Comparison of absorbed-dose-to-water units for Co-60 and high-energy x-rays between PTB and LNE–LNHB

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The LNE-LNHB has developed two primary standards to determine the absorbed dose to water under reference conditions (for 10 cm × 10 cm) in 60 Co, 6 MV, 12 MV and 20 MV photon beams: a new graphite calorimeter and a water calorimeter. This first paper presents the results obtained with the graphite calorimeter and the new associated methodology. The associated relative standard uncertainty (k = 1) of absorbed dose to water is 0.25% for 60 Co and lies between 0.32% to 0.35% for MV x-ray beams.

Section: Methodsmentioning

confidence: 99%

New standards of absorbed dose to water under reference conditions by graphite calorimetry for⁶⁰Co and high-energy x-rays at LNE-LNHB

Delaunay¹,

Gouriou²,

Daures³

et al. 2014

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“…The results show that water and graphite calorimetry can be applied successfully to determine the k Q factors of ionization chambers in small radiation fields. Compared with the k Q factors under reference field size no dependence of the k Q factors on the field size within the standard uncertainties was found for the investigated chambers [25,27]. This indicates that the k Q factors given in the dosimetry protocols can also be used for dosimetry in field sizes down to 2 cm × 2 cm.…”

Section: Project: 'External Beam Cancer Therapy' (Ebct)mentioning

confidence: 79%

“…Using the graphite calorimeter the k Q factors for a 10 cm × 10 cm field size down to a 2 cm × 2 cm size for 6 MV (with and without a flattening filter) and 12 MV photon beams were determined for the PTW31010 and Exradin A1SL chambers. The relative uncertainty achieved with Exradin A1SL is less than 0.4% [27]. The results show that water and graphite calorimetry can be applied successfully to determine the k Q factors of ionization chambers in small radiation fields.…”

Section: Project: 'External Beam Cancer Therapy' (Ebct)mentioning

confidence: 85%

European research projects for metrology in Brachytherapy and External Beam Cancer Therapy

Ankerhold¹,

Toni²

2012

In 2008, within the framework of the European Metrology Research Programme (EMRP), two projects were launched with the central objective of providing reliable measuring techniques for the methods of modern cancer therapy using ionizing radiation—such as brachytherapy, intensity modulated radiation therapy and hadron therapy—and using high intensity therapeutic ultrasound. The two three-year projects are ‘Increasing cancer treatment efficacy using 3D brachytherapy’ (Brachytherapy) and ‘External Beam Cancer Therapy’ (EBCT). For these modern treatment methods there is an urgent requirement for establishing a sound metrological basis with regard to the radiation dose delivered and its spatial distribution. This paper gives a brief overview about the two projects' work, their goals and findings. The details of the projects' work and their outcomes are presented within these conference proceedings or in the cited publications.

“…The product i k i of the corrective factors is mainly for the impurities and the vacuum gaps if the absorbed dose to the graphite was given in a homogeneous graphite material. The new approach [5] is to determine the absorbed dose to water from the mean absorbed dose in the core in the real geometry of the calorimeter, so the correction for vacuum gaps (the main source of uncertainty, evaluated to 0.15%) is taken into account by the graphite-water conversion factor. The benefit to the measurements of the thermal feedback is illustrated in section 4.…”

Section: Quasi-adiabatic Modementioning

confidence: 99%

“…The absorbed dose to water, the quantity of interest, is determined from the value of the absorbed dose to graphite (at a point in a homogeneous phantom [1] or in the core of the calorimeter [5]) with Monte Carlo simulations benchmarked with transfer dosimeters.…”

Section: Introductionmentioning

confidence: 99%

Small section graphite calorimeter (GR-10) at LNE-LNHB for measurements in small beams for IMRT

Daures¹,

Ostrowsky²,

Rapp

2012

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Within the Euramet JRP7 project External Beam Cancer Therapy, a work package was dedicated to the primary standards for IMRT (intensity modulated radiation therapy). The French national metrology laboratory for ionizing radiations, LNE-LNHB, was involved in determining absorbed dose to water based on graphite calorimeters in 6 MV and 12 MV beams for field sizes of 10 cm × 10 cm, 4 cm × 4 cm and 2 cm × 2 cm. The existing GR-09 graphite calorimeter has been successfully used for the beam sizes of 10 cm × 10 cm and 4 cm × 4 cm whereas it was not small enough to perform measurements in the 2 cm × 2 cm beam size. Therefore, during the project a small section graphite calorimeter, GR-10, has been developed. This work deals with the design, construction and tests of this new graphite calorimeter.