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ASTM C1726/C1726M-10(2018)

(Guide)

Standard Guide for Use of Modeling for Passive Gamma Measurements

Standard Guide for Use of Modeling for Passive Gamma Measurements

SIGNIFICANCE AND USE
5.1 The following methods assist in demonstrating regulatory compliance in such areas as safeguards (Special Nuclear Material), inventory control, criticality control, decontamination and decommissioning, waste disposal, holdup and shipping.  
5.2 This guide can apply to the assay of radionuclides in containers, whose gamma-ray absorption properties can be measured or estimated, for which representative certified standards are not available. It can be applied to in situ measurements, measurement stations, or to laboratory measurements.  
5.3 Some of the modeling techniques described in the guide are suitable for the measurement of fall-out or natural radioactivity homogenously distributed in soil.  
5.4 Source-based efficiency calibrations for laboratory geometries may suffer from inaccuracies due to gamma rays being detected in true coincidence. Modeling can be an advantage since it is unaffected by true coincidence summing effects.
SCOPE
1.1 This guide addresses the use of models with passive gamma-ray measurement systems. Mathematical models based on physical principles can be used to assist in calibration of gamma-ray measurement systems and in analysis of measurement data. Some nondestructive assay (NDA) measurement programs involve the assay of a wide variety of item geometries and matrix combinations for which the development of physical standards are not practical. In these situations, modeling may provide a cost-effective means of meeting user’s data quality objectives.  
1.2 A scientific knowledge of radiation sources and detectors, calibration procedures, geometry and error analysis is needed for users of this standard. This guide assumes that the user has, at a minimum, a basic understanding of these principles and good NDA practices (see Guide C1592/C1592M), as defined for an NDA professional in Guide C1490. The user of this standard must have at least a basic understanding of the software used for modeling. Instructions or further training on the use of such software is beyond the scope of this standard.  
1.3 The focus of this guide is the use of response models for high-purity germanium (HPGe) detector systems for the passive gamma-ray assay of items. Many of the models described in this guide may also be applied to the use of detectors with different resolutions, such as sodium iodide or lanthanum halide. In such cases, an NDA professional should determine the applicability of sections of this guide to the specific application.  
1.4 Techniques discussed in this guide are applicable to modeling a variety of radioactive material including contaminated fields, walls, containers and process equipment.  
1.5 This guide does not purport to discuss modeling for “infinite plane” in situ measurements. This discussion is best covered in ANSI N42.28.  
1.6 This guide does not purport to address the physical concerns of how to make or set up equipment for in situ measurements but only how to select the model for which the in situ measurement data is analyzed.  
1.7 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard.  
1.8 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

General Information

Status
Published
Publication Date
31-Mar-2018
ICS
17.240 - Radiation measurements
Technical Committee
C26 - Nuclear Fuel Cycle
Drafting Committee
C26.10 - Non Destructive Assay
Current Stage
Ref Project

Relations

Replaces
ASTM C1726/C1726M-10 - Standard Guide for Use of Modeling for Passive Gamma Measurements
Effective Date
01-Apr-2018
Refers
ASTM C1673-10a(2018) - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Apr-2018
Refers
ASTM C1673-10a - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Nov-2010
Refers
ASTM C1673-10ae1 - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Nov-2010
Refers
ASTM C1490-04(2010) - Standard Guide for the Selection, Training and Qualification of Nondestructive Assay (NDA) Personnel
Effective Date
01-Oct-2010
Refers
ASTM C1673-10 - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Jun-2010
Refers
ASTM C1673-07e1 - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Jun-2007
Refers
ASTM C1673-07 - Standard Terminology of C26.10 Nondestructive Assay Methods
Effective Date
01-Jun-2007
Refers
ASTM C1490-04 - Standard Guide for the Selection, Training and Qualification of Nondestructive Assay (NDA) Personnel
Effective Date
01-Feb-2004
Refers
ASTM C1490-01 - Standard Guide for the Selection, Training and Qualification of Nondestructive Assay (NDA) Personnel
Effective Date
10-Jan-2001
Referred By
ASTM C1592/C1592M-21 - Standard Guide for Making Quality Nondestructive Assay Measurements
Effective Date
01-Apr-2018

