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0001 \page Examplemicroprox Example microprox
0002
0003 Author: S. Incerti et al. \n
0004 Date: March 2nd, 2019 \n
0005 Email: incerti@lp2ib.in2p3.fr
0006
0007 (c) The Geant4-DNA collaboration.
0008
0009 This example shows how to compute proximity functions
0010 in liquid water using exclusively Geant4-DNA
0011 physics processes and models.
0012
0013 This example is provided by the Geant4-DNA collaboration.
0014
0015 These processes and models are further described at:
0016 http://geant4-dna.org
0017
0018 Any report or published results obtained using the Geant4-DNA software shall
0019 cite the following Geant4-DNA collaboration publications: \n
0020 J. Appl. Phys. (2019) in press \n
0021 Med. Phys. 51 (2024) 5873–5889 \n
0022 Med. Phys. 45 (2018) e722-e739 \n
0023 Phys. Med. 31 (2015) 861-874 \n
0024 Med. Phys. 37 (2010) 4692-4708 \n
0025 Int. J. Model. Simul. Sci. Comput. 1 (2010) 157–178
0026
0027 ## Geometry
0028
0029 An infinite box of liquid water.
0030
0031 ## Incident particles
0032
0033 Particles can be selected from the microprox.in macro
0034 as well as their incident energy.
0035 They are shot from the center of the box.
0036 Tracking cut can also be selected (as energy).
0037
0038 ## Physics
0039
0040 The default Geant4-DNA physics constructor 2 is used in
0041 the PhysicsList class. Alternative constructor can be
0042 selected from microprox.in
0043
0044 ## Scoring of enery deposition
0045
0046 Energy depositions are scored in spherical shells from randomly selected hits.
0047 The user can select the dimensions of the shells as well as radius steps in TrackerSD.
0048
0049 ## Run
0050
0051 The code can be run using:
0052 ```
0053 ./microprox microprox.in
0054 ```
0055
0056 ## Results
0057
0058 Results can be analyzed after the run using:
0059 ```
0060 root plot.C
0061 ```
0062
0063 The distribution of t is shown by default.
