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ASTM E854-98

(Test Method)

Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)

Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)

SCOPE
1.1 This test method describes the use of solid-state track recorders (SSTR) for neutron dosimetry in light-water reactor (LWR) applications. These applications extend from low neutron fluence to high neutron fluence, including high power pressure vessel surveillance and test reactor irradiations as well as low power benchmark field measurement. This test method replaces Method E418. This test method is more detailed and special attention is given to the use of state-of-the-art manual and automated track counting methods to attain high absolute accuracies. In-situ dosimetry in actual high fluence-high temperature LWR environs is emphasized.
1.2 This test method includes SSTR analysis by both manual and automated methods. To attain a desired accuracy, the track scanning method selected places limits on the allowable track density. Typically good results are obtained in the range of 5 to 500 000 tracks/cm  and accurate results at higher track densities have been demonstrated for some cases. Track density and other factors place limits on the applicability of the SSTR method at high fluences. Special care must be exerted when measuring neutron fluences (E>1MeV) above 10 16  n/cm .
1.3 High fluence limitations exist. Successful results have been reported for total fluences up to approximately 10 16  n/cm . Beyond 10 16  n/cm  some workers report problems (1),  but others report no problems with total fluences up to approximately 5 X 10 18  n/cm  (2).
1.4 SSTR observations provide time-integrated reaction rates. Therefore, SSTR are truly passive-fluence detectors. They provide permanent records of dosimetry experiments without the need for time-dependent corrections, such as decay factors that arise with radiometric monitors.
1.5 Since SSTR provide a spatial record of the time-integrated reaction rate at a microscopic level, they can be used for "fine-structure" measurements. For example, spatial distributions of isotopic fission rates can be obtained at very high resolution with SSTR.
1.6 This standard does not purport to address the safety problems 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.

General Information

Status
Historical
Publication Date
09-Jan-1998
ICS
27.120.20 - Nuclear power plants. Safety
Technical Committee
E10 - Nuclear Technology and Applications
Drafting Committee
E10.05 - Nuclear Radiation Metrology
Current Stage
Ref Project

Relations

Replaced By
ASTM E854-03 - Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)
Effective Date
10-Feb-2003
Referred By
ASTM E2059-20 - Standard Practice for Application and Analysis of Nuclear Research Emulsions for Fast Neutron Dosimetry
Effective Date
10-Jan-1998
Referred By
ASTM E261-16(2021) - Standard Practice for Determining Neutron Fluence, Fluence Rate, and Spectra by Radioactivation Techniques
Effective Date
10-Jan-1998
Referred By
ASTM E1018-20e1 - Standard Guide for Application of ASTM Evaluated Cross Section Data File
Effective Date
10-Jan-1998
Referred By
ASTM E1005-21 - Standard Test Method for Application and Analysis of Radiometric Monitors for Reactor Vessel Surveillance
Effective Date
10-Jan-1998
Referred By
ASTM E853-23 - Standard Practice for Analysis and Interpretation of Light-Water Reactor Surveillance Neutron Exposure Results
Effective Date
10-Jan-1998
Referred By
ASTM E1035-18(2023) - Standard Practice for Determining Neutron Exposures for Nuclear Reactor Vessel Support Structures
Effective Date
10-Jan-1998
Referred By
ASTM E798-16 - Standard Practice for Conducting Irradiations at Accelerator-Based Neutron Sources
Effective Date
10-Jan-1998
Referred By
ASTM E2005-21 - Standard Guide for Benchmark Testing of Reactor Dosimetry in Standard and Reference Neutron Fields
Effective Date
10-Jan-1998
Referred By
ASTM E910-18 - Standard Test Method for Application and Analysis of Helium Accumulation Fluence Monitors for Reactor Vessel Surveillance
Effective Date
10-Jan-1998
Referred By
ASTM E1006-21 - Standard Practice for Analysis and Interpretation of Physics Dosimetry Results from Test Reactor Experiments
Effective Date
10-Jan-1998
Referred By
ASTM E944-19 - Standard Guide for Application of Neutron Spectrum Adjustment Methods in Reactor Surveillance
Effective Date
10-Jan-1998

