# Use stopping power data from Bethe equation
AT.Mass.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Water, Liquid"),
stopping.power.source = "Bethe")
# Use stopping power data from PSTAR
AT.Mass.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Water, Liquid"),
stopping.power.source = "PSTAR")
# Use stopping power data from ICRU
AT.Mass.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Water, Liquid"),
stopping.power.source = "ICRU")
# Use stopping power data from file shipped with libamtrack
# For water:
AT.Mass.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Water, Liquid"),
stopping.power.source = system.file("extdata",
"FLUKA_DEDX_WATER_76.8eV.txt", package = "libamtrack"))
# And alumina (CAVE: the data file contains stopping power in keV/um, which is
# return, despite the name of the function):
AT.Mass.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Aluminum Oxide"),
stopping.power.source = system.file("extdata",
"FLUKA_DEDX_ALOX.txt", package = "libamtrack"))
# When using density scaling, the value becomes clearily wrong! Thus, do
# preferably use mass stopping power data in the files
AT.Stopping.Power( E.MeV.u = 270.55,
particle.no = 6012,
material.no =
AT.material.no.from.material.name("Aluminum Oxide"),
stopping.power.source = system.file("extdata",
"FLUKA_DEDX_ALOX.txt", package = "libamtrack"))Run the code above in your browser using DataLab