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Numerical Model of an Internal Pellet Target. O. Bezshyyko * , K. Bezshyyko * , A. Dolinskii † ,I. Kadenko * , R. Yermolenko * , V. Ziemann ¶ * Nuclear Physics Department, Taras Shevchenko National University † GSI, 64287, Darmstadt, Germany - PowerPoint PPT Presentation
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Numerical Model of an Internal Pellet Target
Numerical Model of an Internal Pellet Target
O. Bezshyyko*, K. Bezshyyko*, A. Dolinskii†,I. Kadenko*, R. Yermolenko*, V. Ziemann¶
* Nuclear Physics Department, Taras Shevchenko National University†GSI, 64287,Darmstadt, Germany
¶Svedberg Laboratory, Uppsala University, S-75121Uppsala, Sweden
Pellet TargetPellet Target
• Beam of small frozen hydrogen pellets
• Shape of pellet – nearly spheres
• Pellet diameter ~ 30 µm (20 - 70 µm)
• ρH=0.0708 g /cm2
• Mass of 1 pellet ~ 10-9 g (d=30 µm)
• Number of atoms in 1 pellet ~ 5·1014 (d=30 µm)
• Pellet generation rate ~ 50 kHz (20 - 80 kHz)
Pellet TargetPellet Target
• Vertical velocity ~ 50 m/s• Distance between pellets ~ 1
mm (rate 60 kHz, Vv= 50 m/s)• Angle divergence of pellet
beam ~ 0.040
• Distance between injection nozzle and area of beam ~ dozens of cm (real example 241 cm)
• Spread of pellet beam in the point of crossing with antiproton beam ~ ±1 (±1 - ±3)
Pellet beam
Ion beam
Internal target effectsInternal target effects
• Small angle scattering
• Energy loss, energy straggling (relative momentum straggling ∆p/p)
• Moliere theory (with various modifications) – widely used approach
• Main restriction to Moliere theory – number of scatters Ω0≥20
- parameters of Moliere theory,
- critical scattering angle
- atomic electron screening angle
- incident particle charge
- total path length in the scatterer
• Ω02 for pellets with diameter 30 m This value is out of area of Moliere theory application
• 1<Ω0<20 – “Plural Scattering” approach (direct simulation method), used by GEANT toolkit
22
212
2
0
tZb
e inccc
22 , c57721,0
2c2
incZ
t
Coulomb Multiple ScatteringCoulomb Multiple Scattering
Plural Scattering algorithmPlural Scattering algorithm
1. Calculation of scatters number n. Poisson distribution with average
2. Generation of random number - angle of the single scattering
This approximates Rutherford
distribution:
where is a random number uniformly distributed in the interval between 0 and 1
3. Generation of random number (uniformly distributed in the interval between 0
and 2) – to project the scattering angle into the horizontal (or vertical) direction.
4. Calculation of total scattering angle for one hit:
for horizontal direction for vertical direction
n
iii sinˆˆ
0167.1
11ˆ
i
i
2222
)(
2
d
dN
i
n
iii cosˆˆ
Scattering angle distribution for Plural scattering and simple Moliere scatteringRMS scattering angle dependence on diameter of
pellet
Numerical resultsNumerical results
Energy losses and straggling
Energy losses and straggling
Main parameters for choice between theories
1. 2.
- mean energy loss - maximum transferable energy in single collision with an atomic electron
- mean ionization potential of the atom
- the electron mass
- the mass of the incident particle
- charge of the incident particle
- atomic number and weight of the target
- density of the target
- thickness of the target
2
22
max
21
2
x
e
x
e
e
mm
mm
mE
maxE
I
maxEI
KeVxA
ZZ inc ,4.1532
2
em
xm
incZ
AZ ,
x
Area of Gauss distribution
Area of Vavilov distribution5010 and
501001.0 and
5001.0 and
Area of Landau distribution
Pellet target
210 5 and for E=1 GeV, d=30 µm
It is necessary to take into account atomic structure and direct simulation of scattering
Conditions for choice of the modelConditions for choice of the model
Algorithm
1. Calculation of
2. Calculation of ni (Poisson distribution)
3. Calculation of excitation energy loss
4. Calculation of ionisation energy loss
5. Calculation of the total energy loss
6. Calculation of the relative momentum straggling
in
2211 EnEnEex
3
1
max
max1
n
ji
ion
IE
EI
E
ionex EEE
E
E
p
p
1
Urban modelUrban model
ionisationi
levelsenergyofexitationixn ii
3
2,1,
f1+f1=1; f1lnE1+ f2lnE2 =lnI; f1,2 – oscilator strengths
Macroscopic cross-section for exitation (i=1,2):
Macroscopic cross-section for ionisation:
Distribution of ionisation energy loss:
Approximation of g(E) distribution:
is a random number uniformly distributed between 0 and 1
)1()/2ln(
)/2ln(222
222
rImE
Emf
dx
dE
i
iii
r
IIE
IEI
E
dx
dEi
)ln()( maxmax
max
Urban modelUrban model
11
max
max
E
EI
Er
2max
max 1)()(
EE
IIEEg
Subroutine featuresSubroutine features
•Detail 2D (in plane normal to beam axis) geometrical description of particle interaction with pellet is applied
•Spatial distribution of pellet beam in the interaction area is recalculated through spatial and angle distribution at the injection nozzle
•The local (not mean value) thickness of pellet is taken into account
•Main input parameters - x,y,x’,y’, energy of particle, parameters of the pellet beam
•Output data – dp/p (relative momentum straggling ) and (total
scattering angle ) projections into the horizontal and vertical direction
RMS dE distribution Emax dependence on pellet diameter
Numerical test resultsNumerical test results
dp/p dependence on pellet
diameter
Numerical test resultsNumerical test results
ConclusionsConclusions
•Program block for Monte Carlo simulation of the pellet target is developed
•„Plural Scattering“ model for simulation of angle distributions during every turn analysis is used
•Urban model for simulation of energy losses during every turn analysis is used
•Moliere theory and Landau (Vavilov, Gauss) models are preferable only in cases of analysis of target effects after dozens and more turns
•Detailed 2D (in plane normal to beam axis) geometrical description of particle interaction with pellet is applied
•Preliminary numerical results to check the code are obtained, extended tests of code as part of some Monte Carlo codes for analysis of beam parameters are planned in the near future
RMS dE dependence on Ionisation/Excitation ratio
RMS dE dependence on Ionisation/Excitation ratio (log scale)
Ionisation/Excitation ratio, r
Ionisation/Excitation ratio, r
