Regulatory Guide 5.21: Difference between revisions

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{{Adams
{{Adams
| number = ML003739991
| number = ML13064A082
| issue date = 12/31/1983
| issue date = 04/30/1974
| title = (Task SG 044-4), Revision 1, Nondestructive Uranium-235 Enrichment Assay by Gamma Ray Spectrometry
| title = Nondestructive Uranium-235 Enrichment Assay by Gamma-Ray Spectrometry
| author name =  
| author name =  
| author affiliation = NRC/RES
| author affiliation = US Atomic Energy Commission (AEC)
| addressee name =  
| addressee name =  
| addressee affiliation =  
| addressee affiliation =  
Line 10: Line 10:
| license number =  
| license number =  
| contact person =  
| contact person =  
| document report number = RG-5.21, Rev 1
| document report number = RG-5.021
| document type = Regulatory Guide
| document type = Regulatory Guide
| page count = 10
| page count = 7
}}
}}
{{#Wiki_filter:Revision 1 December 1983 U.S. NUCLEAR REGULATORY COMMISSION
{{#Wiki_filter:April 1974 U.S. ATOMIC ENERGY COMMISSION
                            REGULATORY GUIDE
REGULATORY GU I D E
                            OFFICEOF NUCLEAR REGULATORY RESEARCH
DIRECTORATE OF REGULATORY STANDARDS
                                                          REGULATORY GUIDE 521 (Task SG 0444)
REGULATORY GUIDE 5.21 NONDESTRUCTIVE URANIUM-235 ENRICHMENT ASSAY
                                    NONDESTRUCTIVE URANIUM-235 ENRICHMENT ASSAY
BY GAMMA-RAY SPECTROMETRY
                                                  BY GAMMA RAY SPECTROMETRY


==B. DISCUSSION==
==A. INTRODUCTION==
Section 70.51, "Material Balance, Inventory, and Records Requirements," of 10 CFR Part 70, "Special Nuclear Material,"
requires, in part, that licensees authorized to possess at any one time more than one effective kilogram of special nuclear material (SNM)
determine the material unaccounted for (MUF) and its associated limit of error (LEMUF) for each element and the fissile isotope for uranium contained in material in process. Such a determination is to be based on measurements of the quantity of the element and of the fissile isotope folr uranium.
 
The majority of measurement techniques used in SNM accountability are specific to either the element or the isotope but not to both. A combination of techniques is therefore required to determine the MUF
and LEMUF by element and by fissile isotope for
'uranium.
 
Passive gamma-ray spectrometry is a
nondestructive ýmethod for measuring the enricdment, or relative concentration, of the fihuile isotope U-235- in uranium. As such, this technique is used in conjunction with an assay for the element uranium in order to determine the amount of U-235.
 
This guide details conditions for an acceptable U-235 enrichment measurement using gamma-ray spectrometry, and prescribes procedures for operation, calibration, error analysis, and measurement control.


==A. INTRODUCTION==
. DISCUSSION
1. BASIS FOR GAMMK.RAY MEASUREMENT OF URA
The alpha decay of U-235 to Th-231 is accompanied by the emission of a prominent gamma ray at 185.7 keV
        Section 70.51, "Material Balance, Inventory, and Records Requirements," of 10 CFR Part 70, "Domestic Licensing of                      NIUM ENRICHMENT
(4.3 x 104 of these 185.7-keV gamma rays are emitted per second per gram of U.235). The relatively low energy and consequent low penetrating power of these gamma rays implies that most of those emitted within the interior of the material are absorbed within the material itself. These thick ' materials therefore exhibit a 185.7-keV gamma ray activity which approximates the activity characteristic of an infinite medium: i.e., the activity does not depend on the size or dimensions of the .material. Under these conditions, the 185.7-keV
    Special Nuclear Material," requires, in part, that licensees                                                        31 The alpha decay of 2 3 5 U to 2 Th Is accompanied by authorized to possess and use at any one time more than the emission of a prominent gamma ray at 185.7 keV
activity is directly proportional to the U-235 enrichment. A measurement of this 185.7-keV activity with a suitable detector forms the basis for an enrichment measurement technique.
    one effective kilogram of special nuclear material (SNM)
 
                                                                            (4.3 x 104 of these 185.7-keV gamma rays are emitted per determine the inventory difference (ID) and its associated second per gram of 2 3 5 U). The relatively low energy and standard error (estimator) of inventory difference (SEID)
The thickness of the material with respect to the mean free path of the 185.7-keV gamma ray is the primary characteristic which determines the applicability of passive gamma-ray spectrometry for the measurement of isotope enrichment. The enrichment technique is applicable only if the material is thick. However, in addition to the thickness of the material, other conditions must be satisfied before the gamma-ray enrichment technique can be accurately applied. An approximate analytical expression for the detected
                                                                            consequent low penetrating power of these gamma rays for each element and the fissile isotope for uranium con implies that most of the rays that are emitted in the tained in material in process. Such a determination is to be interior of the sample are absorbed within the material based on measurements of the quantity of the element and Itself. Thick2 materials therefore exhibit a 185.7-keV
185.7-keV activity is given below. This expression has been separated into several individual terms in order to aid in identifying those parameters which may interfere with the measurement. Although approximate, 'this relationship can be used to estimate the magnitude of interfering effects in order to establish limits on the range of applicability and to determine the associated uncertainties introduced into the measurement. This relationship is:
    of the fissile isotope for uranium.
'Thick"
and -thin" am used throughout this guide to refer to distances in relation to the mean free path of the 185.7 keV gammn ray in the material under consideration. The mean free path is the I/e-folding distance of the gamma-ray flux or, in other terms,'.the average distance a gamma ray traverses before interacting.


gamma ray emission characteristic of an infinite medium;
USAEC REGULATORY GUIDES
        The majority of measurement techniques used in SNM                  Le., the 185.7-keV gamma flux emitted from the sample surface does not depend upon the size or dimensions of accountability are specific to either the element or the the material. Under these conditions the 185.7-keV
Copies of pub" Id Sui*es my be obtained by request Indicating the division desired to the US. Atomic Energy Commission., WhIngon, DZC. 20546, Regulatory Guides ae issued to describe and make maildable to the public Attention: Director of Regulatory Steondaerd. Comments snd suggetions for mnthods acceptable to the AEC Regulatory staff of Implementing speciffic pats of Imlwovaetlr;s In theme guides en and id'ould be sent to tdw Secretary
    isotope but not to both. A combination of techniques Is intensity Is directly proportional to the             U enrichment.
'the Commission's regulations, to de*lls
-
dwli usd by V.w staff in of the Commission. US. Atomic Energy Commission. Washington. D.C. 2M346.


therefore required to determine the ID and SEID by element and by fissile isotope for uranium. Passive gamma ray                    A measure of this 185.7-keV intensity with a suitable
evaluating spiedfii problems or postuletiodLa:ements, or to provide guidene to Attention: Chief. Public PrFt rnis Staff.
.2                                                                            detector forms the basis for an enrichment measurement spectrometry is a nondestructive method for measuring the                technique.


enrichment
appllmnst. Rogulatory Guides ar, not substitutes fo reguletlohss and c pllanes with them is not required. Methods and tolutios dlast frosm diw a ull mt in Th guides ae issued I. tht following ten brood divisic.:
    235            or relative concentration of the fissile isotope U in uranium, but this technique is used in conjunction The thickness of the material with respect to the mean with an assay for the element uranium in order to deter free path of the 185.7-keV gamma ray is the primary mine the amount of 235 U.
the guides will be acoosoehie' If they provide a both for the fInidis guu*l*t, to the isuance or continuance of a permit or lianso by the Commission.


characteristic that determines the applicability of passive gamma ray spectrometry for the measurement of isotope This guide describes conditions for 235U enrichment enrichment. The measurement technique is applicable measurements using gamma ray spectrometry that are only If the material Is thick. However, in addition to the acceptable to the NRC staff and provides procedures for thickness of the material, other conditions must be operation, calibration, error analysis, and measurement control.' Examples of 2 3SU enrichment assays using port                  satisfied before the gamma ray measurement technique able and in-line instruments based on the techniques out                  can be accurately applied. An approximate analytical expression for the detected 185.7-keV activity is given lined in this guide may be found in References 1 through 4.
===1. Power Reactors ===


below. This expression has been separated into several indi Any guidance in this document related to information                  vidual terms to aid in identifying those parameters that may interfere with the measurement. Although approximate, collection activities has been cleared under OMB Clearance No. 3150-0009.                                                            this relationship can be used to estimate the magnitude of
===6. Products===
                                                                                    2 The terms "thick" and "thin" are used throughout this guide to refer to distances in relation to the mean free path of the. I5.7-keV
2.
          Calibration error analysis, and measurement control are dis          gamma ray in the material under consideration. The mean free path cussed in Regulatory Guide 5.53, "Qualification, Calibration, and          Isthe I/e-foldlng distance of the gamma ray flux or, in other terms, Error Estimation Methods for Nondestructive Assay." A proposed            the average distance a gamma ray traverses before Interacting.


revision to this guide has been issued for comment as Task SG 049-4.
Research end Teot Reactors


USNRC REGULATORY GUIDES                                Comments should be sent to the Sectetary            of the Commission, U.S. Nuclear Regulatory Commission. Washington, D.C. 20555, Regulatory Guides are Issued to describe and make available to the        Attention: Docketing and Service Branch.
===7. Transportation===
3.


public methods acceptable to the NRC staff of Implementing to delineate tech- specific parts of the Commission's regulations, problems                  The guides are Issued In the following ten broad divisions niques used by the staff In evaluating specific              or postu lated accidents or to provide guidance to applicants. Regulatory          1. Power Reactors                    6. Products Guides are noR substitutes for regulations, and compliance with            2. Research and Test Reactors        7. Transportation them Is not required. Methods and solutions different from those set      3. Fuels and Materials Facilities 8. Occupational Health out in the guides will be acceptable If they provide a basis for the      4. Environmental and Siting          9. Antitrust and Financial Review findings requisite to the issuance or continuance of a permit or          5. Materials and Plant Protection 10. General license by the Commission.
Fuels end Materials Fac1lit1is
8.


