Endothermic Processes in Tissue-Equivalent Plastic

Endothermic Processes in Tissue-Equivalent Plastic

The use of tissue-equivalent plastic as the absorbing element for absolute calorimetric measurement of dose is limited by uncertainties existing in the heat lost by endothermic processes induced in the plastic by the absorbed radiation. Measurements have been conducted to determine experimentally th...

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Veröffentlicht in:Radiat. Res., 37: 316-22(Feb. 1969) 37: 316-22(Feb. 1969), 1969-02, Vol.37 (2), p.316-322
Hauptverfasser: Fleming, D. M., Glass, W. A.
Format: Artikel
Sprache:eng
Schlagworte:
ABSORPTION
Aluminum
Beam currents
CALORIMETERS
Calorimetry
DOSEMETERS
Electric potential
Energy
ERRORS
MOCKUP
Models, Biological
N28420 -Life Sciences-Health Physics & Safety-Dosimetry & Monitoring
PHANTOMS
PHANTOMS/radiation dosimetry in tissue-equivalent plastic, thermal defect in proton
PLASTICS
Plastics - radiation effects
PLASTICS/radiation dosimetry in tissue-equivalent, thermal defect in proton
Proton beams
PROTONS
PROTONS/dosimetry in tissue-equivalent plastic, thermal defect in
Radiation dosage
RADIATION DOSES
RADIATION DOSIMETERS, CALORIMETRIC/errors in tissue-equivalent plastic, proton-induced thermal defect
Radiation Effects
Radiometry
REACTION KINETICS
Temperature gradients
Thermistors
Thermodynamics
TISSUES
VARIATIONS
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Beschreibung
Zusammenfassung:The use of tissue-equivalent plastic as the absorbing element for absolute calorimetric measurement of dose is limited by uncertainties existing in the heat lost by endothermic processes induced in the plastic by the absorbed radiation. Measurements have been conducted to determine experimentally the difference between the absorbed energy and the resulting thermal energy, a thermal defect, for Shonka-type tissue-equivalent plastic when irradiated by monoenergetic protons. Results of this work indicate that the thermal defect varies with total absorbed dose and is nearly twice as great as has been predicted for a similar plastic on the basis of independently determined G values. An extrapolated zero-dose value for the thermal defect was found to be 4.17 ± 0.2%. The thermal defect decreases with accumulated absorbed dose and appears to reach a saturation value of 3.67% for doses above 108 rads.
ISSN:0033-7587
1938-5404
DOI:10.2307/3572735