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ASTM C1726/C1726M-10(2018) - Standard Guide for Use of Modeling for Passive Gamma MeasurementsASTM C1726/C1726M-10(2018) - Standard Guide for Use of Modeling for Passive Gamma Measurements
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ASTM C1726/C1726M-10(2018) - Standard Guide for Use of Modeling for Passive Gamma Measurements
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: C1726/C1726M − 10 (Reapproved 2018)
Standard Guide for
Use of Modeling for Passive Gamma Measurements
This standard is issued under the fixed designation C1726/C1726M; the number immediately following the designation indicates the
year of original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last
reapproval. A superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope 1.6 This guide does not purport to address the physical
concerns of how to make or set up equipment for in situ
1.1 This guide addresses the use of models with passive
measurements but only how to select the model for which the
gamma-ray measurement systems. Mathematical models based
in situ measurement data is analyzed.
on physical principles can be used to assist in calibration of
1.7 The values stated in either SI units or inch-pound units
gamma-ray measurement systems and in analysis of measure-
are to be regarded separately as standard. The values stated in
ment data. Some nondestructive assay (NDA) measurement
programs involve the assay of a wide variety of item geom- each system may not be exact equivalents; therefore, each
system shall be used independently of the other. Combining
etries and matrix combinations for which the development of
physical standards are not practical. In these situations, mod- values from the two systems may result in non-conformance
with the standard.
eling may provide a cost-effective means of meeting user’s
data quality objectives.
1.8 The values stated in inch-pound units are to be regarded
as standard. The values given in parentheses are mathematical
1.2 A scientific knowledge of radiation sources and
conversions to SI units that are provided for information only
detectors, calibration procedures, geometry and error analysis
and are not considered standard.
isneededforusersofthisstandard.Thisguideassumesthatthe
user has, at a minimum, a basic understanding of these
1.9 This international standard was developed in accor-
principles and good NDA practices (see Guide C1592/
dance with internationally recognized principles on standard-
C1592M),asdefinedforanNDAprofessionalinGuideC1490.
ization established in the Decision on Principles for the
The user of this standard must have at least a basic understand-
Development of International Standards, Guides and Recom-
ing of the software used for modeling. Instructions or further
mendations issued by the World Trade Organization Technical
training on the use of such software is beyond the scope of this
Barriers to Trade (TBT) Committee.
standard.
2. Referenced Documents
1.3 The focus of this guide is the use of response models for
2.1 ASTM Standards:
high-purity germanium (HPGe) detector systems for the pas-
C1490 GuidefortheSelection,TrainingandQualificationof
sive gamma-ray assay of items. Many of the models described
Nondestructive Assay (NDA) Personnel
in this guide may also be applied to the use of detectors with
C1592/C1592M Guide for Making Quality Nondestructive
different resolutions, such as sodium iodide or lanthanum
Assay Measurements (Withdrawn 2018)
halide. In such cases, an NDA professional should determine
C1673 Terminology of C26.10 Nondestructive Assay Meth-
the applicability of sections of this guide to the specific
ods
application.
2.2 Other Standard:
1.4 Techniques discussed in this guide are applicable to
ANSI N42.28 Performance Standard for the Calibration of
modeling a variety of radioactive material including contami-
Germanium Detectors for In Situ Gamma-Ray Measure-
nated fields, walls, containers and process equipment.
ments
1.5 This guide does not purport to discuss modeling for
3. Terminology
“infinite plane” in situ measurements. This discussion is best
3.1 See Terminology C1673.
covered in ANSI N42.28.
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
This guide is under the jurisdiction ofASTM Committee C26 on Nuclear Fuel Standards volume information, refer to the standard’s Document Summary page on
Cycle and is the direct responsibility of Subcommittee C26.10 on Non Destructive the ASTM website.
Assay. The last approved version of this historical standard is referenced on
Current edition approved April 1, 2018. Published May 2018. Originally www.astm.org.
approved in 2010. Last previous edition approved in 2010 as C1726/C1726M – 10. Available from American National Standards Institute (ANSI), 25 W. 43rd St.,
DOI: 10.1520/C1726_C1726M-10R18. 4th Floor, New York, NY 10036, http://www.ansi.org.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
