September 2016 Update: EPA has validated and published a rapid method for sodium hydroxide fusion
of asphalt roofing material matrices for analysis of americium-241, plutonium-238, plutonium-239, radium-
226, strontium-90, uranium-234, uranium-235, and uranium-238. The method is summarized and
accessible through the link provided below.
Rapid Method for Sodium Hydroxide Fusion of Asphalt Roofing Material Matrices Prior to
Americium, Plutonium, Strontium, Radium, and Uranium Analyses
Analyte(s)
CAS RN®
Americium-241
14596-10-2
Plutonium-238
13981-16-3
Plutonium-239
15117-48-3
Radium-226
13982-63-3
Strontium-90
10098-97-2
Uranium-234
13966-29-5
Uranium-235
15117-96-1
Uranium-238
7440-61-1
Analysis Purpose: Qualitative analysis
Technique: Alpha spectrometry
Method Developed for: Americium-241 (241Am), plutonium-238 (238Pu), plutonium-239 (239Pu),
radium-226 (226Ra), strontium-90 (90Sr), uranium-234 (234U), uranium-235 (235U) and uranium-
238 (238U) in asphalt roofing material samples
Method Selected for: SAM will list this method for qualitative analysis of americium-241,
plutonium-238, plutonium-239, radium-226, strontium-90, uranium-234, uranium-235 and
uranium-238 in asphalt shingle matrices (roofing material).
Description of Method: The term "asphalt roofing materials" is used in this procedure to mean
asphalt organic shingles or asphalt fiberglass shingles typically used for residential or
commercial roofs. This roofing material procedure was validated with asphalt fiberglass
shingles. Other roofing types will need to be validated by the laboratory.
Asphalt roofing material samples should be cut into very small pieces prior to taking a
representative aliquant for furnace heating and fusion. The method is based on ashing a 25
gram (g) subsample of asphalt roofing material sample in a furnace to remove organic
components, followed by taking a representative aliquant from the ashed sample. The 1-1.5 g
aliquant of ashed sample is fused using sodium hydroxide fusion at 600 °C. Plutonium,
uranium, and americium are separated from the alkaline matrix using an iron/titanium hydroxide
precipitation (enhanced with calcium phosphate precipitation) followed by a lanthanum fluoride
matrix removal step. Strontium is separated from the alkaline matrix using a phosphate
precipitation, followed by a calcium fluoride precipitation to remove silicates. Radium is
separated from the alkaline matrix using a carbonate precipitation. The method is applicable to
the sodium hydroxide fusion of asphalt shingle samples, prior to the chemical separation
procedures described in the following procedures:
U.S. Environmental Protection Agency
Office of Research and Development, Homeland Security Research Program
EPA 600/S-16/271
September 2016
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• U.S. EPA. Rapid Radiochemical Method for Americium-241 in Building Materials for
Environmental Remediation Following Radiological Incidents (EPA 402-R14-007, April
2014)
• U.S. EPA. Rapid Radiochemical Method for Plutonium-238 and Plutonium-239/240 in
Building Materials for Environmental Remediation Following Radiological Incidents (EPA
402-R14-006, April 2014)
• U.S. EPA. Rapid Radiochemical Method for Radium-226 in Building Materials for
Environmental Remediation Following Radiological Incidents (EPA 402-R14-002, April
2014)
• U.S. EPA. Rapid Radiochemical Method for Total Radiostrontium (Sr-90) in Building
Materials for Environmental Remediation Following Radiological Incidents (EPA 402-R14-
00, April 2014)
• U.S. EPA. Rapid Radiochemical Method for Isotopic Uranium in Building Materials for
Environmental Remediation Following Radiological Incidents (EPA 402-R14-005, April
2014)
Special Considerations: The bitumen components, which can have affinity for the
radionuclides, are destroyed in this method. Radionuclides deposited on the surface of the
asphalt roofing material are effectively digested, including refractory radionuclide particles. A
small amount of mineralized granules might remain after the fusion.
Information regarding the elemental composition of the sample may be helpful. For example,
asphalt roofing materials can have native concentrations of uranium, radium, thorium, stable
strontium, or stable barium, all of which could have an effect on the chemical separations used
following the fusion of the sample. In those samples where native constituents are present that
could interfere with the determination of the chemical yield (e.g., strontium for 90Sr analysis) or
with the creation of a sample test source (e.g., barium for 226Radium analysis by alpha
spectrometry), it might be necessary to determine the concentration of these native constituents
in advance of chemical separation (using a separate aliquant of fused material) and make
appropriate adjustments to the yield calculations or amount of carrier added.
Matrix blanks for these matrices might not be practical to obtain. Efforts should be made to
obtain independent, analyte-free materials that have similar composition as the samples to be
analyzed. These blanks will serve as process monitors for the fusion, and as potential monitors
for cross contamination during batch processing. Uncontaminated asphalt roofing material may
be acceptable blank material for Pu, Am, and Sr analyses, but this material will contain
background levels of naturally occurring U and Ra isotopes.
Re-used zirconium crucibles should be cleaned very well using soap and water, followed by
warm nitric acid, and a final water rinse. Blank measurements should be monitored to ensure
effective cleaning.
Additional information regarding potential interferences and procedures for addressing the
interferences is provided in Section 4 of the method.
Source: U.S. EPA, National Air and Radiation Environmental Laboratory. "Rapid Method for
Sodium Hydroxide Fusion of Asphalt Matrices Prior to Americium, Plutonium, Strontium,
Radium, and Uranium Analyses." EPA 402-R16-003, Revision 0, August 2016.
https://www.epa.gov/radiation/rapid-radiochemical-methods-selected-radionuclides
U.S. Environmental Protection Agency
Office of Research and Development, Homeland Security Research Program
EPA 600/S-16/271
September 2016
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