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ASTM E854-98 - Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)ASTM E854-98 - Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)
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ASTM E854-98 - Standard Test Method for Application and Analysis of Solid State Track Recorder (SSTR) Monitors for Reactor Surveillance, E706(IIIB)
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NOTICE: This standard has either been superceded and replaced by a new version or discontinued.
Contact ASTM International (www.astm.org) for the latest information.
Designation: E 854 – 98
Standard Test Method for
Application and Analysis of Solid State Track Recorder
(SSTR) Monitors for Reactor Surveillance, E706(IIIB)
This standard is issued under the fixed designation E 854; 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 (e) indicates an editorial change since the last revision or reapproval.
1. Scope practices and determine the applicability of regulatory limita-
tions prior to use.
1.1 This test method describes the use of solid-state track
recorders (SSTRs) for neutron dosimetry in light-water reactor
2. Referenced Documents
(LWR) applications. These applications extend from low
2.1 ASTM Standards:
neutron fluence to high neutron fluence, including high power
E 418 Method for Fast-Neutron Measurements by Track-
pressure vessel surveillance and test reactor irradiations as well
Etch Techniques
as low power benchmark field measurement. (1) This test
E 844 Guide for Sensor Set Design and Irradiation for
method replaces Method E 418. This test method is more
Reactor Surveillance, E706 (IIC)
detailed and special attention is given to the use of state-of-
the-art manual and automated track counting methods to attain
3. Summary of Test Method
high absolute accuracies. In-situ dosimetry in actual high
3.1 SSTR are usually placed in firm surface contact with a
fluence-high temperature LWR applications is emphasized.
fissionable nuclide that has been deposited on a pure nonfis-
1.2 This test method includes SSTR analysis by both
sionable metal substrate (backing). This typical SSTR geom-
manual and automated methods. To attain a desired accuracy,
etry is depicted in Fig. 1. Neutron-induced fission produces
the track scanning method selected places limits on the
latent fission-fragment tracks in the SSTR. These tracks may
allowable track density. Typically good results are obtained in
be developed by chemical etching to a size that is observable
the range of 5 to 800 000 tracks/cm and accurate results at
with an optical microscope. Microphotographs of etched fis-
higher track densities have been demonstrated for some cases.
sion tracks in mica, quartz glass, and natural quartz crystals can
(2) Track density and other factors place limits on the appli-
be seen in Fig. 2.
cability of the SSTR method at high fluences. Special care
3.1.1 While the conventional SSTR geometry depicted in
must be exerted when measuring neutron fluences (E>1MeV)
16 2 Fig. 1 is not mandatory, it does possess distinct advantages for
above 10 n/cm . (3)
dosimetry applications. In particular, it provides the highest
1.3 High fluence limitations exist. These limitations are
efficiency and sensitivity while maintaining a fixed and easily
discussed in detail in Section 13 and in references (3-5).
reproducible geometry.
1.4 SSTR observations provide time-integrated reaction
3.1.2 The track density (that is, the number of tracks per unit
rates. Therefore, SSTR are truly passive-fluence detectors.
area) is proportional to the fission density (that is, the number
They provide permanent records of dosimetry experiments
of fissions per unit area). The fission density is, in turn,
without the need for time-dependent corrections, such as decay
proportional to the exposure fluence experienced by the SSTR.
factors that arise with radiometric monitors.
The existence of nonuniformity in the fission deposit or the
1.5 Since SSTR provide a spatial record of the time-
presence of neutron flux gradients can produce non-uniform
integrated reaction rate at a microscopic level, they can be used
track density. Conversely, with fission deposits of proven
for “fine-structure” measurements. For example, spatial distri-
uniformity, gradients of the neutron field can be investigated
butions of isotopic fission rates can be obtained at very high
with very high spatial resolution.
resolution with SSTR.
3.2 The total uncertainty of SSTR fission rates is comprised
1.6 This standard does not purport to address the safety
of two independent sources. These two error components arise
problems associated with its use. It is the responsibility of the
from track counting uncertainties and fission-deposit mass
user of this standard to establish appropriate safety and health
uncertainties. For work at the highest accuracy levels, fission-
deposit mass assay should be performed both before and after
the SSTR irradiation. In this way, it can be ascertained that no
This test method is under the jurisdiction of ASTM Committee E-10 on Nuclear
significant removal of fission deposit material arose in the
Technology and Applicationsand is the direct responsibility of Subcommittee
E10.05on Nuclear Radiation Metrology.
Current edition approved Jan. 10, 1998. Published May 1998. Originally
Discontinued; see 1983 Annual Book of ASTM Standards, Vol 12.02.
published as E 854 – 81. Last previous edition E 854 – 90. Annual Book of ASTM Standards, Vol 12.02.
Copyright © ASTM, 100 Barr Harbor Drive, West Conshohocken, PA 19428-2959, United States.
NOTICE: This standard has either been superceded and replaced by a new version or discontinued.
Contact ASTM International (www.astm.org) for the latest information.
E 854
the benchmark field spectrum used for calibration. In any
event, it must be stressed that the SSTR-fission density
measurements can be carried out completely independent of
any cross-section standards (6). Therefore, for certain applica-
tions, the independent nature of this test method should not be
compromised. On the other hand, many practical applications
exist wherein this factor is of no consequence so that bench-
mark field calibration would be entirely appropriate.
5. Apparatus
5.1 Optical Microscopes, with a magnification of 200 3 or
higher, employing a graduated mechanical stage with position
readout to the nearest 1 μm and similar repositioning accuracy.
A calibrated stage micrometer and eyepiece scanning grids are
FIG. 1 Typical Geometrical Configuration Used for SSTR Neutron
also required.
Dosimetry
5.2 Constant-Temperature Baths, for etching, with tempera-
ture control to 0.1°C.
course of the experiment.
5.3 Analytical Weighing Balance, for preparation of etching
bath solutions, with a capacity of at least 1000 g and an
4. Significance and Use
accuracy of at least 1 mg.
4.1 The SSTR method provides for the measurement of
6. Reagents and Materials
absolute-fission density per unit mass. Absolute-neutron flu-
ence can then be inferred from these SSTR-based absolute
6.1 Purity of Reagents—Distilled or demineralized water
fission rate observations if an appropriate neutron spectrum and analytical grade reagents should be used at all times. For
average fission cross section is known. This method is highly
high fluence measurements, quartz-distilled water and ultra-
discriminatory against other components of the in-core radia- pure reagents are necessary in order to reduce background
tion field. Gamma rays, beta rays, and other lightly ionizing