C1726/C1726M − 10 (2018)
4. Summary of Guide being detected in true coincidence. Modeling can be an
advantage since it is unaffected by true coincidence summing
4.1 Passive gamma-ray measurements are applied in con-
effects.
junction with modeling to nondestructively quantify radioac-
tivity.
6. Procedure
4.1.1 Modeling may be used to (1) design and plan the
6.1 Modeling may lead to a bias if any of the measurement
measurements, (2) establish instrument calibration, (3) inter-
parameters do not match the physical characteristics of the
pret the data acquired, (4) quantify contributions to the
item.Uncertaintiesintheitemparametersofthefollowingmay
measurementuncertainty, (5)simulatespectra,and (6)evaluate
lead to a bias:
the effectiveness of shielding.
6.1.1 Matrix distribution is homogenous throughout the
4.1.2 Various models commonly use analytical, numerical
container,
integration and radiation transport approaches. This guide
6.1.2 Hidden containers,
provides a brief review of several approaches to help the user
6.1.3 Matrix identification,
select a suitable method and apply that method appropriately.
6.1.4 Container fill heights,
4.1.3 Modeling makes use of knowledge of the measure-
6.1.5 Mass attenuation coefficients,
ment configuration including the shape, dimensions and mate-
6.1.6 Matrix density,
rials of the detector, collimator, and measurement item content.
6.1.7 Detector parameters, and
4.1.4 The exact geometry may be approximated in the
6.1.8 Physical distribution of radioactivity.
model. The degree of approximation acceptable is assessed on
6.2 If the quantity of nuclear material is “infinitely thick” to
a case by case basis.
the emitted gamma rays, measurement results will be biased.
4.1.5 Process knowledge may be required to provide infor-
This hazard is common when measuring items containing large
mation about inner containers, intervening absorbers, matrix
quantities of heavy elements (for example, thorium, uranium,
materials or which radionuclides are present.
or plutonium) or items with highly attenuating matrices.
4.1.6 The models make use of basic physical interaction
Alternate NDAassay methods are recommended if this condi-
coefficients. Libraries and data sets must be available.
tion exists.
4.1.7 Models are typically used to: (1) account for field of
6.3 Self attenuation, commonly present in lumps of actinide
view and geometry effects, (2) account for matrix attenuation,
material, will bias results low unless lump corrections are
(3) account for container wall and other absorbers, (4) model
computed.
detectors, (5) transfer calibrations from one configuration to
6.4 The Generalized Geometry Holdup Method must be
another, (6) bound the range of assay values due to variations
calibrated with the collimator attached to the detector. If the
in modeling representation parameters, (7) iteratively refine
detector recess changes from the calibration position, the
assessments and decision making based on comparisons with
results will be biased.
observations.
6.5 Absorber foils that are used to reduce count rate must be
4.1.8 Scans may be performed using low-resolution, por-
table gamma-ray detectors (for example, NaI) to identify the included in the model.
location of activity and assist with the modeling.
6.6 Attenuation corrections for very thick items may be
4.1.9 Measurement uncertainties are estimated based on
somewhat compromised by coherent scattering, which may not
uncertainties of the assumptions of the model.
be accurately modeled by attenuation calculations.
5. Significance and Use 7. Method Descriptions
Five commonly used methods are described. These include:
5.1 The following methods assist in demonstrating regula-
(1) Generalized Geometry Holdup, (2) Far-field
tory compliance in such areas as safeguards (Special Nuclear
Approximation, (3) Voxel Intrinsic Efficiency, (4) Radiation
Material), inventory control, criticality control, decontamina-
Transport Code, and (5) Hybrid Monte Carlo.
tion and decommissioning, waste disposal, holdup and ship-
7.1 Generalized Geometry Holdup—The method represents
ping.
items as a point, line, or area (1). Three method calibrations
5.2 This guide can apply to the assay of radionuclides in
are obtained from one set of calibration measurements. Point
containers, whose gamma-ray absorption properties can be
sources of the same material as that to be measured are often
measured or estimated, for which representative certified
used for the calibration. Measurements and calibrations are
standards are not available. It can be applied to in situ
made with a collimator attached. Additional attenuation cor-
measurements, measurement stations, or to laboratory mea-
rection factors are needed for a complete analysis.The detector
surements.
calibrations remain the same for all measurements, but attenu-
