/DoseCoeff/node2.html
• http://www.gsi.de/documents/DOC-2008-Mar-48_e.html
CBM Experimental set-up
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High rate, large acceptance detector system
Excellent particle identification
High-resolution tracking in a compact dipol field right after the target (Silicon)
Flexible arragement of PID detectors and calorimeters
High bandwidth DAQ with high level event selection
CBM Experiment physical goals
• Deconfinement phase transition at high B
– excitation function and flow
of strangeness (K, , , , )
– excitation function and flow
of charm (J/ψ, ψ', D0, D, c)
– melting of J/ψ and ψ'
• QCD critical endpoint
– excitation function of
event-by-event fluctuations (K/π,...)
• The equation-of-state at high B
– collective flow of hadrons
– particle production at threshold energies (open charm?)
• Onset of chiral symmetry restoration at high B
– in-medium modifications of hadrons (,, e+e-(μ+μ-), D)
Particle multiplicities obtained with
FLUKA Simulation code
Positive pions – 1005
Negative pions – 1130 (1,12)
Positive kaons – 84
Negative kaons – 48 (0,57)
Protons - 1153
Antiprotons – 286 (0,25)
Beam energy lost – 43,0% hadrons and muons; 44,8% electromagnetic radiations;
1,8% nuclear recoils and heavy fragments; 1,00% low energy neutrons, 1,6% particles
Non-included in the code lists, 8,8% - other processes
Experimental results:
 Freeze-out curve (T, μB)
 Tfo = 1614 MeV at (μB=0)
 new state of matter = perfect liquid?
L-QCD Predictions:
 TC = 151 ± 7 ± 4 MeV
 TC = 192 ± 7 ± 4 MeV
 crossover transition at μB=0
 1. order phase transition
with critical endpoint at μB > 0