fission tracks from natural uranium and thorium impurities.
particles do not produce observable tracks in appropriate LWR This is particularly important if any pre-irradiation etching is
SSTR candidate materials. However, photofission can contrib-
performed (see 8.2).
ute to the observed fission track density and should therefore be
6.2 Reagents:
accounted for when nonnegligible. For a more detailed discus-
6.2.1 Hydrofluoric Acid (HF), weight 49 %.
sion of photofission effects, see 13.4.
6.2.2 Sodium Hydroxide Solution (NaOH), 6.2 N.
4.2 In this test method, SSTR are placed in surface contact
6.2.3 Distilled or Demineralized Water.
with fissionable deposits and record neutron-induced fission
6.2.4 Potassium Hydroxide Solution (KOH), 6.2 N.
fragments. By variation of the surface mass density (μg/cm )of
6.2.5 Sodium Hydroxide Solution (NaOH), weight 65 %.
the fissionable deposit as well as employing the allowable
6.3 Materials:
2 5
range of track densities (from roughly 1 event/cm up to 10 6.3.1 Glass Microscope Slides.
events/cm for manual scanning), a range of total fluence
6.3.2 Slide Cover Glasses.
sensitivity covering at least 16 orders of magnitude is possible,
2 2 18 2
7. SSTR Materials for Reactor Applications
from roughly 10 n/cm up to 5 3 10 n/cm . The allowable
range of fission track densities is broader than the track density 7.1 Required Properties—SSTR materials for reactor appli-
range for high accuracy manual scanning work with optical cations should be transparent dielectrics with a relatively high
microscopy cited in 1.2. In particular, automated and semi- ionization threshold, so as to discriminate against lightly
automated methods exist that broaden the customary track ionizing particles. The materials that meet these prerequisites
density range available with manual optical microscopy. In this most closely are the minerals mica, quartz glass, and quartz
broader track density region, effects of reduced counting crystals. Selected characteristics for these SSTR are summa-
statistics at very low track densities and track pile-up correc- rized in Table 1. Other minerals such as apatite, sphene, and
tions at very high track densities can present inherent limita- zircon are also suitable, but are not used due to inferior etching
tions for work of high accuracy. Automated scanning tech- properties compared to mica and quartz. These alternative
niques are described in Section 11. SSTR candidates often possess either higher imperfection
4.3 For dosimetry applications, different energy regions of
density or poorer contrast and clarity for scanning by optical
the neutron spectrum can be selectively emphasized by chang- microscopy. Mica and particularly quartz can be found with the
ing the nuclide used for the fission deposit. additional advantageous property of low natural uranium and
4.4 It is possible to use SSTR directly for neutron dosimetry thorium content. These heavy elements are undesirable in
as described in 4.1 or to obtain a composite neutron detection neutron-dosimetry work, since such impurities lead to back-
efficiency by exposure in a benchmark neutron field. The ground track densities when SSTR are exposed to high neutron
fluence and spectrum-averaged cross section in this benchmark fluence. In the case of older mineral samples, a background of
field must be known. Furthermore, application in other neutron fossil fission track arises due mainly to the spontaneous fission
fields may require adjustments due to spectral deviation from decay of U. Glasses (and particularly phosphate glasses) are
NOTICE: This standard has either been superceded and replaced by a new version or discontinued.
Contact ASTM International (www.astm.org) for the latest information.
E 854
NOTE 1—The track designated by the arrow in the mica SSTR is a fossil fission track that has been enlarged by suitable preirradiation etching.
FIG. 2 Microphotograph of Fission Fragment Tracks in Mica
less suitable than mica and quartz due to higher uranium and crystal SSTRs for high-temperature neutron dosimetry mea-
thorium content. Also, the track-etching characteristics of surements is the work described in reference (14).
many glasses are inferior, in that these glasses possess higher
7.2.2 Radiation Damage—Lexan and Makrofol are highly
bulk etch rate and lower registration efficiency. Other SSTR
sensitive to other components of the radiation field. As men-
4 5
materials, such as Lexan and Makrofol are also used, but are
tioned in 7.1, the bulk-etch rates of plastic SSTR are increased
less convenient in many reactor applications due to the
by exposure to b and g radiation. Quartz has been observed to
presence of neutron-induced recoil tracks from elements such
have a higher bulk etch rate after irradiation with a fluence of
as carbon and oxygen present in the SSTR. These detectors are 21 2
4 3 10 neutrons/cm , but both quartz and mica are very
also more sensitive (in the form of increased bulk etch rate) to
insensitive to radiation damage at lower fluences (<10
the b and g components of the reactor radiation field (13).
neutrons/cm ).
Also, they are more sensitive to high temperatures, since the
7.2.3 Background Tracks—Plastic track detectors will reg-
onset of track annealing occurs at a much lower temperature
ister recoil carbon and oxygen ions resulting from neutron
for plastic SSTR materials.
scattering on carbon and oxygen atoms in the plastic. These
7.2 Limitations of SSTR in LWR Environments:
fast neutron-induced recoils can produce a background of short
7.2.1 Thermal Annealing—High temperatures result in the
tracks. Quartz and mica will not register such light ions and are
erasure of tracks due to thermal annealing. Natural quartz
not subject to such background tracks.
crystal is least affected by high temperatures, followed by
mica. Lexan and Makrofol are subject to annealing at much
8. SSTR Pre- and Post-Irradiation Processing
lower temperatures. An example of the use of natural quartz
8.1 Pre-Irradiation Annealing:
8.1.1 In the case of mica SSTR, a pre-annealing procedure
Lexan is a registered trademark of the General Electric Co., Pittsfield, MA.
5 designed to remove fossil track damage is advisable for work
Makrofol is a registered trademark of Farbenfabriken Bayer AG, U. S.
representative Naftone, Inc., New York, NY. at low neutron fluences. The standard procedure is annealing
NOTICE: This standard has either been superceded and replaced by a new version or discontinued.
Contact ASTM International (www.astm.org) for the latest information.
E 854
FIG. 2 Quartz Glass (continued)
FIG. 2 Quartz Crystal (001 Plane) (continued)
tion a few etch pits may be present even in good-quality quartz
for6hat 600°C (longer time periods may result in dehydra- glass. If so, they will be larger than tracks due to fission
tion). Fossil track densities are so low in good Brazilian quartz fragments revealed in the post-etch, and readily distinguished
crystals that pre-annealing is not generally necessary. Anneal- from them.
ing is not advised for plastic SSTR because of the possibility of 8.2.4 Plastic-Track Recorders—If handled properly, back-
thermal degradation of the polymer or altered composition, ground from natural sources, such as radon, will be negligible.
both of which could effect track registration properties of the Consequently, both preannealing and pre-etching should be
plastic. unnecessary.
8.2 Pre-Irradiation Etching: 8.3 Post-Irradiation Etching:
8.2.1 Mica—Unannealed fossil tracks in mica are easily 8.3.1 Mica—Customary
...

