Dataset for "Regolith-Based Lunar Habitat for Astronaut Radiation Protection and Organ Dose Assessment"

organsInfo.csv File grouping ICRP 145 organs to match ICRP 116 definitions corresponding to tissue weighting factors. organId: ID of organ in Geant4 organ/tissue: name of organ vol[cm3]: volume of organ d[g/cm3]: density of organ mass[g]: mass of organ group: group the organ belongs to WT: weighting tissue of the group N_organs: number of organs within the group wT: weighting tissue of the organ (wT=WT/N_organs) wT_all: defined for remainder organs that summarize data from several groups, all other organs satisfy wt=wt_all gcr_2020-02-01_2021-02-01.csv: GCR data from BON2020 used for the study (https://doi.org/10.1029/2020SW002456) Energies are given in MeV/n Fluxes are given in 1/(m^2.s.sr.(MeV/n)) weightParticles.csv: Abundance of particles according to BON2020 during the period used (calculated from gcr_2020-02-01_2021-02-01.csv) Iparticle: ion name Z: charge of ion wP: integrated flux of particles over energies (m^-2.s^-1.sr^-1) number_sim_particles.csv: column 1: scenario simulated, Icru Sphere of ICRP145 Human Phantom at different thicknesses column 2-29: Number of simulated particle for the corresponding charge (title of column is Z). Icrudose.csv:  Absorbed doses and Dose equivalent per primary ion. thick: thickness of regolith for the habitat in cm (density=1.5 g/cm3) ipart: name of primary ion iN: total number of simulated ion DE: Dose equivalent in corresponding tissue DE_low_std: low asymmetric standard deviation of DE DE_up_std: up asymmetric standard deviation of DE Dose: Absorbed dose in corresponding tissue Dose_low_std: low asymmetric standard deviation of Dose Dose_up_std: up asymmetric standard deviation of Dose ICRPdose.csv:  Absorbed doses and Dose equivalent in the ICRP 145 female human phantom per organ per primary ion. thick: thickness of regolith for the habitat in cm (density=1.5 g/cm3) mass[g]: mass of the organ in grams wT: weighting tissue factor according to ICRP116 (values are divided between all organs belonging to the corresponding group) ipart: name of primary ion iN: total number of simulated ion DE: Dose equivalent in corresponding tissue DE_low_std: low asymmetric standard deviation of DE DE_up_std: up asymmetric standard deviation of DE Dose: Absorbed dose in corresponding tissue Dose_low_std: low asymmetric standard deviation of Dose Dose_up_std: up asymmetric standard deviation of Dose ICRP145_flux.csv:  Particle count crossing the inner surface of the dome. Iparticle: name of primary Oparticle: particle penetrating the dome okE: energy bin of particle penetrating the dome (values from 1 to 200 distributing energies between 10^-6 to 10^6.8 MeV in log10 scale) thick: thickness of regolith for the habitat in cm (density=1.5 g/cm3) Z: charge of primary count: number of particles of type Oparticle in bin okE counted overall simulations divided by number of simulated ions of kind Iparticle in the specific (human phantom, thickness) scenario EDE_matthiae.csv Dose equivalent values taken from https://doi.org/10.1029/2024SW004095 converted in csv. thick(g/cm2): thickness of regolith (0.5 of polycarbonate are included by default.) EDE: Dose equivalent values for the respective thickness std: standard deviation of EDE DE_Dobynde.csv Dose equivalents taken from https://doi.org/10.1029/2021JE006930 for 1 g/cm2 of Aluminum. depth: depth of the human phantom in cm (conversion to areal thickness should take into account the values of density given in https://doi.org/10.1029/2021JE006930) DE: Computed dose equivalents