Overview of Ion-Ion validation

1. Overview of Ion-Ion validation KOI, Tatsumi SLAC National Accelerator Laboratory Geant4 Collaboration workshop 2010-10-5

2. Validation of Ion physics • Reaction level validation • Neutron production • (Projectile) Fragment production • Isotope production (Target, Projectile) • Pion production • Often done by developers • Integrated Validation • Thick Target Neutron Yield • Shape of Brag Peak • Rate of Singe Event Upset in Space • Often done by users Geant4 Collaboration workshop 2010-10-5

3. Reaction level validation Geant4 Collaboration workshop 2010-10-5

4. Validations of G4QMD (and BC) • Double Differential Neutron Production Cross Section • Target: Carbon to Lead • Projectile: C12 to Ar40 • Projectile Energy: 290MeV/n to 600 MeV/n • Double Differential Neutron Yield • Target: Carbon to Lead • Projectile: C12 to Xe132 • Projectile Energy: 290MeV/n to 800 MeV/n • Charge Changing Cross Section and Fragment Particle Productions • Comparing simulation results to 131 combinations of projectile and target particles • Target: Carbon to Lead • Projectile: C12 to Fe56 • Projectile Energy: 290MeV/n to 10GeV/n • 98% of the results of charge changing cross sections are within 15% error • 84% of the results of charge changing cross sections are within 10% error

5. Fe 1GeV/n on Al D. M ancusi et al., “Stability of nuclei in peripheral collisions in the JAERI quantum molecular dynamics model” PHYSICAL REVIEW C 79, 014614 (2009) Geant4 Collaboration Workshop 2010-10-7

6. Geant4 Collaboration Workshop 2010-10-7

7. Ion-Ion interactions for space environments Ivantchenko A.

8. Thick Target low energy shielding test • Thick Target Neutron Yield (TTNY); • EXFOR database (CYRIC facility experiment, Tohoku University, Japan); • „Physics list“ test; • Targets Li, Be, C, Al, Ta, W; • Energy 20-70 MeV, 100-400MeV/n; • Reactions (p,n), (d,n), (Ion,n); • Ion-Ion targets 100-400MeV/n* * – very recent settings in the ESA project G4DNA, - this data are different from Tatsumi data reports (D.Satoh, T.Kurosawa, T.Sato, et.al. „Reevalution of secondary neutron spectra from thick targets ...“, Nucl. Instr. Meth. Phys. Res. Sect. A, v.582, 2-3, 507-515)

9. 9.4beta Be(d,n) 25MeV

10. 9.3ref07 Fe56(Al,n) 400MeV

11. 9.3ref07 Ne20(Al,n) 100MeV

12. 9.3ref07 Ne20(Al,n) 400MeV

13. Integrated validation Geant4 Collaboration workshop 2010-10-5

14. Forward Angle Spallation M.A. Clemens et al., IEEE TRANS, VOL. 56, 3158 (2009) Geant4 Space Users Workshop 2010-08-19 Seattle

15. Geant4 Collaboration workshop 2010-10-5

16. Data collection and intercomparison in EC projects Charge changing cross sections in water T.T. Boehlen et al Benchmarking nuclear models of FLUKA and GEANT4 for carbon ion therapy Submitted to Phys. Med. Bio. Paola Sala, SATIF10

17. Validation • Below 100MeV/n • Several validations • Lower limit of QMD ?? • 100 MeV/n ~ 500 MeV/n • Many validation • 500 MeV/n ~ 5 GeV/n • Upper Limit of QMD, BC • A few validations • Data AGS,GSI, DUBNA, MSU • 5 GeV/n ~ 50 GeV/n • FTF • Limited number of validations • Data AGS,DUBNA,SPS • Beyond 50GeV/n • RHIC, LHC? Geant4 Collaboration workshop 2010-10-5

18. Summary • Because of interest from the field of particle therapy, 100MeV/n to 500MeV/n are most validate by both developers and users • Below the 100MeV/n, data exist, but not well validated. Lower limit of QMD is not clear. • Beyond 5GeV/n, Validation against FTF predictions are required. • Compare to two previous presentations, I should admire that organization of this area need to be improve. • So I have a lot of hope for the next presentation. • Are developers making the validation result done by others reflect in future developments? Geant4 Collaboration workshop 2010-10-5