BIOMAT Database Logo BIOMAT Database Logo

Monte Carlo calculations of monoenergetic electron depth dose distributions in LiF chips: skin dose correction factors for beta rays. 1994

Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Physics Department. Ben Gurion University of the Negev, Beersheva, Israel.

Monte Carlo calculations have been carried out for monoenergetic electrons from 0.1 to 4 MeV irradiating LiF chips in both perpendicular and isotropic geometry. This enabled the calculation of skin dose correction factors (beta factors) for typical beta energy spectra as measured with a beta-ray spectrometer at CANDU nuclear generating stations. The correction factors were estimated by averaging the depth dose distributions for the monoenergetic electrons over the experimentally measured beta-ray spectra. The calculations illustrate the large uncertainty in beta factors arising from the unknown angular distribution of the beta-ray radiation field and uncertainties in the shape of the beta-ray spectra below 500 keV.

UI MeSH Term Description Entries
D008961 Models, Structural A representation, generally small in scale, to show the structure, construction, or appearance of something. (From Random House Unabridged Dictionary, 2d ed) Model, Structural,Structural Model,Structural Models
D009010 Monte Carlo Method In statistics, a technique for numerically approximating the solution of a mathematical problem by studying the distribution of some random variable, often generated by a computer. The name alludes to the randomness characteristic of the games of chance played at the gambling casinos in Monte Carlo. (From Random House Unabridged Dictionary, 2d ed, 1993) Method, Monte Carlo
D011834 Radiation Monitoring The observation, either continuously or at intervals, of the levels of radiation in a given area, generally for the purpose of assuring that they have not exceeded prescribed amounts or, in case of radiation already present in the area, assuring that the levels have returned to those meeting acceptable safety standards. Monitoring, Radiation
D011839 Radiation, Ionizing ELECTROMAGNETIC RADIATION or particle radiation (high energy ELEMENTARY PARTICLES) capable of directly or indirectly producing IONS in its passage through matter. The wavelengths of ionizing electromagnetic radiation are equal to or smaller than those of short (far) ultraviolet radiation and include gamma and X-rays. Ionizing Radiation,Ionizing Radiations,Radiations, Ionizing
D011874 Radiometry The measurement of radiation by photography, as in x-ray film and film badge, by Geiger-Mueller tube, and by SCINTILLATION COUNTING. Geiger-Mueller Counters,Nuclear Track Detection,Radiation Dosimetry,Dosimetry, Radiation,Geiger Counter,Geiger-Mueller Counter Tube,Geiger-Mueller Probe,Geiger-Mueller Tube,Radiation Counter,Counter Tube, Geiger-Mueller,Counter Tubes, Geiger-Mueller,Counter, Geiger,Counter, Radiation,Counters, Geiger,Counters, Geiger-Mueller,Counters, Radiation,Detection, Nuclear Track,Dosimetries, Radiation,Geiger Counters,Geiger Mueller Counter Tube,Geiger Mueller Counters,Geiger Mueller Probe,Geiger Mueller Tube,Geiger-Mueller Counter Tubes,Geiger-Mueller Probes,Geiger-Mueller Tubes,Probe, Geiger-Mueller,Probes, Geiger-Mueller,Radiation Counters,Radiation Dosimetries,Tube, Geiger-Mueller,Tube, Geiger-Mueller Counter,Tubes, Geiger-Mueller,Tubes, Geiger-Mueller Counter
D005459 Fluorides Inorganic salts of hydrofluoric acid, HF, in which the fluorine atom is in the -1 oxidation state. (McGraw-Hill Dictionary of Scientific and Technical Terms, 4th ed) Sodium and stannous salts are commonly used in dentifrices. Fluoride
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D012867 Skin The outer covering of the body that protects it from the environment. It is composed of the DERMIS and the EPIDERMIS.
D018020 Lithium Compounds Inorganic compounds that contain lithium as an integral part of the molecule. Compounds, Lithium

Related Publications

Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Monte Carlo calculations of the dose backscatter factor for monoenergetic electrons.
January 1999, Physics in medicine and biology,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Calculations of electron fluence correction factors using the Monte Carlo code PENELOPE.
May 2003, Physics in medicine and biology,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Dose distributions of X-rays in water: measurement with TL-dosimeters and comparison with Monte-Carlo calculations.
August 1984, European journal of radiology,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Beta skin dose determination using TLDs, Monte-Carlo calculations, and extrapolation chamber.
December 1989, Health physics,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Monte Carlo study on dose distributions from total skin electron irradiation therapy (TSET).
March 2021, Physics in medicine and biology,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Monte Carlo calculations of correction factors for plane-parallel ionization chambers in clinical electron dosimetry.
September 2008, Medical physics,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
The denoising of Monte Carlo dose distributions using convolution superposition calculations.
September 2007, Physics in medicine and biology,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Monte Carlo calculations of correction factors for plastic phantoms in clinical photon and electron beam dosimetry.
July 2009, Medical physics,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Wall-correction and absorbed-dose conversion factors for Fricke dosimetry: Monte Carlo calculations and measurements.
January 1993, Medical physics,
Y S Horowitz, and C R Hirning, and P Yuen, and P Wong
Monte Carlo calculations of output factors for clinically shaped electron fields.
January 2004, Journal of applied clinical medical physics,
Copied contents to your clipboard!