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ASTM E1249-15(2021)

(Practice)

Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 Sources

Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 Sources

SIGNIFICANCE AND USE
4.1 Division of the Co-60 Hardness Testing into Five Parts:  
4.1.1 The equilibrium absorbed dose shall be measured with a dosimeter, such as a TLD, located adjacent to the device under test. Alternatively, a dosimeter may be irradiated in the position of the device before or after irradiation of the device.  
4.1.2 This absorbed dose measured by the dosimeter shall be converted to the equilibrium absorbed dose in the material of interest within the critical region within the device under test, for example the SiO2 gate oxide of an MOS device.  
4.1.3 A correction for absorbed-dose enhancement effects shall be considered. This correction is dependent upon the photon energy that strikes the device under test.  
4.1.4 A correlation should be made between the absorbed dose in the critical region (for example, the gate oxide mentioned in 4.1.2) and some electrically important effect (such as charge trapped at the Si/SiO2 interface as manifested by a shift in threshold voltage).  
4.1.5 An extrapolation should then be made from the results of the test to the results that would be expected for the device under test under actual operating conditions.
Note 5: The parts of a test discussed in 4.1.2 and 4.1.3 are the subject of this practice. The subject of 4.1.1 is covered and referenced in other standards such as Practice E668 and ICRU Report 14. The parts of a test discussed in 4.1.4 and 4.1.5 are outside the scope of this practice.  
4.2 Low-Energy Components in the Spectrum—Some of the primary Co-60 gamma rays (1.17 and 1.33 MeV) produce lower energy photons by Compton scattering within the Co-60 source structure, within materials that lie between the source and the device under test, and within materials that lie beyond the device but contribute to backscattering. As a result of the complexity of these effects, the photon energy spectrum striking the device usually is not well known. This point is further discussed in Section 5 and Appendix X1. The presence of ...
SCOPE
1.1 This practice covers recommended procedures for the use of dosimeters, such as thermoluminescent dosimeters (TLD's), to determine the absorbed dose in a region of interest within an electronic device irradiated using a Co-60 source. Co-60 sources are commonly used for the absorbed dose testing of silicon electronic devices.  
Note 1: This absorbed-dose testing is sometimes called “total dose testing” to distinguish it from “dose rate testing.”  
Note 2: The effects of ionizing radiation on some types of electronic devices may depend on both the absorbed dose and the absorbed dose rate; that is, the effects may be different if the device is irradiated to the same absorbed-dose level at different absorbed-dose rates. Absorbed-dose rate effects are not covered in this practice but should be considered in radiation hardness testing.  
1.2 The principal potential error for the measurement of absorbed dose in electronic devices arises from non-equilibrium energy deposition effects in the vicinity of material interfaces.  
1.3 Information is given about absorbed-dose enhancement effects in the vicinity of material interfaces. The sensitivity of such effects to low energy components in the Co-60 photon energy spectrum is emphasized.  
1.4 A brief description is given of typical Co-60 sources with special emphasis on the presence of low energy components in the photon energy spectrum output from such sources.  
1.5 Procedures are given for minimizing the low energy components of the photon energy spectrum from Co-60 sources, using filtration. The use of a filter box to achieve such filtration is recommended.  
1.6 Information is given on absorbed-dose enhancement effects that are dependent on the device orientation with respect to the Co-60 source.  
1.7 The use of spectrum filtration and appropriate device orientation provides a radiation environment whereby the absorbed dose in the sensitive region of an elect...

General Information

Status
Published
Publication Date
31-Jan-2021
ICS
17.240 - Radiation measurements
Technical Committee
E10 - Nuclear Technology and Applications
Drafting Committee
E10.07 - Radiation Dosimetry for Radiation Effects on Materials and Devices
Current Stage
Ref Project