ation correction factors will vary with the specific measure-
5.3 Some of the modeling techniques described in the guide
ment. Results are typically reported in units of mass.
are suitable for the measurement of fall-out or natural radio-
activity homogenously distributed in soil.
5.4 Source-based efficiency calibrations for laboratory ge-
The boldface numbers in parentheses refer to a list of references at the end of
ometries may suffer from inaccuracies due to gamma rays this standard.
C1726/C1726M − 10 (2018)
7.1.1 Advantages of this method are: 7.1.4 Calibration—Point sources, representative of the
7.1.1.1 The detector efficiency is easily determined; three material, m , being measured, are positioned in off-axis posi-
o
different types of geometry calibrations are performed concur- tions and the peak count rate is determined at each location.
rently. The activity of each location can be used to represent the
7.1.1.2 Any cylindrical collimator could be used. activity/unit area of the area within the concentric ring, a. See
i
7.1.1.3 Typically, only point sources are used. Fig. 1. This information is integrated to obtain calibration
7.1.1.4 Additional geometry corrections do not require use constants for point, line, and area configurations.
of half-life or gamma ray yields.
7.2 Far-field Approximation—This method is used for the
7.1.2 Disadvantages of this method are:
calculation of activity in well-defined geometries (2). The
7.1.2.1 Some holdup items being measured may not have
method assumes that the matrix attenuation correction for the
geometries that simulate points, lines, or areas. However, the
item being measured can be estimated using a far-field matrix
errors introduced by these assumptions are often small com-
correction approximation. Additional correction factors are
pared to other errors.
needed for other types of attenuation and geometry. Templates
7.1.2.2 The model assumes uniform concentration and dis-
may be prepared that match parameters of the items being
tribution of radioactive material. The uncertainties due to these
measured and the positioning of the detector during the
assumptions can be mitigated by taking multiple overlapping
measurement. Geometry and attenuation correction factors are
measurements (subject to time constraints) and judicial mea-
computed from the information supplied by the templates.This
surement placement.
model can be used for many shapes. Usually measurements are
7.1.2.3 The calibration applies only to the exact detector-
made with a collimator to provide detector shielding and
collimator configuration used during the calibration.
directional response.The detector calibration remains the same
7.1.2.4 Special nuclear material licenses may be required
for all measurements, but attenuation and geometry correction
for the calibration sources.
factors will vary with the specific measurement. Results are
7.1.3 Typical applications include uranium and plutonium
reported in activity, concentration, or mass units.
holdup.
7.2.1 Advantages of this method are:
7.2.1.1 The detector efficiency is easily determined.
7.2.1.2 The calibration can be applied to any gamma-
emittingradionuclidewithintheenergyrangeofthecalibration
In a gaseous diffusion plant there are many items that contain holdup and
source and the validity of the correction factors.
cannot be measured as points, lines or areas.Two examples are converters and pipes
7.2.1.3 Models can be constructed for cylinders, boxes,
in pipe galleys. In order to have a large enough standoff for pipes to meet the criteria
for lines, several pipes in the galley are usually within the field-of-view. Converters
point sources, and disc geometries.
are typically measured from outside cell housings, which places the detector several
7.2.1.4 Detector collimation is incorporated in the model
feet away. Because the converters have a large diameter (from 1.2 m to 2.7 m for the
and does not affect the detector calibration.
sizes that can be reliably measured by gamma), pulling back far enough to make
them line sources would place several converters into the field-of-view, and then
7.2.2 Disadvantages of this method are:
they would not be long enough to meet the line source definition. In addition, the
internal structure of converters is too complex to model them as point, line, or area.
FIG. 1 Detector Position for Calibration
C1726/C1726M − 10 (2018)
7.2.2.1 The model does not apply to the analysis of activity obtain that information, a point-source calibration must be
in a non-uniform condition (for example, activity in soil in an performed at a fixed distance from the face of the detector.
exponential distribution).
7.4 Radiation Transport Code Methods—Radiation trans-
7.2.2.2 The calibration does not apply to close-up
port codes typically use the Monte Carlo method to track the
geometries, where the far-fi
...

