Is there a way to reduce the lengthy information output I get in example B1 - see example section below

LambdaPrime table from 200 keV to 100 TeV in 61 bins
===== EM models for the G4Region DefaultRegionForTheWorld ======
LivermorePhElectric : Emin= 0 eV Emax= 100 TeV SauterGavrila Fluo
compt: for gamma SubType=13 BuildTable=1
Lambda table from 100 eV to 1 MeV, 7 bins/decade, spline: 1
LambdaPrime table from 1 MeV to 100 TeV in 56 bins
===== EM models for the G4Region DefaultRegionForTheWorld ======
Klein-Nishina : Emin= 0 eV Emax= 100 TeV
conv: for gamma SubType=14 BuildTable=1
Lambda table from 1.022 MeV to 100 TeV, 18 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
BetheHeitler : Emin= 0 eV Emax= 80 GeV ModifiedTsai
BetheHeitlerLPM : Emin= 80 GeV Emax= 100 TeV ModifiedTsai
Rayl: for gamma SubType=11 BuildTable=1
Lambda table from 100 eV to 100 keV, 7 bins/decade, spline: 0
LambdaPrime table from 100 keV to 100 TeV in 63 bins
===== EM models for the G4Region DefaultRegionForTheWorld ======
LivermoreRayleigh : Emin= 0 eV Emax= 100 TeV CullenGenerator
msc: for e- SubType= 10
RangeFactor= 0.04, stepLimType: 1, latDisp: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
UrbanMsc : Emin= 0 eV Emax= 100 MeV Nbins=42 100 eV - 100 MeV
WentzelVIUni : Emin= 100 MeV Emax= 100 TeV Nbins=42 100 MeV - 100 TeV
eIoni: for e- SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
MollerBhabha : Emin= 0 eV Emax= 100 TeV
eBrem: for e- SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
LPM flag: 1 for E > 1 GeV, VertexHighEnergyTh(GeV)= 100000
===== EM models for the G4Region DefaultRegionForTheWorld ======
eBremSB : Emin= 0 eV Emax= 1 GeV ModifiedTsai
eBremLPM : Emin= 1 GeV Emax= 100 TeV ModifiedTsai
CoulombScat: for e-, integral:1 SubType=1 BuildTable=1
Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 100 MeV Emax= 100 TeV
msc: for e+ SubType= 10
RangeFactor= 0.04, stepLimType: 1, latDisp: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
UrbanMsc : Emin= 0 eV Emax= 100 MeV Nbins=42 100 eV - 100 MeV
WentzelVIUni : Emin= 100 MeV Emax= 100 TeV Nbins=42 100 MeV - 100 TeV
eIoni: for e+ SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
MollerBhabha : Emin= 0 eV Emax= 100 TeV
eBrem: for e+ SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
LPM flag: 1 for E > 1 GeV, VertexHighEnergyTh(GeV)= 100000
===== EM models for the G4Region DefaultRegionForTheWorld ======
eBremSB : Emin= 0 eV Emax= 1 GeV ModifiedTsai
eBremLPM : Emin= 1 GeV Emax= 100 TeV ModifiedTsai
annihil: for e+, integral:1 SubType=5 BuildTable=0
===== EM models for the G4Region DefaultRegionForTheWorld ======
eplus2gg : Emin= 0 eV Emax= 100 TeV
CoulombScat: for e+, integral:1 SubType=1 BuildTable=1
Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 100 MeV Emax= 100 TeV
msc: for proton SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for proton SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
Bragg : Emin= 0 eV Emax= 2 MeV
BetheBloch : Emin= 2 MeV Emax= 100 TeV
hBrems: for proton SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for proton SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 17x1001; from 7.50618 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for proton, integral:1 SubType=1 BuildTable=1
Lambda table from threshold to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for GenericIon SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
UrbanMsc : Emin= 0 eV Emax= 100 TeV
ionIoni: for GenericIon SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.02
Stopping Power data for 17 ion/material pairs
===== EM models for the G4Region DefaultRegionForTheWorld ======
BraggIon : Emin= 0 eV Emax= 2 MeV
BetheBloch : Emin= 2 MeV Emax= 100 TeV
msc: for alpha SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
UrbanMsc : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
ionIoni: for alpha SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.02
===== EM models for the G4Region DefaultRegionForTheWorld ======
BraggIon : Emin= 0 eV Emax=7.9452 MeV
BetheBloch : Emin=7.9452 MeV Emax= 100 TeV
msc: for anti_proton SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for anti_proton SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
ICRU73QO : Emin= 0 eV Emax= 2 MeV
BetheBloch : Emin= 2 MeV Emax= 100 TeV
hBrems: for anti_proton SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for anti_proton SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 17x1001; from 7.50618 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for anti_proton, integral:1 SubType=1 BuildTable=1
