Monte Carlo study of the depth-dependent fluence perturbation in parallel-plate ionization chambers in electron beams

Czarnecki, D.; Voigts-Rhetz, P. von; Looe, H. K.; Harder, D.

doi:10.1118/1.4897389

Title: Monte Carlo study of the depth-dependent fluence perturbation in parallel-plate ionization chambers in electron beams

Journal Article · Sat Nov 01 00:00:00 EDT 2014 · Medical Physics

DOI:https://doi.org/10.1118/1.4897389· OSTI ID:22320360

Czarnecki, D.; Voigts-Rhetz, P. von ^[1]; Looe, H. K. ^[2]; Harder, D. ^[3]

Institute of Medical Physics and Radiation Protection (IMPS), University of Applied Sciences Giessen, Giessen D-35390 (Germany)
Clinic for Radiation Therapy, Pius-Hospital, Oldenburg D-26129, Germany and WG Medical Radiation Physics, Carl von Ossietzky University, Oldenburg D-26129 (Germany)
Prof. em., Medical Physics and Biophysics, Georg August University, Göttingen D-37073 (Germany)

Purpose: The electron fluence inside a parallel-plate ionization chamber positioned in a water phantom and exposed to a clinical electron beam deviates from the unperturbed fluence in water in absence of the chamber. One reason for the fluence perturbation is the well-known “inscattering effect,” whose physical cause is the lack of electron scattering in the gas-filled cavity. Correction factors determined to correct for this effect have long been recommended. However, more recent Monte Carlo calculations have led to some doubt about the range of validity of these corrections. Therefore, the aim of the present study is to reanalyze the development of the fluence perturbation with depth and to review the function of the guard rings. Methods: Spatially resolved Monte Carlo simulations of the dose profiles within gas-filled cavities with various radii in clinical electron beams have been performed in order to determine the radial variation of the fluence perturbation in a coin-shaped cavity, to study the influences of the radius of the collecting electrode and of the width of the guard ring upon the indicated value of the ionization chamber formed by the cavity, and to investigate the development of the perturbation as a function of the depth in an electron-irradiated phantom. The simulations were performed for a primary electron energy of 6 MeV. Results: The Monte Carlo simulations clearly demonstrated a surprisingly large in- and outward electron transport across the lateral cavity boundary. This results in a strong influence of the depth-dependent development of the electron field in the surrounding medium upon the chamber reading. In the buildup region of the depth-dose curve, the in–out balance of the electron fluence is positive and shows the well-known dose oscillation near the cavity/water boundary. At the depth of the dose maximum the in–out balance is equilibrated, and in the falling part of the depth-dose curve it is negative, as shown here the first time. The influences of both the collecting electrode radius and the width of the guard ring are reflecting the deep radial penetration of the electron transport processes into the gas-filled cavities and the need for appropriate corrections of the chamber reading. New values for these corrections have been established in two forms, one converting the indicated value into the absorbed dose to water in the front plane of the chamber, the other converting it into the absorbed dose to water at the depth of the effective point of measurement of the chamber. In the Appendix, the in–out imbalance of electron transport across the lateral cavity boundary is demonstrated in the approximation of classical small-angle multiple scattering theory. Conclusions: The in–out electron transport imbalance at the lateral boundaries of parallel-plate chambers in electron beams has been studied with Monte Carlo simulation over a range of depth in water, and new correction factors, covering all depths and implementing the effective point of measurement concept, have been developed.

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OSTI ID:: 22320360

Journal Information:: Medical Physics, Vol. 41, Issue 11; Other Information: (c) 2014 American Association of Physicists in Medicine; Country of input: International Atomic Energy Agency (IAEA); ISSN 0094-2405

Country of Publication:: United States

Language:: English

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46 INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY
ABSORBED RADIATION DOSES
COMPUTERIZED SIMULATION
CORRECTIONS
DEPTH DOSE DISTRIBUTIONS
DIAGRAMS
DISTURBANCES
ELECTRODES
ELECTRON BEAMS
FUNCTIONS
IONIZATION CHAMBERS
IRRADIATION
MONTE CARLO METHOD
MULTIPLE SCATTERING
OSCILLATIONS
PERTURBATION THEORY
PHANTOMS
PLATES
SECURITY PERSONNEL
TRANSPORT
WATER

Title: Monte Carlo study of the depth-dependent fluence perturbation in parallel-plate ionization chambers in electron beams

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