EM physics progress20 January Geant4 Electromagnetic Physics Progress S.Incerti and V.Ivanchenko for Geant4 electromagnetic groups 20 January 2008

EM physics progress 20 January Outline Actions carried out by Geant4 EM groups to address 2007 review recommendations  Low-energy group reorganization  Software infrastructure update  Documentation update Standard EM group  Recent activity  Plan for 2009 and beyond Responses to review recommendations #1-#5 Conclusion remarks

EM physics progress 20 January Low-energy group reorganization S.Incerti was elected as a working group coordinator in spring 2008 Low-energy working group have been reorganized with main goals:  To increase manpower and efficiency of the group  To enable more active participation of experts in low-energy EM projects  To extend capability of the sub-package Details see in the talk of S.Incerti

EM physics progress 20 January Software infrastructure update To provide the most effective usage of Standard and Low-energy EM models a number of improvements have been already introduced in EM software infrastructure  Common interfaces were updated in view of potential combination of standard and low-energy models Physics Lists configuration  Low-energy group started migration to common model based interface in 2008 It is planned to complete in first part of 2009

EM physics progress 20 January Documentation update The electromagnetic web pages have been completely reorganized:  EM Home page easily accessible from G4 web  EM TWiki pages have been created (C.Zacharatou)  Pages are maintained by common efforts of both EM groups

EM physics progress 20 January Electromagnetic (Standard) working group

EM physics progress 20 January Electromagnetic (Standard) working group Exist since beginning of Geant4  Leader for many years - Michel Maire Web: Main focused on LHC Scope of application much wider  Other HEP experiments  Space studies  Medical applications  Instrumental applications

EM physics progress 20 January New physics provided with g4 9.2 Relativistic bremsstrahlung model for E > 1 GeV  Updated density effect Hadron induced bremsstrahlung and e + e - pair production processes/models ICRU’73 data are included and are used for ion ionisation Multiple scattering (MSC) is specialized per particle type:  Optimization CPU versus precision per particle type  G4eMultipleScattering process with MSC model tuned to e- data (L.Urban)  G4MuMultipleScacttering process for muons and hadrons Updated positron annihilation to hadrons (rare high energy process)  added ω(782) and φ(1020) contributions G4Cerenkov process updated G4Scintillation process includes Birks law

EM physics progress 20 January New options and infrastructure components provided with g4 9.2 Spline option for physics tables Option3 Standard Physics builder  Optimized for medical and space applications New utility classes:  G4EmSaturation – Birks effect (used in G4Scintillation) NIEL and gamma interactions  G4ElectronIonPair – helper class to sample of ionisation clusters at charged particle step using ICRU’31 approach  G4EmProcessSubType – enumerator of EM processes  G4EmConfigurator – helper class to configure EM models per energy range and G4Region

EM physics progress 20 January Plan for 2009 Detailed plan is available in the web Selected millstones for 2009  Infrastructure upgrade: Common Standard/Low-energy Physics Lists “ApplyCuts” options per region (kill secondaries below threshold) General ion charge exchange process Cut per recoil  Extend testing suites Add common validation with LE group  Review of bremsstrahlung and photon processes Comparison Standard/Livermore/Penelope models Validation versus data  Further development of ionisation models Review on ionisation potentials Introduce new ICRU’73 model to reference Physics Lists  Further development of single and multiple scattering models

EM physics progress 20 January Outlook beyond – plan for Complete review of EM cross sections and stopping powers  Theory overview  Comparison of various databases data Evaluated data and original publications  Introduce the most precise cross sections in both Standard and Low-energy models Complete single and multiple scattering model review  Optimize configuration of models per particle type and use-case Extend upper applicability limits by including ultra-relativistic models  Radiative corrections, LPM effect X-ray production models and optical models development Polarization model development Providing Physics Lists components per use-case

EM physics progress 20 January Resources available 15 members of the working group Geant4 members  4 associates – model developers Total manpower 2008 – 6 FTE (highest value) Estimated manpower 2009 – 5.5 FTE  Experts of underlying theories (in particular QED) – 5 (1.9 FTE)  Model developers – 5 (2.75 FTE)  Only validation so far – 5 (0.85 FTE) Major support of group members by HEP institutions:  CERN, DESY Zeuthen, KEK, LAPP IN2P3, Lebedev Physics Institute, TRIUMF We need:  Keep expertise in theory and modeling  Extend expertise for new physics models  Increase validation efforts Collaboration with other Geant4 groups (Low-energy, Geometry ….)