Copies of issued guides may be purchased at the current Government This guide was Issued after consideration of comments received from        Printing Office price. A subscription service for future guides in spe the public. Comments and suggestions for Improvements In these            cific divisions is available through the Government Printing Office.
Occupational Health Published quides will be revised perlodicallv, as appropriat


guides are encouraged at all times, and guides will be revised, as        Information on the subscription service and current GPO prices may appropriate, to accommodate comments and to reflect new Informa-          be obtained by writing the U.S. Nuclear Regulatory Commission, tion or experience.                                                        Washington, D.C. 20555, Attention: Publications Sales Manager.
====e. to accommodate ====
4. Environmental and Shing
9.


interfering effects in order to establish limits on the range of applicability and to determine the associated uncer material with a characteristic length called the critical tainties introduced into the measurement. This relationship                    distance xo, where x is defined as the thickness of material that produces 99.5 percent of the measured 185.7-keV
Antitrust Review commenn and to reflect new information or exparien.
    is:
                                                                                  activity:
          effective source of 185.7-keV
          gamma raysfseen by the detector x0 = -A ln(0.005) = S.29A                            (2)
                                                                                  where
                  ?          i""=( -..
                                    u A +W£ (Q/47r) exp(-pclicd)
                                  uuj,        I          ,,a A              (1)
                                                                                            '/A= 1UPU + z Pipi                                  (3)
                                                                                                              I
    enrich-    physical            riea]          otrica    container ment      constants      Composi-        efficiency    absorption don          I                                      Calculated values of xo for several common materials are given in Table 1.


area defined          detector by collimator        efficiency Where                                                                                                        Table 1I
5. Maerials and Plant Protectloo
                                                                                      CALCULATED VALUES OF x AND MATERIAL
1
                  C = detected 185.7-keV activity COMPOSITION fERM
                  E = enrichment of the uranium (<I)
                                                                                                                                      Material Com PU,Pi, PC= density of.the uranium (U), matrix material                                                                        position Term (i), and  container wall (c), respectively, in                                                Critical g/cm 3                                                                            Density      Distance Material        (g/cm 3 )    x 0 (cm)          1
    11U'
                                                                                                                                            I
              PC = mass attenuation coefficient for 185.7-keV
                      gamma rays in uranium (U), matrix material U (metal)          18.7          0.20          1.000
                      (i), and container wall (c) in cm 2 /g                        UF
                                                                                        6
                                                                                                          4.7          1.08          1.040
                a = specific 185.7-keV gamma ray activity of                        UO                  10.9        0.37            1.012
                      23                                                            UA 8                7.3        0.56 sU
                  = 4.3 x 104 gamma rays/sec-g Uranyl. Nitrate      2.8        2.30
                                                                                                                                      1.015
                                                                                                                                      1.09S            K.


.Values of the mass attenuation
===0. General===
                  = net absolute detector full energy peak effi                                                    coefficient, pa, may be found References 6 and 7.                                                in ciency for detecting 185.7-keV gamma rays
                      (<      1)                                                Other nondestructive assay (NDA) techniques are capable of detecting SNM distributed within a containe


====r. The enrich====
Effective source of 185.7.-ceV
                  = solidanglesubtendedby the detector(SI < 2ir)
pmrm rays men by the detector C
                                                                                ment measurement technique, however, is inherently a surface measurement. Therefore, the "sample" observed, A = cross-sectional area of material defined by I.e., the surface, must be representative of all the material in the detector collimator                                    the container. In this respect the enrichment measurement is more analogous to chemical analysis than are other NDA
E (a/tu)
                d = container wall thickness techniques.
A [I +
e (fa/4ir) e-PcIcd enrichmftnt detecor container efecien/c absorption Physical are material geometrical constants defined by composition efficiency collimator
(1)
where Pu,pi,pc AuAi, A
C = detected 185.7-keV activity E = enrichment of the uranium (. -1)
= density of the uranium (u), matrix material (i), and container wall (c), respectively, in (g/cm 3)
c = mass attenuation coefficient for 185.7-keV gamma rays in uranium (u), matrix material (i), and container wall (c) in units of (cm 2/g)
a = specific 185.7-keV gamma ray activity of U-235
= 4.3 x 104 gamma rays/sec-g e = net absolute detector full energy peak efficiency for detecting
185.7-keV gamma rays (< 1)
E2 = solid angle subtended by the detector (11 < 2w)
A = cross-sectional area of material defined by the detector collimator d = container wall thickness A derivation of this expression, as well as other necessary background information relevant to this guide, may be found in the literature. 2 As evident in Eq. 1, the activity (C) is proportional to the enrichment (E)
'but is affected by several other characteristics as well.


A derivation of this expression, as well as other necessary background information on the theory of enrichment mea
Material Thicknm Effects In order for Eq. 1 to be applicable, it is necessary that the material be sufficiently thick to produce strong attenuation of 185.7-keV gamma rays. To determine whether this criterion is met, it is useful to compare the actual thickness of the material with a characteristic length xo, where xo is defined as that thickness of material which produces 99.5% of the measured
                                                                                2.2    Material Composition surements, may be found in Reference 5. As evident in Equation 1, the activity (C) is proportional to the enrich                        If the gamma ray measurement is to be dependent only ment (E) but is affected by sqveral other characteristics as                   on the enrichment, the term related to the composition of the matrix should be approximately equal to one, Le.,
185.7-keV activity, i.e.,
well.
Calculated values of xc, the critical distance, for
.
several common materials are givn in Table 1.


2. MATERIAL AND CONTAINER WALL EFFECTS ON                                                        Pi        ~
TABLE 13 Material Density Critical Material (g/cm 3)
      MEASUREMENT                                                                                                                              (4)
Distance Composition xO lcm)
2.1     Material Thickness                                                    This condition ensures that the enrichment measurement will be insensitive to variations in the matrix composition.
'Term Pi tai
.1 +
2:-
i Pu Mu U (metal)
18.7
0.20
1.000
UF 6 
4.7
1.08
1.040
U0 2 
10.9
0.37
1,012 U308
7.3
0.56
1.015 Uranyl Nitrate
2.8
2.30
1.095 Values of the mass attenuation coefficient, A, may be found in J. H. Hubbell, "Photon Cross Sections, Atteniation Coefficients, and Energy Absorption Coefficents From 10 keV
to 100 GeV," NSRDS-NBS 29, 1969.


In order for Equation 1 to be applicable, the material However, if this matrix term differs significantly from must be sufficiently thick to produce strong attenuation of
X0
185.7-keV gamma rays. To determine whether this criterion                    unity, the enrichment measurement can still be performed provided the matrix composition of the standard and is met, it is useful to compare the actual thickness of the samples remains reasonably constant.
I n(.005) = 5.29 X
where
(2)
(3)
IA = u.u + 7- plip
2 L. A. Kull, "Guldejiws for Gamm&-gray Spectroscopy Measuremente of U-235 Enrichment," BNL-50414, July 1973.


5.21-2
5.21-2


to account for attenuation of the 185.7-keV gamma rays Calculated values of this quantity for common materials       (see Equation 5). Commercial equipment is available to are given in Table 1. The deviations of the numbers in            measure wall thicknesses ranging from about 0.025 to Table I from unity indicate that a bias can be introduced          5.0 cm with relative precisions of approximately 1.0 per
Note: Other nondestructive, techniques are capable of detecting SNM distributed within. a container. The enrichment technique, however, is inherently a surface measurement. Therefore, the "sample" observed-i.e., the surface, must be representative of all the material in the container. In this respect the enrichment mesurement is more analogous to chemical analysis than other NDA
by ignoring the difference in material composition.               cent to 0.1 percent, respectively.
techniques.
 
Material Composition Effeb If the gamma-ray measurement is to be dependent only on the enrichment, the term related to -the composition of the matrix should be approximately equal to one, i.e.,
detector. The fractional change in the measured activity AC/C due to a small change Ad in the container wall thickness can be expressed as follows:
AC--
.=
-ZcPcAd
(5$)
+ pi' L
C.
 