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SCOPE
1.1 This guide describes the application of melt wire temperature monitors and their use for reactor vessel surveillance of light-water power reactors as called for in Practices E185 and E2215.  
1.2 The purpose of this guide is to recommend the selection and use of the common melt wire technique where the correspondence between melting temperature and composition of different alloys is used as a passive temperature monitor. Guidelines are provided for the selection and calibration of monitor materials; design, fabrication, and assembly of monitor and container; post-irradiation examinations; interpretation of the results; and estimation of uncertainties.  
1.3 The values stated in SI units are to be regarded as standard. The values given in parentheses are mathematical conversions to inch-pound units that are provided for information only and are not considered 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. (See Note 1.)  
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 E482-22(Guide)
Standard Guide for Application of Neutron Transport Methods for Reactor Vessel Surveillance

SIGNIFICANCE AND USE
3.1 General:  
3.1.1 The methodology recommended in this guide specifies criteria for validating computational methods and outlines procedures applicable to pressure vessel related neutronics calculations for test and power reactors. The material presented herein is useful for validating computational methodology and for performing neutronics calculations that accompany reactor vessel surveillance dosimetry measurements (see Master Matrix E706 and Practice E853). Briefly, the overall methodology involves: (1) methods-validation calculations based on at least one well-documented benchmark problem, and (2) neutronics calculations for the facility of interest. The neutronics calculations of the facility of interest and of the benchmark problem should be performed consistently, with important modeling parameters kept the same or as similar as is feasible. In particular, the same energy group structure and common broad-group microscopic cross sections should be used for both problems. Further, the benchmark problem should be characteristically similar to the facility of interest. For example, a power reactor benchmark should be utilized for power reactor calculations. Non-power reactors may have special features that may affect pressure vessel fluence and require consideration when developing a benchmark, such as beam tubes, irradiation facilities, and non-core neutron sources. The neutronics calculations involve two tasks: (1) determination of the neutron source distribution in the reactor core by utilizing diffusion theory (or transport theory) calculations in conjunction with reactor power distribution measurements, and (2) performance of a fixed fission rate neutron source (fixed-source) transport theory calculation to determine the neutron fluence rate distribution in the reactor core, through the internals and in the pressure vessel. Some neutronics modeling details for the benchmark, test reactor, or the power reactor calculation will differ; therefore, the proc...
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1.1 Need for Neutronics Calculations—An accurate calculation of the neutron fluence and fluence rate at several locations is essential for the analysis of integral dosimetry measurements and for predicting irradiation damage exposure parameter values in the pressure vessel. Exposure parameter values may be obtained directly from calculations or indirectly from calculations that are adjusted with dosimetry measurements; Guide E944 and Practice E853 define appropriate computational procedures.  
1.2 Methodology—Neutronics calculations for application to reactor vessel surveillance encompass three essential areas: (1) validation of methods by comparison of calculations with dosimetry measurements in a benchmark experiment, (2) determination of the neutron source distribution in the reactor core, and (3) calculation of neutron fluence rate at the surveillance position and in the pressure vessel.  
1.3 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.  
1.4 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 E1892-15(2021)(Guide)
Standard Guide for Preparing Characterization Plans for Decommissioning Nuclear Facilities