Relations

Refers
ASTM E668-20 - Standard Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining Absorbed Dose in Radiation-Hardness Testing of Electronic Devices
Effective Date
01-Jul-2020
Refers
ASTM E1250-15(2020) - Standard Test Method for Application of Ionization Chambers to Assess the Low Energy Gamma Component of Cobalt-60 Irradiators Used in Radiation-Hardness Testing of Silicon Electronic Devices
Effective Date
01-Jul-2020
Refers
ASTM E170-17 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2017
Refers
ASTM E170-16a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Oct-2016
Refers
ASTM E170-16 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Feb-2016
Refers
ASTM E170-15a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2015
Refers
ASTM E1250-15 - Standard Test Method for Application of Ionization Chambers to Assess the Low Energy Gamma Component of Cobalt-60 Irradiators Used in Radiation-Hardness Testing of Silicon Electronic Devices
Effective Date
01-Jun-2015
Refers
ASTM E170-15 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Mar-2015
Refers
ASTM E170-14a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Oct-2014
Refers
ASTM E170-14 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Sep-2014
Refers
ASTM E668-13 - Standard Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining Absorbed Dose in Radiation-Hardness Testing of Electronic Devices
Effective Date
01-Jan-2013
Refers
ASTM E1250-10 - Standard Test Method for Application of Ionization Chambers to Assess the Low Energy Gamma Component of Cobalt-60 Irradiators Used in Radiation-Hardness Testing of Silicon Electronic Devices
Effective Date
01-Dec-2010
Refers
ASTM E668-10 - Standard Practice for Application of Thermoluminescence-Dosimetry (TLD) Systems for Determining Absorbed Dose in Radiation-Hardness Testing of Electronic Devices
Effective Date
01-Jun-2010
Refers
ASTM E170-10 - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
01-Jun-2010
Refers
ASTM E170-09a - Standard Terminology Relating to Radiation Measurements and Dosimetry
Effective Date
15-Aug-2009