I;
li
-
P A
(4)
Calculted values. of this quantity for common materials are given in Table 1. The deviation of the numbers in Table I from unity indicate that a bias can'
be introduced by ignoring the difference in material composition.
 
Inhomogeneities in matrix material composition, uranium density, and uranium enridunent within the measured volume of the maierial (as chariterized by the depth xo and the collimated area A) can produce changes in the measured 185.7-keV activity and-affect v-the accuracy of an enrichment calculated on the bais of that activity. There is a small to negligble effect on the measurement accuracy due to variations in the content of low-atomic-number (Z<30) matrix materials. Care should be exercised, however, in applyin this technique to materials having.high-atomro-number matria" (Z>50)
or materials having uranium concentuations 1.
 
than approximately 75%. Inhomogeneities in uraium density will also produce small to negligible effects on the accuracy if the matrix isu of low-atomic-number elements. Sifjkuw inacraeieas cn. a.Ni, howem, when the urnium enrichment itself ce. be expected to vary throughout the sample.
 
The above , gonclusions about the effects of inhomogeneities are based on the assumption that the thickness of the material exceeds the critical distance, xo, and that the inhomogeneities exist within this depth.
 
In the case of extremely inhomogeneous materiah much as scrap, the condition of sufficient depth may not always be fulfllled,-or inhomogeneitiesmay exist beyond the depth xo; i.e., the "sample" is not representative.
 
Therefore, this technique is not applicable to such inhomogeneous materials.
 
Container Wafl Effects Variations in the thickness of the container walls
-can significantly affect the activity measured by the Calculated values of AC/C, corresponding to a change in container thickness Ad of 0.0025 cm, for common container materials, are given in Table 2.
 
TABLE 2 Material Density (g/cm 3l C
Steel
7.8
- .003 Aluminum
2.7
- .0009 Polyethylene
0.95
- .0004 Therefore, the container wall thickness should be known, e.g., by measuring an adequate number of the containers before loading. In some cases an unknown container wall thickness can be measured using an ultrasonic technique and a simple correction applied to the data to account for attenuation of the 185.7-keV
gamma rays (see eq. 5). Commercial equipment is available to measure wall thicknesses ranging from about
0.025 to 5.0 cm to relative accuracies of approximately
1.0% to 0.1%, respectively.
 
Area and Geometrical Efficiency The area of the material viewed by the detector and the geometrical efficiency are variables which may be adjusted, within limits, to optimize a system. It is important to be aware that once these variables are fixed, changes in these parameters will affect the results of the measurement.
 
It is also important to note that the placement of the material within the container will affect the detected activity. The 'material should fill the volume of the container to a certain depth, leaving no void spaces between the material and the container wall.
 
Net Deteetw Bffidncy Thallium-activated sodium iodide, NaI(T1),
scintillationw detectors and lithium-drifted germanium, Ge(LI), solid-state detectors have been used to perform these measurements. The detection systems are generally conventional gamma-ray spectrometry systems presently commercially available in modular or single-unit construction.
 
5.21,3
 
The following factors influence detector selection and the control required for accurate results.
 
1.
 
Background a.
 
Compton Background. This background is predominately produced by'the 765-keV and ICOl-keV
gamma rays of Pa-234m, a daughter of U-238. Since, in most cases, the Compton background behaves smoothly in the vicinity of the 185.7-keV peak, it can be readily subtracted, leaving only the net counts in the 185.7-keV
full-energy peak.
 
b.
 
Overlapping Peaks. The observable peak from certain gamma rays may overlap that of the 185.7-keV
peak due to the finite energy resolution of the detector;
i.e., the difference in energies may be less than twice the FWHM.
 
This problem is common in enrichment measurements of recently separated uranium from a reprocessing plant. The peak from a strong 208-keV
gamma ray from U-237 (half-life of 6.75 days)- can overlap the 185.7-keV peak when an Nal detector is used. Analytical separation of the two unresolved peaks, i.e., peak stripping, may be applied. An alternative solution is to use a Ge(Li) detector so that both peaks are clearly resolved.
 
The U-237 activity ;present in reprocessed uranium will depend on the amount of Pu-241 present before reprocessing and also on the time elapsed since separation.
 
c.
 
Ambient Background. The third source of background originates from natural sources and from other uranium-bearing materials located in the vicinity of the measuring apparatus. This last source can be particularly bothersome since it can vary with time within wide limits depending on plot operating conditions.
 
2.
 
Count-Rate LoAmes. Calculation of the detector count rates for purposes of making dead time estimates requires that one calculate the total count rate, not only that due to U-235. Total count rate estimates for low-enrichment material must therefore take into account the relatively important background from U-238 gamma rays. If other radioactive materials are present within the sample, their contributions to the total count rate must also be considered.
 
Count-rate corrections can be made by determining the dead time or by making measurements for known
4 FWHM- full width of the spectrum peak at half its maximum height.
 
live-time s intervals. The pile-up or overlap of electronic pulses is a problem which also results in a loss of counts in the full-energy peak for Ge(Li) systems. A pulser may be used to monitor and correct for these losses.
 
Radiation which provides, no useful -information can be selectively attenuated by filters; e.g., a one-millimeter- thick cadmium filter will reduce x-ray interference, eliminating this source of count-rate losses.
 
3.
 
Instability in Detector Electronics. The gain of a photomultiplier tube is sensitive to changes in temperature, count rate, and magnetic field. Provision can be made for gain checks and/or gain stabilization for enrichment measurement applications.
 
Various gain stabilizers that automatically adjust the system gain to keep a reference peak centered between two preset energy limits are available.


Inhomogeneities in matrix material composition, uranium            Using standardized containers to hold the sample mate density, and uranium enrichment within the measured                rial in order to minimize uncertainties and possible errors volume of the material (as characterized by the depth xo          associated with container-to-container wall thickness and the collimated area A) can produce changes in the              corrections is strongly recommended.
==C. REGULATORY POSITION==
Passive gamma-ray spectrometry constitutes an acceptable means for nondestructively determining U-235 enrichment, if the following conditions are satisfied:
Range of Application
1.


measured 185.7-keV activity and affect the accuracy of an enrichment calculated on the basis of that activity. Varia          3. DETECTOR-RELATED FACTORS
All material to be assayed under a certain calibration should be of similar chemical form, physical form, homogeneity, and impurity level.
    tions in the content of low-atomic-number (Z < 30) matrix materials and inhomogeneities in uranium density in such            3.1      Area and Geometrical Efficiency matrix material produce a small to negligible effect on measurement accuracy. Care is necessary, however, in                    The area of the material viewed by the detector and the applying this technique to materials having high-atomic            geometrical efficiency are variables that may be adjusted, number matrices (Z > 50) or materials having uranium                within limits, to optimize a system. Two important factors concentrations less than approximately 75 percent. Signifi          must be noted:
    cant inaccuracies can arise when the uranium enrichment itself varies throughout the sample.                                    1. Once these variables are fixed, changes in these parameters will alter the calibration of the instrument and The above conclusions about the effects of inhomogene          invalidate subsequent measurement results.


ities are based on the assumption that the thickness of the material exceeds the critical distance, xo, and that the                2. The placement of the material within the container inhomogeneities exist within this depth. In the case of            will affect the detected activity. It is important that there extremely inhomogeneous materials such as scrap, the              are no void spaces between the material and the container condition of sufficient depth may not always be fulfilled or      wall.
2.


inhomogeneities may exist beyond the depth xo; i.e., the sample is not representative. Therefore, this technique           3.2      Net Detector Efficiency is not applicable to such inhomogeneous materials.
The critical distance of the material should be determined.. Only those items of the material having dimensions greater than -this critical distance should- be assayed by this technique.


Thallium-activated sodium iodide, Nal(TI), lithium-drifted
3. The material should be homogeneous in all respects on a mnacroscopic 6 scale.- The material should be homogeneous'with respect to uranium enrichment' on a microscopic
2J  2.3    Container Wall Thickness germanium, Ge(Li), and high-purity germanium, HPGe (also referred to as intrinsic germanium, IG), detectors have been Variations in the thickness of the container walls can used to perform these measurements. The detection systems significantly affect the activity measured by the detector.
-wscale.


are generally conventional gamma ray spectrometry systems The fractional change in the activity AC/C due to a small that are commercially available in modular or single-unit change Ad in the container wall thickpess can be expressed:
4.
                                                                        construction. Some useful guidelines for the procurement
                                                              (5)        and setup of a solid-state-detector-based system are given in AC =_*lPcPcAd                                            Regulatory Guide 5.9, "Specifications for Ge(Li) Spectros3 copy Systems for Material Protection Measurements."
      Calculated values of AC/C corresponding to a change in Factors that influence detector selection and the control container thickness Ad of 0.0025 cm for common con required for accurate results are discussed below.


tainer materials are given in Table 2.
The containers should all be of similar size, geometry, and physical and chemical composition.