SIGNIFICANCE AND USE
5.1 Knowledge of the nature and extent of contamination in a nuclear facility to be decommissioned is crucial to choosing the optimum methods for decontamination and decommissioning, and estimating the resulting waste volumes and personnel exposures. Implementing a characterization plan, developed in accordance with this standard, will result in obtaining or deriving the above information.  
5.2 Information on the proposed decommissioning methods, waste volumes, and estimated personnel radiation exposures can be used to define the overall work scope, costs, schedules, and manpower needs for the decommissioning project. This information may be included in the Decommissioning Plan. The extent of over- or under-estimating these project parameters will be a function of the sampling plan and statistical designs, described in Sections 6.1.4 and 6.1.5.
SCOPE
1.1 This standard guide applies to developing nuclear facility characterization plans to define the type, magnitude, location, and extent of radiological and chemical contamination within the facility to allow decommissioning planning. This guide amplifies guidance regarding facility characterization indicated in ASTM Standard E1281 on Nuclear Facility Decommissioning Plans. This guide does not address the methodology necessary to release a facility or site for unconditional use. This guide specifically addresses:  
1.1.1 the data quality objective for characterization as an initial step in decommissioning planning.  
1.1.2 sampling methods,  
1.1.3 the logic involved (statistical design) to ensure adequate characterization for decommissioning purposes; and  
1.1.4 essential documentation of the characterization information.  
1.2 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.  
1.3 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 E1281-15(2021)(Guide)
Standard Guide for Nuclear Facility Decommissioning Plans