Lambda table from threshold to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for kaon+ SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for kaon+ SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
Bragg : Emin= 0 eV Emax=1.05231 MeV
BetheBloch : Emin=1.05231 MeV Emax= 100 TeV
hBrems: for kaon+ SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for kaon+ SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 18x1001; from 3.94942 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for kaon+, integral:1 SubType=1 BuildTable=1
Lambda table from threshold to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for kaon- SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for kaon- SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
ICRU73QO : Emin= 0 eV Emax=1.05231 MeV
BetheBloch : Emin=1.05231 MeV Emax= 100 TeV
hBrems: for kaon- SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for kaon- SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 18x1001; from 3.94942 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for kaon-, integral:1 SubType=1 BuildTable=1
Used Lambda table of kaon+
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for mu+ SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0, polarAngLim(deg)= 180
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
muIoni: for mu+ SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
Bragg : Emin= 0 eV Emax= 200 keV
BetheBloch : Emin= 200 keV Emax= 1 GeV
MuBetheBloch : Emin= 1 GeV Emax= 100 TeV
muBrems: for mu+ SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
MuBrem : Emin= 0 eV Emax= 100 TeV
muPairProd: for mu+ SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 21x1001; from 1 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
muPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for mu+, integral:1 SubType=1 BuildTable=1
Lambda table from threshold to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for mu- SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0, polarAngLim(deg)= 180
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
muIoni: for mu- SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
ICRU73QO : Emin= 0 eV Emax= 200 keV
BetheBloch : Emin= 200 keV Emax= 1 GeV
MuBetheBloch : Emin= 1 GeV Emax= 100 TeV
muBrems: for mu- SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
MuBrem : Emin= 0 eV Emax= 100 TeV
muPairProd: for mu- SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 21x1001; from 1 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
muPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for mu-, integral:1 SubType=1 BuildTable=1
Used Lambda table of mu+
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for pi+ SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for pi+ SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
Bragg : Emin= 0 eV Emax=297.505 keV
BetheBloch : Emin=297.505 keV Emax= 100 TeV
hBrems: for pi+ SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for pi+ SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 20x1001; from 1.11656 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for pi+, integral:1 SubType=1 BuildTable=1
Lambda table from threshold to 100 TeV, 7 bins/decade, spline: 1
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV
msc: for pi- SubType= 10
RangeFactor= 0.2, stepLimType: 0, latDisp: 0
===== EM models for the G4Region DefaultRegionForTheWorld ======
WentzelVIUni : Emin= 0 eV Emax= 100 TeV Nbins=84 100 eV - 100 TeV
hIoni: for pi- SubType=2
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
StepFunction=(0.2, 0.1 mm), integ: 1, fluct: 1, linLossLim= 0.01
===== EM models for the G4Region DefaultRegionForTheWorld ======
ICRU73QO : Emin= 0 eV Emax=297.505 keV
BetheBloch : Emin=297.505 keV Emax= 100 TeV
hBrems: for pi- SubType=3
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
===== EM models for the G4Region DefaultRegionForTheWorld ======
hBrem : Emin= 0 eV Emax= 100 TeV
hPairProd: for pi- SubType=4
dE/dx and range tables from 100 eV to 100 TeV in 84 bins
Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
Sampling table 20x1001; from 1.11656 GeV to 100 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
hPairProd : Emin= 0 eV Emax= 100 TeV
CoulombScat: for pi-, integral:1 SubType=1 BuildTable=1
Used Lambda table of pi+
ThetaMin§ < Theta(degree) < 180; pLimit(GeV^1)= 0.139531
===== EM models for the G4Region DefaultRegionForTheWorld ======
eCoulombScattering : Emin= 0 eV Emax= 100 TeV

