Optimizing non-Pb radiation shielding materials using bilayers

Purpose: The objective of this study was to demonstrate that the weight of non-Pb radiation shielding materials can be minimized by structuring the material as a bilayer composed of different metal-powder-embedded elastomer layers. Methods: Measurements and Monte Carlo (MC) calculations were perform...

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Bibliographic Details
Published in:Medical physics (Lancaster) 2009-12, Vol.36 (12), p.5586-5594
Main Authors: McCaffrey, J. P., Mainegra-Hing, E., Shen, H.
Format: Article
Language:English
Subjects:
ATTENUATION
bilayer
CALIBRATION STANDARDS
DOSIMETRY
Dosimetry/exposure assessment
Elastomeric polymers
elastomers
Emission spectra
KERMA
KEV RANGE 10-100
KEV RANGE 100-1000
LAYERS
Lead
Materials properties
metallic thin films
METALS
Metals - chemistry
Millimeter waves
MONTE CARLO METHOD
Monte Carlo methods
OPTIMIZATION
PROTECTIVE CLOTHING
Radiation monitoring, control, and safety
RADIATION PROTECTION
RADIATION PROTECTION AND DOSIMETRY
radiation shielding
Radiation-Protective Agents - chemistry
shielding
SHIELDING MATERIALS
shielding weight
unleaded protective clothing
X RADIATION
x-ray attenuation
X‐ray effects
X‐ray spectra
X‐rays
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Summary:Purpose: The objective of this study was to demonstrate that the weight of non-Pb radiation shielding materials can be minimized by structuring the material as a bilayer composed of different metal-powder-embedded elastomer layers. Methods: Measurements and Monte Carlo (MC) calculations were performed to study the attenuation properties of several non-Pb metal bilayers over the x-ray energy range 30–150 keV. Metals for the layers were chosen on the basis of low cost, nontoxicity, and complementary photoelectric absorption characteristics. The EGSnrc user code cavity.cpp was used to calculate the resultant x-ray fluence spectra after attenuation by these metal layers. Air kerma attenuation was measured using commercially manufactured metal/elastomer test layers. These layers were irradiated using the primary standard calibration beams at the Institute for National Measurement Standards in Ottawa, Canada utilizing the six x-ray beam qualities recommended in the German Standard DIN 6857. Both the measurements and the calculations were designed to approximate surface irradiation as well as penetrating radiation at 10 mm depth in soft tissue. The MC modeling point and the position of the measurement detector for surface irradiation were both directly against the downstream face of the attenuating material, as recommended in DIN 6857. Results: The low-Z upstream/high-Z downstream ordering of the metal bilayers provided substantially more attenuation than the reverse order. Optimal percentages of each metal in each bilayer were determined for each x-ray radiation beam quality. Conclusions: Depending on the x-ray quality, appropriate choices of two complementary metal-embedded elastomer layers can decrease the weight of radiation shielding garments by up to 25% compared to Pb-based elastomer garments while providing equivalent attenuation.
ISSN:0094-2405
2473-4209
DOI:10.1118/1.3260839