SIGNIFICANCE AND USE
4.1 The standardization of decommissioning plans will provide the nuclear facility owner with a greater assurance that all basic planning elements and requirements have been identified, examined, and addressed.  
4.2 In applying the guidance contained in this standard, the nuclear facility owner will address the significant subject areas necessary to describe a comprehensive decommissioning plan. Additional guidance on the planning of decommissioning projects, and the preparation of decommissioning plans can be found in such references as NUREG-1757 on decommissioning standard review plans, and Regulatory Guide 1.179 on the format and content of license termination plans. Recent new guidance on all aspects of decommissioning is contained in an ASME publication titled The Decommissioning Handbook.6  
4.3 This decommissioning plan will be developed to serve as the executive document that describes the objectives of the decommissioning program and identifies and defines the elements necessary to accomplish the program.  
4.4 A detailed implementation plan describing how the objectives of the decommissioning plan will be met should be prepared. Some of the documents or implementation plans that may be required to support the overall decommissioning program include an engineering plan; a cost, schedule, and financing plan (10 CFR 140 and 170); a field implementation plan; a health and safety plan (29 CFR 1910.120, Guide E1167); a quality assurance plan (10 CFR 50.59 and 10 CFR 830.120); an emergency plan; an environmental monitoring plan (Guide E1819); a radiological protection plan (10 CFR 20, 10 CFR 835, Guide E1167); and a physical security plan (10 CFR 73). These implementation plans shall be separate from and consistent with the decommissioning plan.
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1.1 This guide applies to decommissioning plans for any nuclear facility whose operation was (is) governed by Nuclear Regulatory Commission (NRC), Agreement State license, under Department of Energy (DOE) orders, or whose operation was overseen by another federal, state, or local agency.  
1.2 The guide applies to the preparation and content of the decommissioning plan document itself.  
1.3 The detailed description and development of implementation plans identified in Section 4 is outside the scope of this guide.  
Note 1: Nuclear facilities operated by the U.S. DOE are not licensed by the U.S. NRC, nor are other nuclear facilities which may come under the control of the U.S. Department of Defense or individual agreement states. The references in this guide to licensee, U.S. NRC Regulatory guides, and Title 10 of the U.S. Code of Federal Regulations are to imply appropriate alternative nomenclature with respect to DOE, DOD, or agreement state nuclear facilities. This distinction should not alter the content of decommissioning plans for nuclear facilities.  
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 E2421-15(2021)(Guide)
Standard Guide for Preparing Waste Management Plans for Decommissioning Nuclear Facilities