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ASTM E1249-15(2021) - Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 SourcesASTM E1249-15(2021) - Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 Sources
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ASTM E1249-15(2021) - Standard Practice for Minimizing Dosimetry Errors in Radiation Hardness Testing of Silicon Electronic Devices Using Co-60 Sources
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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: E1249 − 15 (Reapproved 2021)
Standard Practice for
Minimizing Dosimetry Errors in Radiation Hardness Testing
of Silicon Electronic Devices Using Co-60 Sources
This standard is issued under the fixed designation E1249; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
This standard has been approved for use by agencies of the U.S. Department of Defense.
1. Scope 1.7 The use of spectrum filtration and appropriate device
orientation provides a radiation environment whereby the
1.1 This practice covers recommended procedures for the
absorbed dose in the sensitive region of an electronic device
use of dosimeters, such as thermoluminescent dosimeters
can be calculated within defined error limits without detailed
(TLD’s),todetermine the absorbed dose in a regionofinterest
knowledge of either the device structure or of the photon
within an electronic device irradiated using a Co-60 source.
energyspectrumofthesource,andhence,withoutknowingthe
Co-60 sources are commonly used for the absorbed dose
details of the absorbed-dose enhancement effects.
testing of silicon electronic devices.
1.8 The recommendations of this practice are primarily
NOTE 1—This absorbed-dose testing is sometimes called “total dose
applicable to piece-part testing of electronic devices. Elec-
testing” to distinguish it from “dose rate testing.”
tronic circuit board and electronic system testing may intro-
NOTE 2—The effects of ionizing radiation on some types of electronic
devicesmaydependonboththeabsorbeddoseandtheabsorbeddoserate;
duce problems that are not adequately treated by the methods
that is, the effects may be different if the device is irradiated to the same
recommended here.
absorbed-dose level at different absorbed-dose rates. Absorbed-dose rate
1.9 This standard does not purport to address all of the
effects are not covered in this practice but should be considered in
radiation hardness testing. safety concerns, if any, associated with its use. It is the
responsibility of the user of this standard to establish appro-
1.2 The principal potential error for the measurement of
priate safety, health, and environmental practices and deter-
absorbed dose in electronic devices arises from non-
mine the applicability of regulatory limitations prior to use.
equilibriumenergydepositioneffectsinthevicinityofmaterial
1.10 This international standard was developed in accor-
interfaces.
dance with internationally recognized principles on standard-
1.3 Information is given about absorbed-dose enhancement
ization established in the Decision on Principles for the
effects in the vicinity of material interfaces. The sensitivity of
Development of International Standards, Guides and Recom-
such effects to low energy components in the Co-60 photon
mendations issued by the World Trade Organization Technical
energy spectrum is emphasized.
Barriers to Trade (TBT) Committee.
1.4 A brief description is given of typical Co-60 sources
with special emphasis on the presence of low energy compo-
2. Referenced Documents
nentsinthephotonenergy spectrum output from suchsources. 2
2.1 ASTM Standards:
1.5 Procedures are given for minimizing the low energy E170Terminology Relating to Radiation Measurements and
components of the photon energy spectrum from Co-60 Dosimetry
sources, using filtration.The use of a filter box to achieve such E666Practice for CalculatingAbsorbed Dose From Gamma
filtration is recommended. or X Radiation
E668Practice for Application of Thermoluminescence-
1.6 Information is given on absorbed-dose enhancement
Dosimetry (TLD) Systems for Determining Absorbed
effectsthataredependentonthedeviceorientationwithrespect
DoseinRadiation-HardnessTestingofElectronicDevices
to the Co-60 source.
E1250Test Method forApplication of Ionization Chambers
to Assess the Low Energy Gamma Component of
This practice is under the jurisdiction of ASTM Committee E10 on Nuclear
Technology and Applicationsand is the direct responsibility of Subcommittee
E10.07 on Radiation Dosimetry for Radiation Effects on Materials and Devices. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved Feb. 1, 2021. Published February 2021. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1988. Last previous edition approved in 2015 as E1249–15. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/E1249-15R21. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E1249 − 15 (2021)
Cobalt-60 Irradiators Used in Radiation-Hardness Testing dosimeter, or both, for the purpose of minimizing low energy
of Silicon Electronic Devices components of the incident photon energy spectrum.
2.2 International Commission on Radiation Units and Mea- 3.10 spectrum filter—material layer intercepting photons on
surements Reports: their path between the Co-60 source and the device under test.
ICRUReport14 Radiation Dosimetry: X-Rays andGamma Thepurposeofthefilteristoreducelowenergycomponentsof
Rays With Maximum Photon Energies Between 0.6 and
the photon energy spectrum.
50 MeV
3.11 spectrum hardening—process by which the fraction of
ICRUReport18SpecificationofHighActivityGamma-Ray
low energy components of the photon energy spectrum is
Sources
reduced.
3.12 spectrum softening—process by which the fraction of
3. Terminology
low energy components of the photon energy spectrum is
3.1 absorber—material that reduces the photon fluence rate
increased.
from a Co-60 source by any interaction mechanism.
4. Significance and Use
3.2 absorbed-dose enhancement—increase (or decrease) in
the absorbed dose (as compared to the equilibrium absorbed
4.1 Division of the Co-60 Hardness Testing into Five Parts:
dose) at a point in a material of interest. This can be expected
4.1.1 Theequilibriumabsorbeddoseshallbemeasuredwith
to occur near an interface with a material of higher or lower
a dosimeter, such as a TLD, located adjacent to the device
atomic number.
under test. Alternatively, a dosimeter may be irradiated in the
position of the device before or after irradiation of the device.
3.3 absorbed-dose enhancement factor— ratio of the ab-
sorbed dose at a point in a material of interest to the 4.1.2 This absorbed dose measured by the dosimeter shall
be converted to the equilibrium absorbed dose in the material
equilibrium absorbed dose in that same material.
of interest within the critical region within the device under
3.4 average absorbed dose—mass weighted mean of the
test, for example the SiO gate oxide of an MOS device.
absorbed dose over a region of interest.
4.1.3 A correction for absorbed-dose enhancement effects
3.5 average absorbed-dose enhancement factor—ratio of
shall be considered. This correction is dependent upon the
the average absorbed dose in a region of interest to the
photon energy that strikes the device under test.
equilibrium absorbed dose (1).
4.1.4 A correlation should be made between the absorbed
dose in the critical region (for example, the gate oxide
NOTE 3—For a description of the necessary conditions for measuring
equilibrium absorbed dose, see 6.3.1 and the term charged particle mentioned in 4.1.2) and some electrically important effect
equilibriuminTerminologyE170,whichprovidesdefinitionsanddescrip-
(such as charge trapped at the Si/SiO interface as manifested
tions of other applicable terms of this practice.
by a shift in threshold voltage).
3.6 beam trap—absorber that is designed to remove the 4.1.5 Anextrapolationshouldthenbemadefromtheresults
beam that has been transmitted through the device under test.
of the test to the results that would be expected for the device
Its purpose is to eliminate the scattering of the transmitted under test under actual operating conditions.
beam back into the device under test.
NOTE 5—The parts of a test discussed in 4.1.2 and 4.1.3 are the subject
3.7 clean spectrum—onethatisrelativelyfreeoflowenergy of this practice. The subject of 4.1.1 is covered and referenced in other
standards such as Practice E668 and ICRU Report 14. The parts of a test
componentsinthephotonenergyspectrum.Forexample,fora
discussed in 4.1.4 and 4.1.5 are outside the scope of this practice.
Co-60sourceanideallycleanspectrumwouldcontainonlythe
4.2 Low-Energy Components in the Spectrum—Some of the
primary 1.17 and 1.33 MeV photons of Co-60 decay.
primary Co-60 gamma rays (1.17 and 1.33 MeV) produce
3.8 equilibrium absorbed dose—absorbed dose at some
lower energy photons by Compton scattering within the Co-60
incremental volume within the material in which the condition
source structure, within materials that lie between the source
of charged particle equilibrium (the energies, number, and
and the device under test, and within materials that lie beyond
direction of charged particles induced by the radiation are
the device but contribute to backscattering. As a result of the
constant throughout the volume) exists (see Terminology
complexity of these effects, the photon energy spectrum
E170).
striking the device usually is not well known. This point is
NOTE 4—For practical purposes the equilibrium absorbed dose is the
further discussed in Section 5 and Appendix X1.The presence
absorbed dose value that exists in a material at a distance from any
of low-energy photons in the incident spectrum can result in
interface with another material, greater than the range of the maximum
dosimetry errors. This practice defines test procedures that
energy secondary electrons generated by the incident photons.
shouldminimizedosimetryerrorswithouttheneedtoknowthe
3.9 filter box—container, made of one or more layers of
spectrum. These recommended procedures are discussed in
different materials, surrounding a device under test or a
4.5, 4.6, Section 7, and Appendix X5.
4.3 Conversion to Equilibrium Absorbed Dose in the Device
Material—Theconversionfromthemeasuredabsorbeddosein
AvailablefromInternationalCommissiononRadiationUnits,7910Woodmont
thematerialofthedosimeter(suchastheCaF ofaTLD)tothe
Ave., Washington, DC 20014.
equivalentabsorbeddoseinthematerialofinterest(suchasthe
The boldface numbers in parentheses refer to the list of references appended to
this practice. SiO ofthegateoxideofadevice)isdependentontheincident
E1249 − 15 (2021)
photon energy spectrum. However, if the simplifying assump- Finally,shieldingmaterialsoftungsten,lead,concrete,orwater
tion is made that all incident photons have the energies of the are often present. Therefore, a significant fraction of the
primaryCo-60gammarays,thentheconversionfromabsorbed photons incident on the device under test are the result of
dose in the dosimeter to that in the device under test can be Compton scattering that produces low energy components in
made using tabulated values for the energy absorption coeffi- the source output photon energy spectrum (see ICRU Report
cients for the dosimeter and device materials. Where this 18 for additional discussion of gamma-ray sources).
simplification is appropriate, the error incurred by its use to
NOTE 6—As an example, the energy spectrum from even a relatively
determine equilibrium absorbed dose is usually less than 5%
clean Co-60 source has about 35% of its total number of photons with
(see 6.3).
energies of less than 1 MeV (see Ref (2) and Appendix X1).
4.4 Absorbed-Dose Enhancement Effects— If a higher
5.2 Evenforagivensource,aconsiderablevariabilityexists
atomicnumbermaterialliesadjacenttoaloweratomicnumber
in the output energy spectrum depending on the geometry and
material, the energy deposition in the region adjacent to the
positionofirradiation.Thespectrumatanypositionisaffected
interface is a complex function of the incident photon energy
by scattering from walls, floor, and ceiling and by scattering
spectrum, the material composition, and the spatial arrange-
from material located nearby.
mentofthesourceandabsorbers.Theabsorbeddosenearsuch
NOTE 7—A qualitative estimate of the spectrum hardness for a given
an interface cannot be adequately determined using the proce-
source can be obtained using Method E1250.
dure outlined in 4.3. Errors incurred by failure to account for
5.3 The following Co-60 source types are described briefly
these effects may, in unusual cases, exceed a factor of five.
andlistedintheorderofdecreasingrelativespectrumhardness
Becausemicroelectronicdevicescharacteristicallycontainlay-
under the most favorable conditions of irradiation.
ers of dissimilar materials with thicknesses of tens of
nanometres, absorbed-dose enhancement effects are a charac-
NOTE 8—Diagrams of typical sources, a nominal photon energy
teristic problem for irradiation of such devices (see 6.1 and
spectrum for each, and references are given in Appendix X1.
Appendix X2).
5.3.1 A teletherapy source is a completely shielded source
4.5 Minimizing Absorbed-Dose Enhancement Effects—
from which the photon output is confined to a beam that is
Under some circumstances, absorbed-dose enhancement ef-
usually collimated.The source output is typically directed into
fects can be minimized by hardening the spectrum. Hardening
a shielded room, but a shielded container, or box, is used in
isaccomplishedbytheuseofhighatomicnumberabsorbersto
some cases.
remove low energy components of the spectrum, and by
5.3.2 A room sourceisasourcecontainedinashieldedwell
minimizing the amount and proximity of low atomic number
fromwhichitismovedintoashieldedroombyremotecontrol.
material to reduce softening of the spectrum by Compton
Its position in the room relative to walls, floor, and ceiling and
scattering (see Sections 6 and 7).
otherscatteringmaterialdeterminestherelativehardnessofits
4.6 Limits of the Dosimetry Errors— To correct for effective photon energy spectrum. As a result, the photon
absorbed-dose enhancement by calculational methods would energy spectrum obtained in a room source can be relatively
require a knowledge of the incident photon energy spectrum hard or relatively soft as compared with other Co-60 sources.
and the detailed structure of the device under test. To measure
5.3.3 A water well sourceisacompletelyshieldedsourceat
absorbed-dose enhancement would require methods for simu-
a certain depth in a pool of water to which access for
lati
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ASTM
ASTM E3376-23(Practice)
Standard Practice for Calibration and Usage of Germanium Detectors in Radiation Metrology for Reactor Dosimetry