Table 2                                    3.2.1 Background CALCULATED VALUES OF AC/C                                  3.2.1.1 Compton Background. This background is pre dominantly produced by the 765-keV and lO01-keV
System Requirements I.
                                                                                            2 4                        2 38 AC                        gamma rays of 3 mPa, a daughter of                  U. Since in most Density cases the Compton background                behaves  smoothly in Material        (g/cm*)    C
                                                                          the vicinity  of  the  185.7-keV    peak,  it can  be readily sub;
                  Steel          7.8        -0.003                      tracted, leaving only the net counts in the 185.7-keV
                  Aluminum        2.7        -0.0009                    full-energy peak.


Polyethylene 0.95          - 0.0004
Nal('I) scintillation detectors having a resolution of FWHM < 16% at the 185.7-keV peak of' U-235 are s"Live time" means that portion of the measurement period during which the instrument can record detected events.
                                                                              3.2.1.2 Overlapping Peaks. The observable peak from certain gamma rays may overlap that of the 185.7-keV peak Therefore, the container wall thickness must be known          owing to the finite energy resolution of the detector; i.e.,
      (e~g., by measuring an adequate number of the containers
                                                                              3 J  before loading). In some cases, an unknown container wall                  A proposed revision to this guide has been issued for comment Spectros as Task SG 042-2 with the title "Guidelines for Germanium Material."
      thickness can be measured using an ultrasonic technique              copy Systems for Measurement of Special Nuclear after which a simple correction can be applied to the data
                                                                  5.21-3


the difference in energies may be less than twice the full                1-mm-thick cadmium filter will reduce x-ray interference, width of the spectrum peak at half its maximum height                    eliminating this source of count-rate losses. Note that (FWHM). This problem is common in enrichment measure                      present-day counting electronics are capable of handling ments of recently separated uranium from a reprocessing                  high negative count rates without significant losses from
Dead time refers to that portion of the measurement period during which the instrument is busy processing data already recehed anldcannot accept new dat
  3lant. The peak from a strong 208-keV gamma ray from                      either pileup or system dead time. However, if a measure
    37U (half-life of 6.75 days) can overlap the 185.7-keV
                                                                            ment situation arises in which count rates are excessive, peak when a Nal detector is used. Analytical separation of                tighter collimation of the opening on the front face of the the two unresolved peaks, i.e., peak stripping, may be                    detector is a simple method for reducing count rates to applied. An alternative solution is to use a Ge(Li) or HPGe              tolerable levels at which complicated loss corrections are detector so that both peaks are dearly resolved. The2 3U                  not essential.


activity present in reprocessed uranium will depend on the amount of 241pu present before reprocessing and also on                      3.2.3 Instability in Detector Electronics the time elapsed since separation.
====a. in order to compare====
6fferent data for which dead times are appreciable, one must compare counts measured for equal live-time periods.


The gain of a photomultiplier tube is sensitive to changes
(actual measurement period) - (dead time) = live ,time
        3.2.1.3 Ambient Background. The third source of                      in temperature, count rate, and magnetic field. Provision background originates from natural sources and from other                can be made for gain checks or gain stabilization for enrich uranium-bearing materials located in the vicinity of the                 ment measurement applications. Various gain stabilizers measuring apparatus. This source can be particularly                      that automatically adjust the system gain to keep a refer bothersome since it can vary over time within wide limits                ence peak centered between two preset energy limits are depending on plant operating conditions.                                available.
6 Macroscopic refers to distances greater than the critical distance; miuoscopic to distances les than the critical distance.


3.2.2 Count-Rate Losses                                                              . REGULATORY POSITION
5.21-4
      Calculation of the detector count rates for purposes of                  Passive gamma ray spectrometry constitutes a means making dead-time 4 estimates requires calculation of the                acceptable to the NRC staff for nondestructively determin total count rate, not only that due to 2 3 1U. Total count                ing      U enrichment, if the conditions identified below are rate estimates for low-enrichment material must therefore                satisfied.


take into account the relatively important backgrounds of gamma rays from 238V daughters. If other radioactive                      I. RANGE OF APPLICATION
generally adequate for measuring the enrichment of uranium containing more than the natural (0.71%)
  materials are present within the sample, their contributions to the total count rate must also be considered.                               All material to be assayed under a certain calibration Count-rate corrections can be made by determining the should be of similar chemical form, physical form, homo                    I'l
abundance of U-235. Crystals With a thickness of ~- 1.25 cm are recommended for optimum efficienc
                                                                    4 geneity, and impurity level.


dead time or by making measurements for known live-time intervals. The pileup or overlap of electronic pulses is a                   The critical distance o&f the material should be determined.
====y. If other====
-1- radionuclides Which emit significant quantities of gamma radiation in an energy region E = 185.7 keV +/- 2 FWHM
at 185.7 keV are present:
a.


problem that also results in a loss of counts in the full                Only those items of the material having dimensions greater energy peak for Ge(Li) systems. An electronic pulser may                  than this critical distance should be assayed by this technique.
A higher-resolution detector. e.g., Ge(Li),
should be used, or b.


be used to monitor and correct for these losses. However, a more reliable method involves the use of a radioactive                        The material should be homogeneous in all respects on a source fixed to the detector in an invariant geometry.                    macroscopics scale. The material should be homogeneous A photopeak area from the spectrum of this source is                      with respect to uranium enrichment on a microscopics counted along with a uranium peak area. The source peak                  scale.
A peak stripping procedure should be used to subtract the interference. In this case, data should be provided to. show the range of concentration of -the interfering radionuclide, and the accuracy and precision of the stripping technique over this range.


area can then be compared with an earlier value taken without uranium present, and the dead time for the assay                      The containers should all be of similar size, geometry, measurement can be inferred. (Part of the regular measure                and physical and chemical composition.
2.


ment control would then involve uranium-free measurement of
The detection system gain should be stabilized by monitoring a known reference peak.
  241 the source peak area.) One possible source could be                   


===2. SYSTEM REQUIREMENTS===
3. The system should measure live time or provide a means of determining the count-rate losses based on the total counting rate.
        Am, whose 60-keV gamma ray peak would be easily resolved from the uranium lines by either a Ge- or Nal-based                  NaI(TI) scintillation detectors having a resolution of system. If filtering of ambient low-energy gamma radiation                FWHM less than 16 percent at the 185.7-keV peak of 2 3 5 U
is used, the 24 1 Am source can be placed between the                    are generally adequate for measuring the enrichment of detector and the absorber used for the filtering. If a high              uranium. Crystals with a thickness in the range of 1.3 to resolution system is used, the recommended source for                    1.8 cm are recommended for optimum efficiency. If other this purpose is 10 9 Cd, which emits only an 88-keV peak,                radionuclides that emit significant quantities of gamma well below the uranium (185.7-keV) region, and has a                      radiation in an energy region E = 185.7 keV +/- 2 FWHM at half-life of 453 days. Radiation that provides no useful                  185.7 keV are present, one of the following should be used:
information can be selectively attenuated by filters; e.g., a
    4
      "Dead time" refers to that portion of the measurement period            a. A higher resolution detector, e.g., Ge(Li) or HPGe, or during which the instrument Is busy processing data already received and cannot accept new data. "Live time" means that portion of the measurement period during which the instrument can record detected K
events. To compare different data for which dead times are appreci              5 lMacroscople refers to distances greater than the critical distance;
able, compare counts measured for equal live-time periods, Le.,
(actual measurement period) - (dead time) = live time.                      microscopic to distances less than thi critical distance.


5.214
4.


Calibration) should be determined and the position of b. A peak-stripping procedure to subtract the interfer ence. In this case', data 'should be provided to show the                the 185.7-keV peak and neighboring peaks noted. The range of concentration' of the interfering radionuclide and              threshold and width of each energy region should then be the accuracy and precision of the stripping technique over              selected to avoid including any neighboring peaks and to this range.                                                              optimize the system stability and the signal-to-background ratio.
Design of the system should allow reproducible positioning of the detector or item being assayed..
5. The system should be capable of determining the gamma-ray activity in at least two energy regions to allow background subtraction. One region should encompass 185.7 keV, and the other region should be above this but not overlapping. The threshold and width of the regions should be adjustable.


The detection system gain should be stabilized by The net response attributed to 185.7-keV gamma rays monitoring a known reference peak.
6.


should be the accufnulated counts in the peak region minus The system clock should be in live time. The system                a multiple of the counts accumulated in a nearby back should provide a means of determining the count-rate losses              ground region. A single upper background region may be based on the total counting rate, or provide additional                  monitored, or both a region above the peak region and one collimation to reduce the count rate.                                    below may be monitored. If only an upper background region is monitored, the net response, R, is giyen by The design of the system should allow reproducible positioning of the detector or item being assayed.                                      R - G abB.
The &#xfd;system should have provisions for filtering low-energy radiation which could interfere with the
185.7-keV or background regions.