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5.3 For pure plutonium only product solutions, the KED technique can achieve measurement precisions better than 0.3 % for plutonium concentrations >50 g/L for a typical measurement time of 3 × 1000 s.  
5.4 For pure uranium only solutions, precisions of better than 0.3 % can be achieved using the KED technique for uranium concentrations >50 g/L, for a typical measurement time of 3 × 3600 s.  
5.5 For uranium only or plutonium only solutions of concentrations approximately 1 g/L, assayed using XRF, a measurement precision of 1.0 % has been achieved (1). For solutions of concentration approximately 50 g/L, assayed using XRF, measurement precisions of 0.2 % or better have been achieved. The typical measurement time for stand-alone XRF assay is 3 × 3000 s.  
5.6 Quality Control (QC) samples are assayed for a typical measurement time of 3 × 3000 s.  
5.7 It is applicable when solutions to be measured are homogeneous with respect to chemical composition.  
5.8 Results are typically used for fuel fabrication, process control, quality control, material control and accountancy, and safeguards in nuclear fuel reprocessing plants. Each application can have its own data quality objectives (Guide C1068).  
5.9 The HKED instrument may use a single cylindrical vial for both the KED and XRF measurements, or separate sample containers for KED and XRF. The typical values for the path length of the rectangular cuvette and the inner diameter of the cylindrical vial are given in 7.8.  
5.10 The transfer of the sample into the HKED system can be accomplished either horizontally b...
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1.1 This test method specifies the determination of the volumetric uranium and plutonium concentrations, typically, in nitric acid solutions through the combination of K-Edge absorption Densitometry (KED) and K X-Ray fluorescence (XRF) using an X-Ray generator. It is known as the “Hybrid K-Edge” (HKED) technique whose original implementation is described in Ref (1).2 The method is applicable to dissolver (input) solutions and product solutions. The test method also specifies the determination of low concentrations (  
1.2 This test method is applicable to the following common-use conditions:  
1.2.1 Spent nuclear fuel reprocessing and fuel production.  
1.2.2 Homogeneous aqueous solutions contained in cylindrical vials or cuvettes. HKED systems may use two separate sample containers, namely a rectangular cuvette for KED and a cylindrical vial for XRF. Alternatively, there are HKED systems that use a sample contained in a single cylindrical vial, for both K-Edge and XRF.  
1.2.3 The results produced by the two sample configuration (a rectangular cuvette for K-Edge densitometry and a cylindrical vial for XRF) are compliant with the International Target Values (ITV) (1).  
1.2.4 The precision results produced by the single cylindrical vial configuration are degraded in comparison to the two container system.  
1.2.5 This test method is applicable to facilities that do not adopt the ITVs, but have their own Data Quality Objectives (DQO).  
1.2.6 Solutions which contain uranium and plutonium with uranium concentration of 150 to 250 g/L and a U:Pu ratio of 100:1 typically, in the presence of fission products with β, γ, activity of up to 10 TBq/L.
1.2.6.1 This test method is not applicable to samples where a minor element such as U needs to be quantified in which Pu is the major element.
1.2.6.2 This test method is applicable for common use process control applications for quantifying Pu in the 5 g/L to 30 g/L range ...