SIGNIFICANCE AND USE
4.1 A waste management plan based on the contents of this guide will provide for the successful identification of potential waste streams anticipated from decommissioning activities, and provide a clear and concise methodology for the handling of identified waste from generation to final disposition.  
4.2 The waste management plan will identify the general waste types, characterization, packaging, transportation, disposal, and quality assurance requirements for potential waste streams.
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1.1 This guide addresses the development of waste management plans for potential waste streams resulting from decommissioning activities at nuclear facilities, including identifying, categorizing, and handling the waste from generation to final disposal.  
1.2 This guide is applicable to potential waste streams anticipated from decommissioning activities of nuclear facilities whose operations were governed by the Nuclear Regulatory Commission (NRC) or Agreement State license, under Department of Energy (DOE) Orders, or Department of Defense (DoD) regulations.  
1.3 This guide provides a description of the key elements of waste management plans that if followed will successfully allow for the characterization, packaging, transportation, and off-site treatment or disposal, or both, of conventional, hazardous, and radioactive waste streams.  
1.4 This guide does not address the on-site treatment, long term storage, or on-site disposal of these potential waste streams.  
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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ASTM E1819-15(2021)(Guide)
Standard Guide for Environmental Monitoring Plans for Decommissioning of Nuclear Facilities

SIGNIFICANCE AND USE
5.1 Use of this guide will ensure that the potential impact on the surrounding environment from planned decommissioning activities has been properly assessed.  
5.2 Use of this guide will ensure that the adequacy of environmental sampling has been assessed for location, frequency, analytical techniques, and media type to monitor the environment and to detect site-related releases and their impact.
SCOPE
1.1 This guide covers the development or assessment of environmental monitoring plans for decommissioning nuclear facilities. This guide addresses: (1) development of an environmental baseline prior to commencement of decommissioning activities; (2) determination of release paths from site activities and their associated exposure pathways in the environment; and (3) selection of appropriate sampling locations and media to ensure that all exposure pathways in the environment are monitored appropriately. This guide also addresses the interfaces between the environmental monitoring plan and other planning documents for site decommissioning, such as radiation protection, site characterization, and waste management plans, and federal, state, and local environmental protection laws and guidance. This guide is applicable up to the point of completing D&D activities and the reuse of the facility or area for other purposes.  
1.2 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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