The system should be capable of determining the gamma              where G and B are the gross counts in the peak region and ray activity in at least two energy regions to allow subtrac            the background region, respectively, and b is the multiple tion of the background. One region should encompass                      of the background to be subtracted. This net response, R,
Data Reduction I. if the total counting rate is determined primarily by the 185.7-keV gamma ray, the counting rate should be restricted (absorbers, decreased geometrical efficiency)
185.7 keV, and the other should be above this region but                should then be proportional to the enrichment, E:
below those rates requiring correction. The system sensitivity will be reduced by these measures and, if no longer adequate,' separate calibrations should be made in two or more enrichment regions.
should not overlap it. The threshold and, width of the regions should be adjustable. If dead-time corrections are                              E =CIR - C(G - bB)
measured with a pulser or source peak, a third and fourth region will have to be defined to establish the additional                where C1 is a calibration constant to be determined (see peak area and its background.                                            Regulatory Position 4, Calibration). The gross counts, G
                                                                          and B, should be measured for all the standards. The The system should have provision for filtering out                  quantities G/E should then be plotted as a function of the low-energy radiation from external sources.                              quantities B/E anda straight line through the data determined:
3. DATA ACQUISITION                                                                    G/E =b(B/E) + I/C1 Initial preparation of the assay instrumentation for data            The slope of this line is b, the multiple of the upper back acquisition should involve careful determination of the                  ground region to be subtracted. The data from all the system energy gain, the position of key photopeak and                    standards should be used in determining this slope.


background regions, and the instrument response to cali bration. However, after the proper instrument settings are                  If both an upper and a lower background are monitored, established, routine operation can involve a less detailed              the counts in each of these regions should be used to check of the peak positions. This verification can consist of            determine a straight-line fit to the background. Using this either a visual check of the gamma ray spectrum on a                    straight-line approximation, the area or number of counts multichannel analyzer or a brief scan of the 140- to 200-keV            under this line in the peak region should be subtracted from energy region with a single-channel analyzer. Verification              the gross counts, G, to obtain the net response. An adequate that the 185.7-keV peak position correspondi to its~value at,            technique based on this principle Is described in Reference 8.
Ifrthe total counting rate is determined primarily by events other than those due to 185.7-keV gamma rays, counting rate corrections should be made.


calibration ensures that the instrument is still biased properly.        On a number of recently developed portable gamma ray Verification of the 185.7-keV count rate with a uranium                  spectroscopy instruments, these calibration procedures can check source can also demonstrate continued validity of the             be performed automatically by means of a microprocessor response calibration. In some cases it may be useful to                  based computational capability built into the instrument or check the position of two peaks in the tammanray spectrum,              by a calculator. In such cases, the more reliable procedure in which case a 5 7Co gamma ray source (with a photopeak                of complete calibration of the instrument before each assay at 122 keV) would be convenient.                                        session may be practical.
2. To determine the location and width of the
185.7-keV peak region and the background region(s),
the energy spectrum from each calibration standard (see Calibration, next section) should be determined and the position of the 185.7-keV peak and neighboring peaks noted. The threshold and width of each energy region should then be selected to avoid including any neighboring peaks, and to optimize the system stability and the signal-to-background ratio.


If the total counting rate is determined primarily by the           
3.


===4. CALIBRATION===
The net response attributed to 185.7-keV gamma rays should be the accumulated counts in the peak region minus a multiple of the counts accumulated in a nearby background region(s). A single upper background region may be monitored or both a region above the peak region and one below may be monitored.
  185.7-keY gamma ray, the counting rate should be restricted (e.g., by absorbers or decreased geometrical efficiency)                     Calib&#xfd;ation 6 standards should be obtained by:
  below those rates requiring correction. The system sensitivity will be reduced by these measures, and, if the sensitivity is                1. Selecting items from the production material. A
no longer adequate, separate calibrations should be made in              group of the items selected should, after determination of two or more enrichment regions.


6 To determine the location and width of the 185.7-keV                    'None of the calibration techniques or data reduction procedures peak region and the background regions, the energy spectrum              discussed precludes the use of automated direct-readout systems for operation. The procedures described In this guide should be used for from each calibration standard (see Regulatory Position 4,               adjustment and calibration of direct-readout instruments.
If only an upper background region is monitored, the net response, R, should be given by R = G-bB
where G and B are the gross counts in the peak region and the background region, respectively, and b is the multiple of the background to be subtracted. This net response, R, should then be proportional to the enrichment, E, given by E = C, R = C, (G-bB)
where C, is a calibration constant to be determined (see Calibration, next section). The gross counts, G and B,
should be measured for all the standards. The quantities G/E should then be plotted as a function of the quantities B/E and the slope of a straight line through the data determined. This slope is b, the multiple of the upper background region to be subtracted, i.e..
G/E = b(B/E) + I/CI
The data from all the standards should be used in determining this slope.


5.21-5
If both an upper and a lower background are monitored, the counts in each of these regions should be used to determine a straight line fit to the background.
 
Using this straight line approximation, the area or number of counts under this line in the peak region should be subtracted from the gross counts, G. to obtain the net response. An adequate technique based on this principle is described in the literature.
 
Calibration s
1. Calibration standards should be obtained by:
a.


the gamma ray response, be measured by an independent,               S. OPERATIONS
Selecting items from the production material. A
  more accurate technique, e.g., mass spectrometry, that is traceable to or calibrated with National Bureau of Standards            . The measurement of enrichment involves counting the (NBS) standard reference material. The other items should            185.7-keV gamma ray intensity from an infinite thickness be retained as working standards.                                   of uranium-bearing material in a constant counting geometry.
group of the items selected should, after determination G. Gunderson, 1. Cohen, M. Zucker, "Proceedings: 13th Annual Meeting, Institute of Nuclear Materials Management,"
Boston, Mass. (1972) p. 221.


A schematic of the counting geometry is given in Figure 1.
" None of the calibration techniques or data reduction procedures exclude the use of automated direct-readout systems for operation. The procedures described in this guide should be used for adjustment and calibration of direct-readout instruments.


2. Fabricating standards that represent the material to          The detector should be collimated and shielded from be assayed in chemical form, physical form, and impurity            ambient radiation so that, as much as possible, only the level. The 235U enrichment of the material used in the              radiation from the sample container is detected.
5.21-5


fabrication of the standards should be determined by a technique, e.g., mass spectrometry, that is traceable to or               The detection system and counting geometry (i.e.,
of the gamma-ray response, be measured by an independent, more accurate technique traceable to, or calibrated with, NBS standard reference material, e.g.,
  calibrated with NBS standard reference material.                     collimator opening area, A, and collimator depth, x), the data reduction technique, and the count-rate loss corrections, The containers for the standards should have a geometry,        if included, should be Identical to those used in the calibration.
mass spectrometry. The other items should be retained as working standards.


dimensions, and a composition that approximate the mean of these parameters in the containers to be assayed. However,            Data from all measurements should be recorded in an it should be emphasized that the best procedure is to                appropriate log book.
b.


standardize the, sample containers to minimize, if not eliminate, container-to-container differences.                            At least two working standards should be measured during each eight-hour operating shif
Fabricating standards which represent the material to be assyed in chemical form, physical form, homogeneity, and impurity level. TheU-235 enrichment of the material used in the fabrication of the standards should be determined by a technique traceable to, or calibrated with, NBS standard reference material, e.g.,
mass spectrometry.


====t. The measured====
2.
      3. The values of enrichment for the calibration standards        response should be compared to the expected response should span the range of values encountered in normal                (value used in calibration) to determine if the difference
                                                                                                                                          7 operation. No less than three separate standards should be          exceeds three times the expected standard deviation. If used. (Good calibration practice dictates the use of at least        this threshold is exceeded, measurements should be repeated two standards to determine the linear calibration constants          to verify that the response is significantly different and that and a third standard to check the calibration computations.)        the system should be recalibrated. In the event of a significant However, if the assay response (after application of appro          change in the instrument response, every effort should be priate corrections) can be shown to be highly linear and to          made to understand the underlying cause of the change have zero offset (i.e., zero response for zero enrichment),          and, if possible, to remedy the cause rather than simply it may be more advantageous to avoid using standards with            calibrate around the problem.


low enrichment because the low count rates would reduce the calibration precision. In such a case, calibration in the            Prior to counting, all containers should be agitated. If upper half of the range of expected enrichments combined            this is not possible, the material should be mixed by some with the constraint of zero response for zero enrichment            method. One container from every ten should be measured can produce a higher precision calibration than a fitting of        at two different locations on the container. The others may                K
The containers for the standards should have a geometry, dimensions, and composition which approximate the mean of these parameters in the containers to be assayed.
standard responses over the full range of expected enrich            be measured at only one location. (If containers are scanned ments, including values at low enrichment. If such a cali            to obtain an average enrichment, the degree of inhomogeneity bration procedure is used, careful initial establishment of          should still be measured by this method.)
the zero offset and instrument linearity, followed by occasional verification of both assumptions, is strongly                  The difference between the measurements at different recommended. Such verification could be accomplished by              locations on the container should be used to indicate a lack an occasional extended measurement of a low-enrichment              of the expected homogeneity. If the two responses differ standard. It should be noted that if the measurement                by more than three times the expected standard devia-.
system exhibits a nonzero offset (i.e., a nonzero response          tion (which should include the effects of the usual or for zero sample enrichment), this is an indication of a              expected inhomogeneity), measurements should be repeated background problem that should be corrected before assays            to verify the existencen of an abnormal inhomogeneity. If are performed.                                                      the threshold is exceeded, the container should be rejected and investigated to determine the cause of the abnormal Each standard should be measured at a number of                  inhomogeneity.8 different locations, e.g., for a cylinder, at different heights and rotations about the axis. The mean of these values                    The container should be viewed at such a position that should be used as the response for that enrichment. The              an infinite thickness of material fills the field of view dispersion in these values should be used as an initial              defined by the collimator and detector (see Figure 1). The estimate of the variance due to material and container              procedure for determining the fill of the container should inhomogeneity.                                                      be recorded, e.g., by visually inspecting at the time of filling and recording on the container tag.