SIGNIFICANCE AND USE
5.1 High-purity germanium detectors are used for precise gamma-ray spectroscopy for the purpose of determining radioactivity in materials. Typical applications include monitoring, mapping, and characterization of neutron energy spectra in nuclear reactors or isotopic fission sources.
SCOPE
1.1 This standard establishes techniques for calibration, usage, and performance testing of germanium detectors for the measurement of gamma-ray emission rates of radionuclides in radiation metrology for reactor dosimetry. The practice is applicable only to samples of small size, approximating to point sources. It covers the energy and full-energy peak efficiency calibration as well as the determination of gamma-ray energies in the 0.06 MeV to 2 MeV energy region and is designed to yield gamma-ray emission rates with an uncertainty of ±3 % (see Note 1). This technique applies to measurements that do not involve overlapping peaks, and in which peak-to-continuum considerations are not important.
Note 1: Uncertainty U is given at the 68 % confidence level; that is,  where δi are the estimated maximum systematic uncertainties, and σi are the random uncertainties at the 68 % confidence level. Other techniques of error analysis are in use (1, 2).2  
1.2 Additional information on the setup, calibration, and quality control for radiometric detectors and measurements is given in IEEE/ANSI N42.14 and in Guide C1402 and Practice D7282.  
1.3 The values stated in SI units are generally to be regarded as standard. The rad is an exception.  
1.4 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.  
1.5 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 E181-23(Guide)
Standard Guide for Detector Calibration and Analysis of Radionuclides in Radiation Metrology for Reactor Dosimetry