              HADRONIC PROCESSES SUMMARY (verbose level 1)

                       Hadronic Processes for neutron

Process: hadElastic
Model: hElasticCHIPS: 0 eV —> 100 TeV
Cr_sctns: G4NeutronElasticXS: 0 eV —> 100 TeV

Process: neutronInelastic
Model: FTFP: 3 GeV —> 100 TeV
Model: BertiniCascade: 1 GeV —> 5 GeV
Model: Binary Cascade: 0 eV —> 1.5 GeV
Cr_sctns: G4NeutronInelasticXS: 0 eV —> 100 TeV

Process: nCapture
Model: nRadCapture: 0 eV —> 100 TeV
Cr_sctns: G4NeutronCaptureXS: 0 eV —> 100 TeV

Process: nKiller

                       Hadronic Processes for GenericIon

Process: ionInelastic
Model: Binary Light Ion Cascade: 0 eV /n —> 4 GeV/n
Model: FTFP: 2 GeV/n —> 100 TeV/n
Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: ionElastic
Model: NNDiffuseElastic: 0 eV /n —> 100 TeV/n
Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

                       Hadronic Processes for He3

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100 TeV/n
Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: He3Inelastic
Model: Binary Light Ion Cascade: 0 eV /n —> 4 GeV/n
Model: FTFP: 2 GeV/n —> 100 TeV/n
Cr_sctns: G4ParticleInelasticXS: 0 eV —> 100 TeV

                       Hadronic Processes for alpha

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100 TeV/n
Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: alphaInelastic
Model: Binary Light Ion Cascade: 0 eV /n —> 4 GeV/n
Model: FTFP: 2 GeV/n —> 100 TeV/n
Cr_sctns: G4ParticleInelasticXS: 0 eV —> 100 TeV

                       Hadronic Processes for anti_He3

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100.1 MeV/n
Model: AntiAElastic: 100 MeV/n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_He3Inelastic
Model: FTFP: 0 eV /n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: hFritiofCaptureAtRest

                       Hadronic Processes for anti_alpha

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100.1 MeV/n
Model: AntiAElastic: 100 MeV/n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_alphaInelastic
Model: FTFP: 0 eV /n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: hFritiofCaptureAtRest

                       Hadronic Processes for anti_deuteron

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100.1 MeV/n
Model: AntiAElastic: 100 MeV/n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_deuteronInelastic
Model: FTFP: 0 eV /n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: hFritiofCaptureAtRest

                       Hadronic Processes for anti_neutron

Process: hadElastic
Model: hElasticLHEP: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_neutronInelastic
Model: FTFP: 0 eV —> 100 TeV
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

                       Hadronic Processes for anti_proton

Process: hadElastic
Model: hElasticLHEP: 0 eV —> 100.1 MeV
Model: AntiAElastic: 100 MeV —> 100 TeV
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_protonInelastic
Model: FTFP: 0 eV —> 100 TeV
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: hFritiofCaptureAtRest

                       Hadronic Processes for anti_triton

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100.1 MeV/n
Model: AntiAElastic: 100 MeV/n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: anti_tritonInelastic
Model: FTFP: 0 eV /n —> 100 TeV/n
Cr_sctns: AntiAGlauber: 0 eV —> 100 TeV
Cr_sctns: GheishaInelastic: 0 eV —> 100 TeV

Process: hFritiofCaptureAtRest

                       Hadronic Processes for deuteron

Process: hadElastic
Model: hElasticLHEP: 0 eV /n —> 100 TeV/n
Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV —> 100 TeV
Cr_sctns: GheishaElastic: 0 eV —> 100 TeV

Process: dInelastic
Model: Binary Light Ion Cascade: 0 eV /n —> 4 GeV/n
Model: FTFP: 2 GeV/n —> 100 TeV/n
Cr_sctns: G4ParticleInelasticXS: 0 eV —> 100 TeV

Hello,

you may set verbosity level to zero for EM physics via UI command, and also separately for hadronic physics. However, if you are newcomer better to have this information.

VI

what is the syntax for these 2 commands?

Hello,

/process/em/verbose 0

VI

VI,
Thanks that helped a little but still getting a lot of other output which I’m not thinking is helpful - below are the section headings for many of these output lines.
Is there another setting command to cancel this output?

1.              HADRONIC PROCESSES SUMMARY (verbose level 1)
   

2. ========= Table of registered couples ==============================

There is no corresponding /process/had/verbose command, unfortunately (use “help” from the G4 PreInit> prompt, and you can discover this). The global /process/verbose 0 command should work to turn off all of that dump (it says it applies to the “Process Table”).

Thank mkelsey,
That command helped to remove more of the many verbose output lines!

So far I set the following in the macro files

/gps/verbose 0
/control/verbose 0
/run/verbose 0
/event/verbose 0
/tracking/verbose 0
/process/verbose 0

but still getting quite a bit of output related to the ‘HADRONIC PROCESSES SUMMARY’

Yes, would be very useful to be able to turn off this very lengthy output, especially for beginners. I am trying to understand how my tracking proceeds, and this info is buried under 100’s of lines of non-really-useful-nor-actionable information.

I appreciate any concerns about educating users but handling the output stream makes things very difficult. Besides, what can a novice user do with seeing this 100’s of times ?

muPairProd: for mu- SubType=4
dE/dx and range tables from 100 eV to 100 GeV in 180 bins
Lambda tables from threshold to 100 GeV, 20 bins/decade, spline: 1
Sampling table 9x1001; from 1 GeV to 0.1 TeV
===== EM models for the G4Region DefaultRegionForTheWorld ======
muPairProd : Emin= 0 eV Emax= 100 GeV

Also, I am not finding anywhere in the documentation a self contained explanation on how to control all of this verbosity, for instance /process verbose. Thank you

I have an opposite issue. I would like to see more information, specifically material of the volume (in addition to the volume name) which is being traversed by a particle. Is there a verbose command for this, please?