In general, the data from the standards, i.e., the net responses attributed to the 185.7-keV gamma rays from the known uranium enrichments, can be employed in a simple                    7 The user can always have a stricter criterion. This is a minimum.
3.


linear calculation of the two calibration constants as described in Appendix 3 of Reference 5. If desired, more                  SThe difference may also be due to a large variation in wall involved least-squares techniques can also be used.                  thickness.
The values of enrichment for the calibration standards should span the range of values encountered in normal operation. No less than three separate standards should be used.


5.21-6
4.
 
Each standard should be measured at a number of different locations, e.g., for a cylinder, at different heights and rotations about the axis. The mean of these values should be used as the response for that enrichment. The dispersion in these values should be used as an initial estimate of the error due to material and container inhomogeneity.


SCHEMATIC OF ENRICHMENT MEASUREMENT
5.
                                                          SETUP
                                                                                                                                  (
                                                            FIGURE 1 A schematic of a typical detector/collimator arrangement for a uranium enrichment measurement. The collimator depth (crucial in the calibration of the enrichment instrument) is denoted by x, the distance from the container surface to the collimator opening by r, and the container wall thickness by d. As long as an infinite thickness of assay material is contained
2 in the field of view of the detector, the distance r is not crucial. However, the preferred enrichment measurement setup is with the collimator opening in contact with the container surface (i.e., r = 0).
                                                              5.21-7


The container wall thickness should be measured. The The measurement-to-measurement variance should be wall thickness and location of the measurement should be determined by periodically observing the net response indicated if the individual wall thickness measurements and                                                                  from the standards and repeating measurements on selected the gamma ray measurement are made at this location. If process items. Each repeated measurement should be made the containers are nominally identical, an adequate sampling of these containers should be sufficient. The mean of the at a different location on the container surface, at different times of the day, and under different ambient conditions.9 K
The data from the standards, i.e., the net response attributed to 185.7-keV gamma rays and the known uranium enrichment, should be used to determine the constants in a calibration function by a weighted least-squares technique.
  measurements on these samples constitutes an acceptable The standard deviation should be determined and any measured value of the wall thickness that may be applied to trends (e.g., trends due to time or temperature) corrected all containers of this type or category.


for.
Operations
1. The detection system and counting onometry (collimator and container-to-detector distance) should be identical to those used in calibration.


The energy spectrum from a process item selected at The item-to-item variance due to the variation in wall random should be used to determine the existence of thickness should be determined. The variance in the con unexpected interfering radiations and the approximate tainer wall thickness should be determined from measure magnitude of the interference. This test should be per ments of the sample container wall thickness, either during formed at a frequency that will ensure testing:                  the course of the assays or from separate measurements of randomly selected samples. The computed variance in the
2. The data reduction technique and count-rate loss corrections, if included, should be identical to those used in calibration.
      1. At least one item in any new batch of material.


samples should be used as the variance of wall thickness.
3.


This variance should be multiplied by the effect of a unit
Data from all measurements should be recorded in an appropriate log book.
      2. At least one item if any changes in the material          variation in that thickness on the measured 185.7-keV (see, processing occur.                                                  e.g., Table 2) response to determine its contribution to the total measurement variance.


3. At least one item per two-month period.
4.


Item-to-item variations other than those measured, e.g.,
At least two working standards, should be measured during each eight-hour operating shift. The measured response should be&#xfd; compared to the expected response (value used in calibration) to determine if the difference exceeds three times the expected standard deviation. If this threshold is exceeded, repeat measurements should be made to verify that the response is significantly different and that the system should be recalibrated.
    If an interference appears, either a higher resolution        wall thickness, should be determined by periodically (see detector should be acquired or an adequate peak-stripping          guidelines in Regulatory Position 5) selecting an item and routine applied. In both cases, additional standards that          determining the enrichment by an independent technique include the interfering radiations should be selected and the traceable to, or calibrated with, NBS standard reference system should be recalibrated.                                    material. A recommended approach is to adequately sample and determine the 2 3SU enrichment by calibrated mass No item should, be assayed if the measured response spectrometry. In addition to estimating the standard devia exceeds that of the highest enrichment' standard by more tion of these comparative measurements, the data can also than twice the standard deviation in the response from this be used to verify the continued stability of the instrument standard.


calibration. If any significant deviation of the calibration is noted from these comparisons, the cause of the change K
5.
6. ERROR ANALYSIS,
                                                                  should be identified before further assays are performed.


A regression or analysis-of-variance technique should be used to determine the uncertainty in the calibration con              9 The variance due to counting (including background) and variance due to lnhomogenelty, ambient conditions, etc., will the be stants.                                                            included In this measurement-to-measurement variance.
All containers should be agitated, or the material mixed in some manner, if possible, prior to counting.


K1
One container from every ten should be measured at two different locations. Other items may be measured at only one position. (If containers am scanned to obtain an average -enrichment, the degree of inhomogeneity should still be measured by this method.)
                                                            5.21-8
The difference between the measurements at different locations should be used to indicate a lack of the expected homogeneity. If the two responses differ by more than three times the expected standard deviation (which should include the effects of the usual or expected inhomogeneity),
repeat measurements should be made to verify that an abnormal inhomogeneity exists. If the threshold is exceeded, the container should be rejected and investigated to determine the cause of the abnormal inhomogeneity. 9
6.


REFERENCES
In the event that all containers are not filled to a uniform height, the container should be viewed at a position such that material fills the entire volume viewed by the detector. The procedure for determining the fill of the container should be recorded' e.g., by visual inspection at the time of filling and recording on the container tag.
1. R. B. Walton et al., "Measurements of UF 6 Cylinders            5. L. A. Kull, "Guidelines for Gamma-Ray Spectroscopy with Portable Instruments," Nuclear Technology, Vol. 21,            Measurements of 2 3 sU Enrichment," Brookhaven p. 133, 1974.                                                       National Laboratory, BNL-50414, March 1974.


2. T. D. Reilly et al., "A Continuous In-Line Monitor for          6. J. H. Hubbell, "Photon Cross Sections, Attenuatim UF Enrichment," Nuclear Technology, Vol. 23, p. 318,              Coefficients, and Energy Absorption Coefficients from
7. The container wall thickness should be measured.
    19A4.                                                              10 keV to 100 GeV," National Bureau of Standards, NSRDS-NBS 29, 1969.


3. P. Matussek and H. Ottmar, "Gamma-Ray Spectrom etry for In-Line Measurements of 2 3 5 U Enrichment            7. E. Storm and H. I. Israel, "Photon Cross Sections from in a Nuclear Fuel Fabrication Plant," in Safeguarding              .001 to 100 MeV.for Elements I through 100," Los NuclearMaterials, IAEA-SM-201/46, pp.223-233, 1976.                 Alamos Scientific Laboratory, LA-3753, 1967.
The wall thickness and location of the measurement should be indicated, if individual wall thickness measurements are made, and the gamma-ray measurement made at this location. If the containers are nominally identical, an adequate sampling of these containers should be representative. The mean of the measurements on these samples constitutes an acceptable measured value of the wall thickness which may be applied to all containers of this type or category.


Available from the International Atomic Energy Agency, UNIPUB, Inc., P.O. Box 433, New York, New York
8.
    10016.                                                        8. G. Gunderson and M. Zucker, "Enrichment Measure ment in Low Enriched 2 3 SU Fuel Pellets," in "Proceed
4. R. B. Walton, "The Feasibility of Nondestructive Assay              ings: 13th Annual Meeting," Journal of the Institute Measurements in Uranium Enrichment Plants," Los                    of Nuclear Materials Management, Vol. 1, No. 3, p. 221, Alamos Scientific Laboratory, LA-7212-MS, 1978.                    1972.