ABSTRACT
These methods cover general procedures for the calibration of radiation detectors and the analysis of radionuclides. For each individual radionuclide, one or more of these methods may apply. These methods are concerned only with specific radionuclide measurements. The chemical and physical properties of the radionuclides are beyond the scope of this standard. Among the measurement standards discussed are: the calibration and usage of germanium detectors, scintillation detector systems, scintillation detectors for simple and complex spectra, and counting methods such as beta particle counting, aluminum absorption curve, alpha particle counting, and liquid scintillation counting. For each of the methods, the scope, apparatus used, summary of methods, preparation of apparatus, calibration procedure, measurement of radionuclide, performance testing, sources of uncertainty, precautions and tests, and calculations are detailed.
SCOPE
1.1 This guide covers general procedures for the calibration of radiation detectors and measurement for radiation metrology for reactor dosimetry. For any particular radionuclide, one or more of these methods may apply.  
1.2 These techniques are concerned only with specific radionuclide measurements. The chemical and physical properties of the radionuclides are not within the scope of this standard.  
1.3 E3376, Standard Practice for Calibration and Usage of Germanium Detectors in Radiation Metrology for Reactor Dosimetry, was previously in Guide E181 and is now found in Volume 12.02 of the Annual Book of ASTM Standards. The discussion herein is not a sufficient substitute for the full standard. This guide is specifically NOT to be used as a direct reference to Practice E3376. Only the standard listed provides sufficient information to serve as a reference.  
1.4 Additional information on the setup, calibration, and quality control for radiometric detectors and measurements is given in Guide C1402 and Practice D7282.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
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 E170-23(Terminology)
Standard Terminology Relating to Radiation Measurements and Dosimetry
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ASTM
ASTM E2450-23(Practice)
Standard Practice for Application of CaF2(Mn) Thermoluminescence Dosimeters in Mixed Neutron-Photon Environments

