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Simulation of Neutron Backgrounds in the ILC Extraction Line Beam Dump

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Presentation on theme: "Simulation of Neutron Backgrounds in the ILC Extraction Line Beam Dump"— Presentation transcript:

1 Simulation of Neutron Backgrounds in the ILC Extraction Line Beam Dump
Siva Darbha University of Toronto SLAC, ILC BDS Supervisors: Lewis Keller and Takashi Maruyama Thursday, August 16, 2007 SULI Presentation

2 The International Linear Collider (ILC)
500 GeV center of mass energy Precision measurements Clean signal to noise ratio Thursday, August 16, 2007 SULI Presentation

3 Extraction Line and Water Dump
x (cm) Concrete Collimator Most n are directed forward n 40 cm e+ A e- e- 250 GeV A’ H2O Concrete Tunnel FLUKA was used for all simulations, ROOT for analysis and some particle generation z (cm) Thursday, August 16, 2007 SULI Presentation

4 Fluence at IP x (cm) Tunnel Wall At A-A’ (on the surface of the dump) Flux was treated as isotropic from -1 < cosθ < -0.99 Flux for 1.5 cm radius scoring plane at z=0 was found from flux in 2 m radius scoring plane Quadrupole aperture y (cm) Scoring plane at z=0 Thursday, August 16, 2007 SULI Presentation

5 Particle Biasing Three types of biasing were used: γ A → n + X
Leading particle biasing simulating a full EM shower requires long CPU time to save time, take only the most energetic secondary and remove all others applied to e+,e-, and γ’s < 2.5 GeV Photonuclear interaction length #n produced proportional to lσ σ was increased by a factor of 50 ‘weight’ associated with each n produced from this was decreased by a factor of 50 to compensate γ A → n + X (σ, l) Thursday, August 16, 2007 SULI Presentation

6 Particle Biasing (continued)
Splitting/Russian roulette Dump divided into 10 regions Each region given a factor of 2 larger importance As e+, e-, or γ crosses a boundary, their number is increased or decreased on average by the ratio of importances on either side of the boundary ‘weight’ is adjusted accordingly x (cm) e- 8 4 2 1 z (cm) Thursday, August 16, 2007 SULI Presentation

7 Cutoffs Production Transport e+, e- > 50 MeV photons > 10 keV
neutrons > 10 keV (group number < 48) Thursday, August 16, 2007 SULI Presentation

8 Computation Time 6000 incident e- n total ‘weight’ n total number
Run # Type of Bias CPU time At z=300m At z=0 1 None 23 h 35 min 82 2 LPB 1 h 36 min 103. 87 3 Interaction length 6 h 46 min 0.781 5008 49 4 Splitting/RR 6 h 22 min 96.4 1.09 16619 117 Thursday, August 16, 2007 SULI Presentation

9 Fluence at IP n’s/cm2/year at IP (z=0) Mean (10 runs) RMS
No tunnel or collimator 8.33*1010 1.50*1010 Collimator 3.73*1010 3.34*1010 Tunnel and Collimator 3.65*1010 2.34*1010 1010 n/cm2 at the VXD would cause displacement damage to CCD Si detectors However, not all neutrons that reach the IP will hit the inner detector Thursday, August 16, 2007 SULI Presentation

10 Neutron Energy Distribution
Information was gathered on the neutron distribution in the backward direction and was used to generate 106 neutrons to study the real flux at the VXD 10 MeV bins In first 10 MeV bin Thursday, August 16, 2007 SULI Presentation

11 Detector x (cm) All n’s were given a 7 mrad trajectory towards the detector C 2.4 cm quadrupole 2.4 cm 7 mrad n 3.0 cm C’ Be Si VXD W BeamCal Thursday, August 16, 2007 SULI Presentation z (cm)

12 Initial position of n’s
n’s randomly and uniformly distributed within the quadrupole bore C-C’ Thursday, August 16, 2007 SULI Presentation

13 CCD Si VXD with Be beampipe
x (cm) x (cm) B-B’ A’ z (cm) B’ A-A’ y (cm) Thursday, August 16, 2007 SULI Presentation

14 Results: Fluence at VXD
The BeamCal acts as a collimator for neutron backscattering from dump No BeamCal W BeamCal Black BeamCal With the W BeamCal, the nominal fluence at Layer 1 of VXD is: 4.28*108 n/cm2/year Thursday, August 16, 2007 SULI Presentation

15 1 MeV Neutron Equivalent Fluence
However, the amount of displacement damage done to CCD Si detector by neutrons is a function of neutron energy When relative damage to Si is considered, normalized to 1 MeV, the fluence is: 9.27*108 n/cm2/year When e+ beam is considered also, value is doubled to 1.85*109 n/cm2/year A value of 1010 n/cm2 would damage the CCD Si detector by this measure 1 MeV Thursday, August 16, 2007 SULI Presentation T. M. Flanders and M. H. Sparks, “Monte Carlo calculations of the neutron environment produced by the White Sands Missile Range Fast Burst Reactor,” Nuclear Science and Engineering, vol. 103, pp. 265 – 275, 1989.

16 BeamCal Radius Dependence
Values are not normalized to 1 MeV fluence Values should be doubled to incorporate positron beam Thursday, August 16, 2007 SULI Presentation

17 Acknowledgements Takashi Maruyama and Lewis Keller Tom Markiewicz
Nan Phinney Mario Santana Nicholas Arias SLAC ILC BDS Group DOE, Office of Science Thursday, August 16, 2007 SULI Presentation


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