BIBLIOGRAPHY
The energy spectrum from a process item selected at random should be used to determine the existence of unexpected interfering radiations and the approximate magnitude of the interference. The frequency of this test should be determined by the following guidelines:
Alvar, K., H. Lukens, and N. Lurie, "Standard Containers              This report contains a wealth of information on for SNM Storage, Transfer, and Measurement," U.S.                    nondestructive assay techniques and their asso Nuclear Regulatory Commission, NUREG/CR-1847, 1980.                    ciated instrumentation and has an extensive Available through the NRC/GPd Sales Program, U.S.                      treatise on gamma ray enrichment measurements.
a.


Nuclear Regulatory Commission, Washington, D.C. 20555.
At leat one item in any new batch of material.


This report describes the variations of container              Sher, R., and S. Untermeyer, "The Detection of Fission properties (especially wall thicknesses) and their            able Materials by Nondestructive Means," American Nuclear effects on NDA measurements. A candidate list                  Society Monograph, La Grange Park, Illinois, 1980.
b.


of standard containers, each sufficiently uniform to cause less than 0.2 percent variation in assay results, is given, along with comments on the                     This 1Iook contains a helpful overview of a wide value and impact of container standardization.                    variety of nondestructive assay techniques, including enrichment measurement by gamma ray Augustson, R. H., and T. D. Reilly, "Fundamentals of                  spectrometry. In addition, it contains a rather Passive Nondestructive Assay of Fissionable, !Material,"              extensive discussion of error estimation, measure Los Alamos Scientific Laboratory, LA-5651-M, Albuquerque,            ment control techniques, and measurement New Mexico, 1974.                                                    statistics.
At ieast one item if any chanps in the material procesing occur.


5.21-9
c. At least one item per material balance period.


VALUE/IMPACT STATEMENT
If an interference appears, either a higher-resolution detector must be acquired or an adequate peak stripping routine applied. In both cases additional standards which include the interfering radiations should be selected and the system recalibrated.
1. PROPOSED ACTION                                                  1.3.4 Public
1.1    Description                                                    No impact on the public can be foreseen.


Licensees authorized to possess at any one time more          1.4  Decision on Proposed Action than one effective kilogram of special nuclear material (SNM) are required in &sect; 70.51 of 10CFR Part 70 to                    The guide should be revised to reflect improvements in determine the inventory difference (ID) and the associated        technique and to bring the guide. into conformity with standard error (SEID) for each element and the fissile            current usage.
The difference nmy also be due to a large variation in wall thickness.


isotope of uranium contained in material in process. The determination is made by measuring the quantity of the element and of the fissile isotope for uraniu
Il
5.21-6


====m.     ====
9.


===2. TECHNICAL APPROACH===
No item should be assayed if the mesured response exceeds that of the highest enrichment standard by more than tvice the standard deviation in the reponse from this standard.
    It is not usually possible to determine both element              Not applicable.


and isotope with one measurement. Therefore, a combina tion of techniques is required to measure the SNM ID and the SEID by element and by fissile isotope. Passive gamma         
Error Anysis I.


===3. PROCEDURAL APPROACH===
A least4quares technique should be used to determine the uncertainty in the calibration constants.
ray spectroscopy is a nondestructive method for measuring the relative concentration of the fissile isotope 2 3 5 U in          Of the alternative procedures considered, revision of uranium. This technique is then used in conjunction with          the existing regulatory guide was selected as the most an assay for the element uranium to determine the amount          advantageous and cost effective.


of 2 3 5 U.
2.


Regulatory Guide 5.21 describes conditions for 23SU          4. STATUTORY CONSIDERATIONS
The measurement.to-measurement error should be determined by periodically observing the net response from the standards and repeating measurements on selected process items. Each repeat measurement should be made at a different location on the container surface, at different times of the day, and under differing ambient conditions.' "The standard deviation should be determined and any systematic trends corrected for.
enrichment measurements using gamma ray spectroscopy that are acceptable to the NRC staff. The proposed action        4.1    NRC Authority will revise the guide to conform to current usage and to add information on the state of the art of this technique.            Authority for the proposed action is derived from the Atomic Energy Act of 1954, as amended, and the Energy
1.2    Need                                                      Reorganization Act of 1974, as amended, and implemented through the Commission's regulations.


The proposed action is needed to bring Regulatory Guide 5.21 up to date.
'
The statistical error due to counting (Including backipound) and the erron due to inhomopamsity, ambient conditions, etc. will be include in this measurement- to-measurement error.


4.2    Need for NEPA Assessment
3.
1.3     Value/Impact Assessment The proposed action is not a major action that may
    1.3.1 NRC Operations                                          significantly affect the quality of the human environment and does not require an environmental impact statement.


The experience and improvements in technology that have occurred since the guide was issued will be made available for use in the regulatory process. Using these          S. RELATIONSHIP TO OTHER EXISTING OR
The item-to-item error due to the uncertainty in wall thickness should be determined. The uncertainty in the wall thickness may be the standard deviation about the mean computed from measurements on randomly selected samples, or it may be the uncertainty in the thickness measurement of individual containers. This uncertainty in wall thickness should be multiplied by the effect of a unit variation in wall thickness on the measured
updated techniques should have no adverse impact.                      PROPOSED REGULATIONS OR POLICIES
185.7-keV
    1.3.2 Other Government Agencies                                  The proposed action is one of a series of revisions of existing regulatory guides on nondestructive assay Not applicable.                                               techniques.
response to determine this component uncertainty.


1.3.3 Industry
4. Item-to-item errors other that those measured, e.g.,
                                                                  6. SUMMARY.AND CONCLUSIONS
wall thickness, should be determined by periodically (see guidelines in paragraph 8. of the Operation Section)
    Since industry is already applying the techniques discussed in the guide, updating these techniques should              Regulatory Guide 5.21 should be revised to bring it up have no adverse impact.                                          to date.
selecting an item and determining the enrichment by an independent technique traceable to, or calibrated with, NBS
standard reference material. A recommended approach is to adequately sample and determine the U-235 enrichment by calibrated mass spectrometry. In addition to estimating the limit of error from these comparative measurements, the data should be added to the data used in the original calibration and new calibration constants determined.


5.21-10}}
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Nondestructive Uranium-235 Enrichment Assay by Gamma-Ray Spectrometry
ML13064A082
Person / Time
Issue date: 04/30/1974
From:
US Atomic Energy Commission (AEC)
To:
References
RG-5.021
Download: ML13064A082 (7)
v  d  e


April 1974 U.S. ATOMIC ENERGY COMMISSION

REGULATORY GU I D E

DIRECTORATE OF REGULATORY STANDARDS

REGULATORY GUIDE 5.21 NONDESTRUCTIVE URANIUM-235 ENRICHMENT ASSAY

BY GAMMA-RAY SPECTROMETRY

A. INTRODUCTION

Section 70.51, "Material Balance, Inventory, and Records Requirements," of 10 CFR Part 70, "Special Nuclear Material,"

requires, in part, that licensees authorized to possess at any one time more than one effective kilogram of special nuclear material (SNM)

determine the material unaccounted for (MUF) and its associated limit of error (LEMUF) for each element and the fissile isotope for uranium contained in material in process. Such a determination is to be based on measurements of the quantity of the element and of the fissile isotope folr uranium.

The majority of measurement techniques used in SNM accountability are specific to either the element or the isotope but not to both. A combination of techniques is therefore required to determine the MUF

and LEMUF by element and by fissile isotope for

'uranium.

Passive gamma-ray spectrometry is a

nondestructive ýmethod for measuring the enricdment, or relative concentration, of the fihuile isotope U-235- in uranium. As such, this technique is used in conjunction with an assay for the element uranium in order to determine the amount of U-235.

This guide details conditions for an acceptable U-235 enrichment measurement using gamma-ray spectrometry, and prescribes procedures for operation, calibration, error analysis, and measurement control.

. DISCUSSION

The alpha decay of U-235 to Th-231 is accompanied by the emission of a prominent gamma ray at 185.7 keV

(4.3 x 104 of these 185.7-keV gamma rays are emitted per second per gram of U.235). The relatively low energy and consequent low penetrating power of these gamma rays implies that most of those emitted within the interior of the material are absorbed within the material itself. These thick ' materials therefore exhibit a 185.7-keV gamma ray activity which approximates the activity characteristic of an infinite medium: i.e., the activity does not depend on the size or dimensions of the .material. Under these conditions, the 185.7-keV

activity is directly proportional to the U-235 enrichment. A measurement of this 185.7-keV activity with a suitable detector forms the basis for an enrichment measurement technique.

The thickness of the material with respect to the mean free path of the 185.7-keV gamma ray is the primary characteristic which determines the applicability of passive gamma-ray spectrometry for the measurement of isotope enrichment. The enrichment technique is applicable only if the material is thick. However, in addition to the thickness of the material, other conditions must be satisfied before the gamma-ray enrichment technique can be accurately applied. An approximate analytical expression for the detected

185.7-keV activity is given below. This expression has been separated into several individual terms in order to aid in identifying those parameters which may interfere with the measurement. Although approximate, 'this relationship can be used to estimate the magnitude of interfering effects in order to establish limits on the range of applicability and to determine the associated uncertainties introduced into the measurement. This relationship is:

'Thick"

and -thin" am used throughout this guide to refer to distances in relation to the mean free path of the 185.7 keV gammn ray in the material under consideration. The mean free path is the I/e-folding distance of the gamma-ray flux or, in other terms,'.the average distance a gamma ray traverses before interacting.