SIGNIFICANCE AND USE
4.1 Electronic devices are typically tested for device response to gamma radiation in pure gamma-ray fields. Testing electronic device response against neutrons is more complex since there is invariably a gamma-ray component in addition to the neutron field. The gamma-ray response of the electronic device is typically subtracted from the overall response to find the device response to neutrons. This approach to the testing requires a determination of the gamma-ray exposure in the mixed field. To enhance the neutron effects, the radiation field is sometimes selected to have as large a neutron component as possible.  
4.2 CaF2(Mn) TLDs are often used to monitor the gamma-ray dose in mixed neutron/gamma radiation fields. Since the dosimeters are exposed along with the device under test to the mixed field, their response must be corrected for neutrons. In a field rich in neutrons, the uncertainty in the interpretation of the TLD response grows. In fields with relatively few neutrons, the total TLD response may be used to make a correction for gamma response of the device under test. Under this condition, the relative uncertainty in the TLD neutron response is not likely to drive the overall uncertainty in the correction to the electronic device response.  
4.3 This practice gives a means of estimating the response of CaF2(Mn) TLDs to neutrons. This neutron response is then subtracted from the measured response to determine the TLD response due to gamma rays. The procedure has relatively high uncertainty because the neutron response of CaF2(Mn) TLDs may vary depending on the source of the material, and this procedure is a generic calculation applicable to CaF2(Mn) TLDs independent of their manufacturer/source. The neutron response given in this practice is a summary of CaF2(Mn) TLD responses reported in the literature. The associated uncertainty envelops the range of results reported and includes the variety of CaF2(Mn) TLDs used as well as the uncertainties in the det...
SCOPE
1.1 This practice describes a procedure for correcting a CaF2(Mn) thermoluminescence dosimeter (TLD) reading for its response to neutrons during the irradiation. The neutron response may be subtracted from the total TLD response to give the gamma-ray response. In fields with a large neutron contribution to the total response, this procedure may result in large uncertainties.  
1.2 More precise experimental techniques may be applied if the uncertainty derived from this practice is larger than the level that the user can accept. These more precise techniques are not discussed here. The references in Section 8 describe some of these techniques.  
1.3 This practice does not discuss effects on the TLD reading from neutron interactions with the material surrounding the TLD and used to ensure a charged particle equilibrium. These effects will depend on the isotopic composition of the surrounding material and its thickness, and on the incident neutron spectrum  (1).2  
1.4 The values stated in SI units are to be regarded as standard.  
1.5 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 E526-22(Test Method)
Standard Test Method for Measuring Fast-Neutron Reaction Rates By Radioactivation of Titanium

