2022
DOI: 10.1088/1361-6560/ac783c
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Investigating the lateral dose response functions of point detectors in proton beams

Abstract: Objective Point detector measurements in proton fields are perturbed by the volume effect originating from geometrical volume-averaging within the extended detector’s sensitive volume and density perturbations by non-water equivalent detector components. Detector specific lateral dose response functions K(x) can be used to characterize the volume effect within the framework of a mathematical convolution model, where K(x) is the convolution kernel transforming the true dose profile D(x) into the measured signal… Show more

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Cited by 3 publications
(15 citation statements)
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“…The one-dimensional K(x) for three ionization chambers: a Semiflex 3D 31021 and a PinPoint 3D 31022 (PTW Freiburg, Germany), and a CC01G Razor chamber (IBA Dosimetry, Schwarzenbruck, Germany), a microSilicon diode 60023 and a microDiamond detector 60019 (PTW Freiburg, Germany) have been previously reported in Kretschmer et al 14 for the axial orientation, that is, the detector's axis is parallel to the beam's axis. Additionally, Monte Carlo simulations in GATE9.0/Geant4.10.06.p03 38,39 were performed in this work according to the methods reported in Kretschmer et al 14 to determine K(x) for an Advanced Markus 34045 ionization chamber (PTW Freiburg, Germany) not included in the previous work. These functions derived using a narrow slit beam geometry are also referred to as the line spread function.…”
Section: Derivation Of Two-dimensional Lateral Dose Response Function...mentioning
confidence: 75%
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“…The one-dimensional K(x) for three ionization chambers: a Semiflex 3D 31021 and a PinPoint 3D 31022 (PTW Freiburg, Germany), and a CC01G Razor chamber (IBA Dosimetry, Schwarzenbruck, Germany), a microSilicon diode 60023 and a microDiamond detector 60019 (PTW Freiburg, Germany) have been previously reported in Kretschmer et al 14 for the axial orientation, that is, the detector's axis is parallel to the beam's axis. Additionally, Monte Carlo simulations in GATE9.0/Geant4.10.06.p03 38,39 were performed in this work according to the methods reported in Kretschmer et al 14 to determine K(x) for an Advanced Markus 34045 ionization chamber (PTW Freiburg, Germany) not included in the previous work. These functions derived using a narrow slit beam geometry are also referred to as the line spread function.…”
Section: Derivation Of Two-dimensional Lateral Dose Response Function...mentioning
confidence: 75%
“…Figure 1 shows the rotational symmetrical K(r) for the six point detectors derived from the corresponding K(x) determined experimentally in Kretschmer et al 14 or simulated in this work (Advanced Markus chamber). The width of K(r) increases with increasing diameter of the sensitive volume such that the Advanced Markus chamber has the broadest function, while the K(r) of the smallest microSilicon diode is the narrowest among the investigated detectors.…”
Section: Two-dimensional Lateral Dose Response Functionsmentioning
confidence: 95%
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