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G4NAMU meeting March 6th, 2006 Validation Activities at SLAC of Relevance to Medical Users Koi, Tatsumi SLAC/SCCS.

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Presentation on theme: "G4NAMU meeting March 6th, 2006 Validation Activities at SLAC of Relevance to Medical Users Koi, Tatsumi SLAC/SCCS."— Presentation transcript:

1 G4NAMU meeting March 6th, 2006 Validation Activities at SLAC of Relevance to Medical Users Koi, Tatsumi SLAC/SCCS

2 G4NAMU meeting March 6th, 2006 We regularly check Geant4 performances and provides results for inside and outside users of SLAC. From such our efforts, I pick up several validations which have relations in the medical fields

3 G4NAMU meeting March 6th, 2006 Medical use case validations “Questions for comparison of clinical Monte Carlo codes” (D. W. O. Roger, Author of EGS-NRC) –Speed test –Accuracy test for 18MV photon beam –Accuracy test for 20MeV electron beam

4 G4NAMU meeting March 6th, 2006 Speed of photon & electron calculations Geometry –The phantom is 30.5 cm x 39.5 cm x30 cm deep and filled with 5 mm 3 voxels. –The voxels are to be filled randomly with one of 4 materials (water, aluminum, lung (ICRU, ρ =0.26 g/cm 3 ) and graphite) Incident beams –photon 6 MV spectrum (calculated and given) –Electron 6MeV and 20 MeV –a point source at 100 cm SSD and collimated to 10x10 cm 2 at the phantom surface. Statistical Uncertainties to be achieved –an average relative statistical uncertainty on voxels with a dose greater than Dmax/2 of 0.02 or less.

5 G4NAMU meeting March 6th, 2006 Results geant4 v8.0.p01

6 G4NAMU meeting March 6th, 2006 Accuracy test Photon case Geometry –Similar to the previous, however material and voxel size are different. –From 0 to 3 cm is water, 3 to 5 cm is aluminum, 5 to 12 cm is lung and 12 to 30 cm is water. –The voxels are 5 mm 2 in the x-y directions but only 2 mm deep to increase the resolution. (beams come from z direction) Incident beams –a uniform 18MV beam from a realistic clinical accelerator as calculated at NRC using the BEAM code (given)

7 G4NAMU meeting March 6th, 2006 Standard EM H20H20 Aluminum Lung H20H20

8 G4NAMU meeting March 6th, 2006 Low energy EM PL comes from example/advanced/underground

9 G4NAMU meeting March 6th, 2006 Accuracy test Electron case Geometry –The phantoms are very similar to those for photon beams –From 1 to 2 cm is water, 2 to 3 cm is aluminium, 3 to 6 cm is lung material and 6 to 30 cm is water. Incinde beams –20 MeV mono energetic electrons

10 G4NAMU meeting March 6th, 2006 Standard EM H20H20 H20H20 Aluminum Lung

11 G4NAMU meeting March 6th, 2006 Low energy EM PL comes from example/advanced/underground

12 G4NAMU meeting March 6th, 2006 Standard EM (ExN03PhysicsList) We also tests Low energy EM (DMXPhysicsList)

13 G4NAMU meeting March 6th, 2006 These validations are carried out for each release of Geant4.

14 G4NAMU meeting March 6th, 2006 Nuclear interactions of 160 MeV protons stopping in copper: A test of Monte Carlo nuclear models Bernard Gottschalk, Rachel Platais, and Harald Paganetti pp. 2597-2601 Med. Phys 26-12 (1999) The longitudinal charge distribution left by 160 MeV protons stopping in a multilayer Faraday cup (MLFC) was measured The distribution consists of two regions –build-up region attributable entirely to nuclear interactions –sharp peak attributable entirely to protons stopping by EM interactions

15 G4NAMU meeting March 6th, 2006 Multi Layers Faraday Cups ~160MeV protons Kapton-Cu layers build-up region Hadron Physics Validation sharp peak EM Physics Validation Nuclear interactions of 160 MeV protons stopping in copper: A test of Monte Carlo nuclear models Bernard Gottschalk, Rachel Platais, and Harald Paganetti pp. 2597-2601 Med. Phys 26-12 (1999) Bernard GottschalkRachel PlataisHarald Paganetti

16 G4NAMU meeting March 6th, 2006 Verification of High Precision Neutron models Checking Cross Sections and Final State Products of High Precision Neutron models of Geant4 with Evaluated Nuclear Data File (ENDF) libraries MCNPs depend on ENDF libraries –at least data driven parts of its