EM physics progress 20 January Responses to review recommendations

EM physics progress 20 January Recommendation 1 We recommend setting up an easily accessible central repository with detailed references to data comparisons and validation papers for the models, e.g. a web page linked from the EM home page Geant4 response:  Central repository – main EM TWiki page  Includes link to the TWiki EM publication page Links to all available publications of Geant4 concerning EM physics Links to user publications  Includes links to different validation sub-pages Most important validation results EM tests, validation and verification  Web pages are maintained by common efforts of both EM groups

EM physics progress 20 January Recommendation 2 We recommend rapid integration of the ICRU 73 heavy ion stopping power model Geant4 response:  During 2008 ICRU’73 data were converted to C++ code and included in G4 material sub-package Data can be used in concrete models and for validation  The new model for simulation of ion ionisation fully based on ICRU’73 data have been developed by A. Lechner and released with g Validation is in progress. Complete validation and usage in referenced Physics Lists will be provided in 2009

EM physics progress 20 January A.Lechner, V.Ivanchenko, (Poster at IEEE NSS 2008) New model was compared with existing G4 model  Validations have been done for stopping powers and Bragg peak simulation  New model show good robustness The difference between SRIM, MSTAR, ICRU’73 models was confirmed

EM physics progress 20 January Recommendation 3 We recommend providing guidance on the tradeoffs between physics accuracy and computing speed. For example, collect and publish via the web results from users in various domains regarding computing speed vs range cut, and provide a Wiki-like forum where users can document their experience; etc Geant4 response:  Corresponding documentation is provided and is progressively updated with EM web pages  With g4 9.2 different EM Physics Lists are provided variants of EM physics configurations Reference Physics Lists Extended and advance examples.  The trade off is discussed in Geant4 publications, conference presentations, tutorials, HyperNews Forum, and user publications  Permanent efforts Is a part of the Geant4 working plan

EM physics progress 20 January LHCb type sampling calorimeter: example of tradeoff accuracy versus CPU Accuracy of visible energy depends on cut EMV Physics List underestimates visible energy Optimal working point

EM physics progress 20 January Recommendation 4 We recommend providing guidance on the choice between the two EM models for specific particle species, energies, etc Geant4 response:  Corresponding documentation is provided and is progressively updated in Geant4 web  Common interface for both sub-packages allows more effective way of combining and validation of different EM models 2008: start the migration to the common model-type interface for EM 2009 working plan:  Comparisons of Standard, Livermore and Penelope models  Documentation of possible choice

EM physics progress 20 January Example: Gamma conversion Standard and low-energy models are nearly identical Compton scattering and photo-electric effects are not identical (see talk of S.Incerti) As a result of validation and comparison several choices of EM physics will be provided Escape test

EM physics progress 20 January Recommendation 5 We recommend integrating the two EM models into a single package, similar to what exists in hadronic models. This will allow a user to choose one model in one energy range and the other model in a different energy range in order to optimize physics and computing performance for his application Geant4 response:  Ongoing convergence of the EM physics Existing model interface was agreed (and revised slightly)  Different models of the same process may be configured per particle type, per energy range and geometry region Unification of four EM models (Standard, Livermore, Penelope and DNA)  Low-energy photon processes were migrated to the new interface for g4 9.2  New ion ionization model was created using common interface  Plans for 2009 and beyond: Remaining processes/models (Livermore, Penelope, DNA) migration Validation of migrated processes

EM physics progress 20 January Conclusion remarks The recommendations #1-#5 are in a good part implemented  There is a plan for 2009 and beyond for completion  The speed of implementation depends on available manpower Some further details concerning implementations of the recommendations are in next talks