SIGNIFICANCE AND USE
5.1 Refer to Guide E844 for the selection, irradiation, and quality control of neutron dosimeters.  
5.2 Refer to Practice E261 for a general discussion of the determination of fast-neutron fluence rate with threshold detectors.  
5.3 Titanium has good physical strength, is easily fabricated, has excellent corrosion resistance, has a melting temperature of 1668 °C, and can be obtained with satisfactory purity.  
5.4 46Sc has a half-life of 83.787 (16)4 days (2). The 46Sc decay emits a 0.889271 (2) MeV gamma 99.98374 (35) % of the time and a second gamma with an energy of 1.120537 (3) MeV 99.97 (2) % of the time.  
5.5 The recommended “representative isotopic abundances” for natural titanium (3) are:    
8.25 (3) % 46Ti  
7.44 (2) % 47Ti  
73.72 (2) % 48Ti  
5.41 (2) % 49Ti  
5.18 (2) % 50Ti  
5.6 The radioactive products of the neutron reactions 47Ti(n,p)47Sc (τ1/2 = 3.3485 (9) d) (2) and 48Ti(n,p)48Sc (τ1/2 = 43.67 h), (3) might interfere with the analysis of 46Sc.  
5.7 Contaminant activities (for example, 65Zn and 182Ta) might interfere with the analysis of 46Sc. See 7.1.2 and 7.1.3 for more details on the 182Ta and 65Zn interference.  
5.8 46Ti and 46Sc have cross sections for thermal neutrons of 0.59 ± 0.18 and 8.0 ± 1.0 barns, respectively (4); therefore, when an irradiation exceeds a thermal-neutron fluence greater than about 2 × 1021 cm–2, provisions should be made to either use a thermal-neutron shield to prevent burn-up of 46Sc or measure the thermal-neutron fluence rate and calculate the burn-up.  
5.9 Fig. 1 shows a plot of the International Reactor Dosimetry and Fusion File, IRDFF-II cross section (5) versus neutron energy for the fast-neutron reactions of titanium which produce 46Sc (that is, natTi(n,X)46Sc). Included in the plot is the 46Ti(n,p) reaction and the 47Ti(n,np:d) contributions to the 46Sc production, normalized per natTi atom with the individual isotopic contributions weighted using the natural abundances (3). This figure ...
SCOPE
1.1 This test method covers procedures for measuring reaction rates by the activation reaction natTi(n,X)46Sc. The “X” designation represents any combination of light particles associated with the production of the residual 46Sc product. Within the applicable neutron energy range for fission reactor applications, this reaction is a properly normalized combination of three different reaction channels: 46Ti(n,p)46Sc; 47Ti(n, np)46Sc; and 47Ti(n,d)46Sc.
Note 1: The 47Ti(n,np)46Sc reaction, ENDF-6 format file/reaction identifier MF=3, MT=28, is distinguished from the 47Ti(n,d)46Sc reaction, ENDF-6 format file/reaction identifier MF=3/MT=104, even though it leads to the same residual product (1).2 The combined reaction, in the IRDFF-II library, has the file/reaction identifier MF=10/MT=5.
Note 2: The cross section for the combined 47Ti(n,np:d) reaction is relatively small for energies less than 12 MeV and, in fission reactor spectra, the production of the residual 46Sc is not easily distinguished from that due to the 46Ti(n,p) reaction.  
1.2 The reaction is useful for measuring neutrons with energies above approximately 4.4 MeV and for irradiation times, under uniform power, up to about 250 days (for longer irradiations, or for varying power levels, see Practice E261).  
1.3 With suitable techniques, fission-neutron fluence rates above 109 cm–2·s–1 can be determined. However, in the presence of a high thermal-neutron fluence rate, 46Sc depletion should be investigated.  
1.4 Detailed procedures for other fast-neutron detectors are referenced in Practice E261.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
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 an...

