Spectral fluence response and off-axis corrections for ionization chambers and silicon diodes in small photon fields.

IF 4.2

Zeitschrift fur medizinische Physik Pub Date : 2025-07-21 DOI:10.1016/j.zemedi.2025.06.004

Julian Roers, Florian Katsch, Hans T Eich, Christos Moustakis

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Abstract

Purpose: This study investigates the charged particle fluence response of two reference ionization chambers (PTW T31021 Semiflex 3D and IBA CC04) and two silicon diode detectors (PTW microSilicon and IBA Razor diode) when measuring relative off-axis profiles in medium- to small-sized photon fields. Monte Carlo (MC) simulations are employed to determine the spectral fluence distribution of charged particles at different off-axis positions in water and within the investigated detectors. The goal is to enhance our understanding of the challenges associated with the dosimetry under non-equilibrium conditions and to calculate off-axis correction factors for the detectors under investigation.

Methods: Spectral fluence correction factors p_E,glf were determined using a modified version of the EGSnrc user code egs_chamber. A standard linear accelerator model based on the Elekta Precise was used as beam source with a photon beam quality specifier TPR_20,10 of 0.671. Field sizes as small as 0.5 cm ×0.5 cm were evaluated at a water depth of 10 cm.

Results: The analysis of spectral electron fluence in water as a function of off-axis positions across different field sizes revealed notable spectrum variations, particularly beyond the field edge and in the penumbra. These fluctuations directly impact the energy-dependent fluence response of the detectors. The assessment of p_E,glf at the field edge demonstrated that the volume-averaging effect in air-filled ionization chambers is energy-dependent, with high-energy electron fluences being more strongly disturbed than low-energy fluences. In contrast, silicon diodes reproduced the relative profile within a 2% deviation but exhibited sensitivity to low-energy fluence fluctuations, especially in the penumbra.

Conclusion: The findings highlight the importance of selecting appropriate detectors for relative profile measurements and the necessity of applying detector-specific off-axis correction factors to account for variations in spectral electron fluence response.

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小光子场中电离室和硅二极管的光谱通量响应和离轴校正。

目的：研究了两个参考电离室（PTW T31021 Semiflex 3D和IBA CC04）和两个硅二极管探测器（PTW microSilicon和IBA Razor二极管）在测量中小型光子场中相对离轴轮廓时的电荷通量响应。利用蒙特卡罗（MC）模拟确定了水中不同离轴位置和所研究探测器内带电粒子的光谱通量分布。目的是增强我们对非平衡条件下剂量学相关挑战的理解，并计算正在研究的探测器的离轴校正因子。方法：采用改良版EGSnrc用户代码egs_chamber测定光谱丰度校正因子pE、glf。采用基于Elekta Precise的标准直线加速器模型作为光束源，其光子光束质量指标TPR20,10 = 0.671。在水深为10 cm时，评估了小至0.5 cm ×0.5 cm的场大小。结果：对水中电子的光谱影响作为不同场尺寸离轴位置的函数的分析揭示了显著的光谱变化，特别是在场边缘和半影区。这些波动直接影响探测器的能量依赖影响响应。对电场边缘的pE、glf的评估表明，在充满空气的电离室中，体积平均效应与能量有关，高能电子影响比低能电子影响受到更强烈的干扰。相比之下，硅二极管在2%的偏差范围内再现了相对轮廓，但对低能量影响波动表现出敏感性，特别是在半影区。结论：研究结果强调了选择合适的探测器进行相对剖面测量的重要性，以及应用探测器特异性离轴校正因子来解释光谱电子影响响应变化的必要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Zeitschrift fur medizinische Physik

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