17 G4NAMU meeting March 6th, 2006 Verification of High Precision Neutron models Channel Cross Sections 20MeV neutron on Gd157 Ela XS 3.7104216 [barn] Inela XS 1.2508858 Inela XS F01 0.99179298 Inela XS F04 0.18413539 Inela XS F06 0.020973994 Inela XS F10 0.041302787 Inela XS F23 0.009658162 Inela XS F27 0.0030225183 Cap XS 0.0017767842 3.708710+0 [barn] 9.940940E-1 1.836200E-1 2.126800E-2 4.064300E-2 9.717300E-3 3.306100E-3 1.646330E-3 Geant4 resultsENDF data

18 G4NAMU meeting March 6th, 2006 Verification of High Precision Neutron models Energy Spectrum of Secondary Particles

19 G4NAMU meeting March 6th, 2006 Comparison of Computing Speed and Memory consume among deferent implementation of Simple Voxelized Geometries. Geometry: Phantom 30x30x30 cubic cm. Fill this Phantom by 216k voxels which have size of 0.5x0.5x0.5 cubic cm. Incidence particle: 50MeV electron Vertical incidence to a surface of Phantom Uniform incidence to the surface. Implementation of Phantom 1, All voxels are place by G4Placement. (216k voxels) 2, Configured a rod from voxels and placed these rods. (3.6k rods) 3, Configured a disk from rods and placed these disks. (60disks) 4, Using G4VPVParameterisation with kXAxis with kUndefined

20 G4NAMU meeting March 6th, 2006 Results Memory consume 1,47830k 2, 572k 3, 2k 4,42250k with kUndefined 4k with kXAxis Computing Speed 100k electrons incidence 1, 433.99sec 2, 410.69sec 3, 427.97sec 4, 446.85sec with kUndefined 44685 sec with kXAxis (estimated from 1k electrons) Order of magnitude differences appeared in both memory consume and CPU performances. Please take care geometry implementations, even it ’ s a simple voxelized one.

21 G4NAMU meeting March 6th, 2006 Other validation activities at SLAC

22 G4NAMU meeting March 6th, 2006 Hadron interaction validation For all major hadronic physics lists (Ex LHEP, QGSP, FTFP etc) –Gamma, Pion, and Kaon production spectra –Mean multiplicity distributions Gazdzicki, M. and Roehrich D., Z. Phys. C65 215 (1995) Dermer, Apj 307 47-59 (1986) –Charged multiplicity distributions Brick, D. et al., Phys. Rev. D25, 2794 (1982) Adamus, M. et al., Z. Phys. C32 475 (1986) Ammar, R. et al., Phys. Lett. B178, 124-128 (1986)

23 G4NAMU meeting March 6th, 2006 Ion interaction validations Neutron double differential production cross sections –Iwata et al.,Phys. Rev. C64 pp. 05460901(2001) Pion double differential production cross sections –J. Papp, LBL-3633, May 1975. 202pp Neutron Yield from Thick Target –T. Kurosawa et al., Phys. Rev. C62 pp. 04461501 (2000) Fragment particle production cross sections –F. Flesch et al., J, RM, 31, 533, 1999 –F. Flesch et al., J, RM, 34, 237, 2001 –Webber, W. R. et al., Phys. Rev.C: Nucl. Phys., vol. 41, no. 2, Feb. 1990, –V.D.AKSINENKO et al. J, NP/A, 348, 518, 1980 –Bertulani, C. A. and B. Gerhard, Phys. Rep., vol. 163, nos. 5 & 6, June 1988, pp. 299-408. –Westfall, G. D. et al., Phys. Rev. C, vol. 19, no. 4, Apr. 1979,

24 G4NAMU meeting March 6th, 2006 Validation of LC Physics Lists which SLAC provided Geant4 v7.0.p01 147 to 800 GeV p on H

25 G4NAMU meeting March 6th, 2006 QGSP FTFP Geant4 v7.1.p01 Hadronic List PACK 2.5

26 G4NAMU meeting March 6th, 2006 Neutron Production 400 MeV/n Carbon on Copper Pion Production 1 GeV/c/n Carbon on Be, C, Cu and Pn Geant4 6.2.p02 Binary Cascade Light Ions

27 G4NAMU meeting March 6th, 2006 Neutron Yield Fe 400 MeV/n beams CarbonThick TargetAluminum Thick Target T. Kurosawa et al., Phys. Rev. C62 pp. 04461501 (2000)

28 G4NAMU meeting March 6th, 2006 And so on,

29 G4NAMU meeting March 6th, 2006 Summary Several validations which related to medical use cases are already run regularly at SLAC. We have a plan of expansion of validations –Comparison requests with reference of data are welcome.

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