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ASTM
ASTM C1673-10a(2018)(Terminology)
Standard Terminology of C26.10 Nondestructive Assay Methods

SCOPE
1.1 The terminology defined in this document is associated with nondestructive assay of nuclear material.  
1.2 All of the definitions are associated with measurement techniques that measure nuclear emissions (that is, neutrons, gamma-rays, or heat) directly or indirectly.  
1.3 Definitions are relevant to any standards and guides written by subcommittee C26.10.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM C1343-16(Test Method)
Standard Test Method for Determination of Low Concentrations of Uranium in Oils and Organic Liquids by X-ray Fluorescence

SIGNIFICANCE AND USE
5.1 This test method is applicable to organic solutions containing 20 to 2000 μg uranium per mL of solution presented to the spectrometer for the solution techniques or 200 to 50 000 μg uranium per g using the fused pellet technique.  
5.2 Either wavelength-dispersive or energy-dispersive XRF systems may be used, provided that the software accompanying the system is able to accommodate the use of internal standards.
SCOPE
1.1 This test method covers the steps necessary for the preparation and analysis by X-ray fluorescence (XRF) of oils and organic solutions containing uranium. Two different preparation techniques are described.  
1.2 The procedure is valid for those solutions containing 20 to 2000 μg uranium per mL as presented to the spectrometer for the solution technique and 200 to 50 000 μg uranium per g for the pellet technique.  
1.3 This test method requires the use of an appropriate internal standard. Care must be taken to ascertain that samples analyzed by this test method do not contain the internal standard or that this contamination, whenever present, has been corrected for mathematically. Such corrections are not addressed in this procedure. Care must be taken that the internal standard and sample medium are compatible; that is, samples must be miscible with tri- n-butyl phosphate (TBP) and must not remove the internal standard from solution. Alternatively, a scatter line may be used as the internal standard.2  
1.4 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Specific precautionary statements are given in Section 9 and Note 2.

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ASTM
ASTM E1894-24(Guide)
Standard Guide for Selecting Dosimetry Systems for Application in Pulsed X-Ray Sources

SIGNIFICANCE AND USE
4.1 Flash X-ray facilities provide intense bremsstrahlung radiation environments, usually in a single sub-microsecond pulse, which often fluctuates in amplitude, shape, and spectrum from shot to shot. Therefore, appropriate dosimetry must be fielded on every exposure to characterize the environment, see ICRU Report 34. These intense bremsstrahlung sources have a variety of applications which include the following:
(1) Studies of the effects of X-rays and gamma rays on materials.
(2) Studies of the effects of radiation on electronic devices such as transistors, diodes, and capacitors.
(3) Computer code validation studies.  
4.2 This guide is written to assist the experimenter in selecting the needed dosimetry systems for use at pulsed X-ray facilities. This guide also provides a brief summary on how to use each of the dosimetry systems. Other guides (see Section 2) provide more detailed information on selected dosimetry systems in radiation environments and should be consulted after an initial decision is made on the appropriate dosimetry system to use. There are many key parameters which describe a flash X-ray source, such as dose, dose rate, spectrum, pulse width, etc., such that typically no single dosimetry system can measure all the parameters simultaneously. However, it is frequently the case that not all key parameters must be measured in a given experiment.
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1.1 This guide provides assistance in selecting and using dosimetry systems in flash X-ray experiments. Both dose and dose rate techniques are described.  
1.2 Operating characteristics of flash X-ray sources are given, with emphasis on the spectrum of the photon output.  
1.3 Assistance is provided to relate the measured dose to the response of a device under test (DUT). The device is assumed to be a semiconductor electronic part or system.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM 51026-23(Practice)
Standard Practice for Using the Fricke Dosimetry System