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ASTM
ASTM E496-14(2022)(Test Method)
Standard Test Method for Measuring Neutron Fluence and Average Energy from 3H(d,n)4He Neutron Generators by Radioactivation Techniques

SIGNIFICANCE AND USE
5.1 Refer to Practice E261 for a general discussion of the measurement of fast-neutron fluence rates with threshold detectors.  
5.5.1 Fig. 5 (2) shows how the neutron energy depends upon the angle of scattering in the laboratory coordinate system when the incident deuteron has an energy of 150 keV and is incident on a thick and a thin tritiated target. For thick targets, the incident deuteron loses energy as it penetrates the target and produces neutrons of lower energy. A thick target is defined as a target thick enough to completely stop the incident deuteron. The two curves in Fig. 5, for both thick and thin targets, come from different sources. The dashed line calculations come from Ref (3); the solid curve calculations come from Ref (4); and the measured data come from Ref (5). The dash-dot curve and the right-hand axis give the difference between the calculated neutron energies for thin and thick targets. Computer codes are available to assist in calculating the expected thick and thin target yield and neutron spectrum for various incident deuteron energies (6).
FIG. 5 Dependence of 3H(d,n)4He Neutron Energy on Angle (2)  
5.6 The Q-value for the primary 3H(d,n)4He reaction is +17.59 MeV. When the incident deuteron energy exceeds 3.71 MeV and 4.92 MeV, the break-up reactions 3H(d,np)3H and 3H(d,2n)3He, respectively, become energetically possible. Thus, at high deuteron energies (>3.71 MeV) this reaction is no longer monoenergetic. Monoenergetic neutron beams with energies from about 14.8 to 20.4 MeV can be produced by this reaction at forward laboratory angles (7).  
5.7 It is recommended that the dosimetry sensors be fielded in the exact positions where the dosimetry results are wanted. There are a number of factors that can affect the monochromaticity or energy spread of the neutron beam (7, 8). These factors include the energy regulation of the incident deuteron energy, energy loss in retaining windows if a gas target is used or energy loss within t...
SCOPE
1.1 This test method covers a general procedure for the measurement of the fast-neutron fluence rate produced by neutron generators utilizing the 3H(d,n)4He reaction. Neutrons so produced are usually referred to as 14-MeV neutrons, but range in energy depending on a number of factors. This test method does not adequately cover fusion sources where the velocity of the plasma may be an important consideration.  
1.2 This test method uses threshold activation reactions to determine the average energy of the neutrons and the neutron fluence at that energy. At least three activities, chosen from an appropriate set of dosimetry reactions, are required to characterize the average energy and fluence. The required activities are typically measured by gamma-ray spectroscopy.  
1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 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.  
1.5 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 E261-16(2021)(Practice)
Standard Practice for Determining Neutron Fluence, Fluence Rate, and Spectra by Radioactivation Techniques

SIGNIFICANCE AND USE
5.1 Transmutation Processes—The effect on materials of bombardment by neutrons depends on the energy of the neutrons; therefore, it is important that the energy distribution of the neutron fluence, as well as the total fluence, be determined.
SCOPE
1.1 This practice describes procedures for the determination of neutron fluence rate, fluence, and energy spectra from the radioactivity that is induced in a detector specimen.  
1.2 The practice is directed toward the determination of these quantities in connection with radiation effects on materials.  
1.3 For application of these techniques to reactor vessel surveillance, see also Test Methods E1005.  
1.4 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.
Note 1: Detailed methods for individual detectors are given in the following ASTM test methods: E262, E263, E264, E265, E266, E343, E393, E481, E523, E526, E704, E705, and E854.  
1.5 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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