Development and application of a water calorimeter for the absolute dosimetry of short-range particle beams.

Renaud, James;Rossomme, Séverine;Sarfehnia, Arman;Vynckier, Stefaan;Seuntjens, Jan;et.al.
(2016) Physics in Medicine and Biology — Vol. 61, n° 18, p. 6602-6619 (2016)

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Authors
  • Renaud, James
    Author
  • Rossomme, SéverineUCLouvain
    Author
  • Sarfehnia, Arman
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  • Seuntjens, Jan
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Abstract
In this work, we describe a new design of water calorimeter built to measure absorbed dose in non-standard radiation fields with reference depths in the range of 6-20 mm, and its initial testing in clinical electron and proton beams. A functioning calorimeter prototype with a total water equivalent thickness of less than 30 mm was constructed in-house and used to obtain measurements in clinical accelerator-based 6 MeV and 8 MeV electron beams and cyclotron-based 60 MeV monoenergetic and modulated proton beams. Corrections for the conductive heat transfer due to dose gradients and non-water materials was also accounted for using a commercial finite element method software package. Absorbed dose to water was measured with an associated type A standard uncertainty of approximately 0.4% and 0.2% for the electron and proton beam experiments, respectively. In terms of thermal stability, drifts were on the order of a couple of hundred µK min(-1), with a short-term variation of 5-10 µK. Heat transfer correction factors ranged between 1.021 and 1.049. The overall combined standard uncertainty on the absorbed dose to water was estimated to be 0.6% for the 6 MeV and 8 MeV electron beams, as well as for the 60 MeV monoenergetic protons, and 0.7% for the modulated 60 MeV proton beam. This study establishes the feasibility of developing an absorbed dose transfer standard for short-range clinical electrons and protons and forms the basis for a transportable dose standard for direct calibration of ionization chambers in the user's beam. The largest contributions to the combined standard uncertainty were the positioning (⩽0.5%) and the correction due to conductive heat transfer (⩽0.4%). This is the first time that water calorimetry has been used in such a low energy proton beam.
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Renaud, J., Rossomme, S., Sarfehnia, A., Vynckier, S., Palmans, H., Kacperek, A., & Seuntjens, J. (2016). Development and application of a water calorimeter for the absolute dosimetry of short-range particle beams. Physics in Medicine and Biology, 61(18), 6602-6619. https://doi.org/10.1088/0031-9155/61/18/6602 (Original work published 2016)