SIGNIFICANCE AND USE
4.1 The Fricke dosimetry system provides a reliable means for measurement of absorbed dose to water, based on a process of oxidation of ferrous ions to ferric ions in acidic aqueous solution by ionizing radiation (ICRU 80, PIRS-0815, (4)). In situations not requiring traceability to national standards, this system can be used for absolute determination of absorbed dose without calibration, as the radiation chemical yield of ferric ions is well characterized (see Appendix X3).  
4.2 The dosimeter is an air-saturated solution of ferrous sulfate or ferrous ammonium sulfate that indicates absorbed dose by an increase in optical absorbance at a specified wavelength. A temperature-controlled calibrated spectrophotometer is used to measure the absorbance.
SCOPE
1.1 This practice covers the procedures for preparation, testing, and using the acidic aqueous ferrous ammonium sulfate solution dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. The system will be referred to as the Fricke dosimetry system. The Fricke dosimetry system may be used as either a reference standard dosimetry system or a routine dosimetry system.  
1.2 This practice is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the Fricke dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628.  
1.3 The practice describes the spectrophotometric analysis procedures for the Fricke dosimetry system.  
1.4 This practice applies only to gamma radiation, X-radiation (bremsstrahlung), and high-energy electrons.  
1.5 This practice applies provided the following are satisfied:  
1.5.1 The absorbed dose range shall be from 20 Gy to 400 Gy (1).2  
1.5.2 The absorbed dose rate does not exceed 106 Gy·s−1 (2).  
1.5.3 For radioisotope gamma sources, the initial photon energy is greater than 0.6 MeV. For X-radiation (bremsstrahlung), the initial energy of the electrons used to produce the photons is equal to or greater than 2 MeV. For electron beams, the initial electron energy is greater than 8 MeV.  
Note 1: The lower energy limits given are appropriate for a cylindrical dosimeter ampoule of 12 mm diameter. Corrections for displacement effects and dose gradient across the ampoule may be required for electron beams (3). The Fricke dosimetry system may be used at lower energies by employing thinner (in the beam direction) dosimeter containers (see ICRU Report 35).  
1.5.4 The irradiation temperature of the dosimeter should be within the range of 10 °C to 60 °C.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D5928-23(Practice)
Standard Practice for Screening of Waste for Radioactivity

SIGNIFICANCE AND USE
5.1 Most facilities disposing or using waste materials are prohibited from handling wastes that contain radioactive materials. This practice provides the user a rapid method for screening waste material for the presence or absence of radioactivity at user-established levels that consider background radiation and the intended use of the screening method. It is important to these facilities to be able to verify generator-supplied information in regard to radiation and to meet worker health and safety needs.
SCOPE
1.1 This practice covers the screening for α–, β–, and γ radiation above ambient background levels or user-defined criteria, or both, in liquid, sludge, or solid waste materials.  
1.2 This practice is intended to be a gross screening method for determining the presence or absence of radioactive materials in liquid, sludge, or solid waste materials. It is not intended to replace more sophisticated quantitative analytical techniques, but to provide a method for rapidly screening samples for radioactivity above ambient background levels or user-defined criteria, or both, for facilities prohibited from handling radioactive waste.  
1.3 This practice may or may not be suitable for applications such as site assessments and remediation activities, depending on the data quality objectives or intended use.  
1.4 The values stated in SI units are to be regarded as the standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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