USAEC REGULATORY GUIDES

Copies of pub" Id Sui*es my be obtained by request Indicating the division desired to the US. Atomic Energy Commission., WhIngon, DZC. 20546, Regulatory Guides ae issued to describe and make maildable to the public Attention: Director of Regulatory Steondaerd. Comments snd suggetions for mnthods acceptable to the AEC Regulatory staff of Implementing speciffic pats of Imlwovaetlr;s In theme guides en and id'ould be sent to tdw Secretary

'the Commission's regulations, to de*lls

-

dwli usd by V.w staff in of the Commission. US. Atomic Energy Commission. Washington. D.C. 2M346.

evaluating spiedfii problems or postuletiodLa:ements, or to provide guidene to Attention: Chief. Public PrFt rnis Staff.

appllmnst. Rogulatory Guides ar, not substitutes fo reguletlohss and c pllanes with them is not required. Methods and tolutios dlast frosm diw a ull mt in Th guides ae issued I. tht following ten brood divisic.:

the guides will be acoosoehie' If they provide a both for the fInidis guu*l*t, to the isuance or continuance of a permit or lianso by the Commission.

1. Power Reactors

6. Products

2.

Research end Teot Reactors

7. Transportation

3.

Fuels end Materials Fac1lit1is

8.

Occupational Health Published quides will be revised perlodicallv, as appropriat

e. to accommodate

4. Environmental and Shing

9.

Antitrust Review commenn and to reflect new information or exparien.

5. Maerials and Plant Protectloo

1

0. General

Effective source of 185.7.-ceV

pmrm rays men by the detector C

E (a/tu)

A [I +

e (fa/4ir) e-PcIcd enrichmftnt detecor container efecien/c absorption Physical are material geometrical constants defined by composition efficiency collimator

(1)

where Pu,pi,pc AuAi, A

C = detected 185.7-keV activity E = enrichment of the uranium (. -1)

= density of the uranium (u), matrix material (i), and container wall (c), respectively, in (g/cm 3)

c = mass attenuation coefficient for 185.7-keV gamma rays in uranium (u), matrix material (i), and container wall (c) in units of (cm 2/g)

a = specific 185.7-keV gamma ray activity of U-235

= 4.3 x 104 gamma rays/sec-g e = net absolute detector full energy peak efficiency for detecting

185.7-keV gamma rays (< 1)

E2 = solid angle subtended by the detector (11 < 2w)

A = cross-sectional area of material defined by the detector collimator d = container wall thickness A derivation of this expression, as well as other necessary background information relevant to this guide, may be found in the literature. 2 As evident in Eq. 1, the activity (C) is proportional to the enrichment (E)

'but is affected by several other characteristics as well.

Material Thicknm Effects In order for Eq. 1 to be applicable, it is necessary that the material be sufficiently thick to produce strong attenuation of 185.7-keV gamma rays. To determine whether this criterion is met, it is useful to compare the actual thickness of the material with a characteristic length xo, where xo is defined as that thickness of material which produces 99.5% of the measured

185.7-keV activity, i.e.,

Calculated values of xc, the critical distance, for

.

several common materials are givn in Table 1.

TABLE 13 Material Density Critical Material (g/cm 3)

Distance Composition xO lcm)

'Term Pi tai

.1 +

2:-

i Pu Mu U (metal)

18.7

0.20

1.000

UF 6

4.7

1.08

1.040

U0 2

10.9

0.37

1,012 U308

7.3

0.56

1.015 Uranyl Nitrate

2.8

2.30

1.095 Values of the mass attenuation coefficient, A, may be found in J. H. Hubbell, "Photon Cross Sections, Atteniation Coefficients, and Energy Absorption Coefficents From 10 keV

to 100 GeV," NSRDS-NBS 29, 1969.

X0

I n(.005) = 5.29 X

where

(2)

(3)

IA = u.u + 7- plip

2 L. A. Kull, "Guldejiws for Gamm&-gray Spectroscopy Measuremente of U-235 Enrichment," BNL-50414, July 1973.

5.21-2

Note: Other nondestructive, techniques are capable of detecting SNM distributed within. a container. The enrichment technique, however, is inherently a surface measurement. Therefore, the "sample" observed-i.e., the surface, must be representative of all the material in the container. In this respect the enrichment mesurement is more analogous to chemical analysis than other NDA

techniques.

Material Composition Effeb If the gamma-ray measurement is to be dependent only on the enrichment, the term related to -the composition of the matrix should be approximately equal to one, i.e.,

detector. The fractional change in the measured activity AC/C due to a small change Ad in the container wall thickness can be expressed as follows:

AC--

.=

-ZcPcAd

(5$)

+ pi' L

C.

I;

li

-

P A

(4)

Calculted values. of this quantity for common materials are given in Table 1. The deviation of the numbers in Table I from unity indicate that a bias can'

be introduced by ignoring the difference in material composition.

Inhomogeneities in matrix material composition, uranium density, and uranium enridunent within the measured volume of the maierial (as chariterized by the depth xo and the collimated area A) can produce changes in the measured 185.7-keV activity and-affect v-the accuracy of an enrichment calculated on the bais of that activity. There is a small to negligble effect on the measurement accuracy due to variations in the content of low-atomic-number (Z<30) matrix materials. Care should be exercised, however, in applyin this technique to materials having.high-atomro-number matria" (Z>50)

or materials having uranium concentuations 1.

than approximately 75%. Inhomogeneities in uraium density will also produce small to negligible effects on the accuracy if the matrix isu of low-atomic-number elements. Sifjkuw inacraeieas cn. a.Ni, howem, when the urnium enrichment itself ce. be expected to vary throughout the sample.

The above , gonclusions about the effects of inhomogeneities are based on the assumption that the thickness of the material exceeds the critical distance, xo, and that the inhomogeneities exist within this depth.

In the case of extremely inhomogeneous materiah much as scrap, the condition of sufficient depth may not always be fulfllled,-or inhomogeneitiesmay exist beyond the depth xo; i.e., the "sample" is not representative.

Therefore, this technique is not applicable to such inhomogeneous materials.

Container Wafl Effects Variations in the thickness of the container walls

-can significantly affect the activity measured by the Calculated values of AC/C, corresponding to a change in container thickness Ad of 0.0025 cm, for common container materials, are given in Table 2.

TABLE 2 Material Density (g/cm 3l C

Steel

7.8

- .003 Aluminum

2.7

- .0009 Polyethylene

0.95

- .0004 Therefore, the container wall thickness should be known, e.g., by measuring an adequate number of the containers before loading. In some cases an unknown container wall thickness can be measured using an ultrasonic technique and a simple correction applied to the data to account for attenuation of the 185.7-keV

gamma rays (see eq. 5). Commercial equipment is available to measure wall thicknesses ranging from about

0.025 to 5.0 cm to relative accuracies of approximately

1.0% to 0.1%, respectively.

Area and Geometrical Efficiency The area of the material viewed by the detector and the geometrical efficiency are variables which may be adjusted, within limits, to optimize a system. It is important to be aware that once these variables are fixed, changes in these parameters will affect the results of the measurement.

It is also important to note that the placement of the material within the container will affect the detected activity. The 'material should fill the volume of the container to a certain depth, leaving no void spaces between the material and the container wall.

Net Deteetw Bffidncy Thallium-activated sodium iodide, NaI(T1),

scintillationw detectors and lithium-drifted germanium, Ge(LI), solid-state detectors have been used to perform these measurements. The detection systems are generally conventional gamma-ray spectrometry systems presently commercially available in modular or single-unit construction.

5.21,3

The following factors influence detector selection and the control required for accurate results.

1.

Background a.

Compton Background. This background is predominately produced by'the 765-keV and ICOl-keV

gamma rays of Pa-234m, a daughter of U-238. Since, in most cases, the Compton background behaves smoothly in the vicinity of the 185.7-keV peak, it can be readily subtracted, leaving only the net counts in the 185.7-keV

full-energy peak.

b.

Overlapping Peaks. The observable peak from certain gamma rays may overlap that of the 185.7-keV

peak due to the finite energy resolution of the detector;

i.e., the difference in energies may be less than twice the FWHM.

This problem is common in enrichment measurements of recently separated uranium from a reprocessing plant. The peak from a strong 208-keV

gamma ray from U-237 (half-life of 6.75 days)- can overlap the 185.7-keV peak when an Nal detector is used. Analytical separation of the two unresolved peaks, i.e., peak stripping, may be applied. An alternative solution is to use a Ge(Li) detector so that both peaks are clearly resolved.

The U-237 activity ;present in reprocessed uranium will depend on the amount of Pu-241 present before reprocessing and also on the time elapsed since separation.

c.

Ambient Background. The third source of background originates from natural sources and from other uranium-bearing materials located in the vicinity of the measuring apparatus. This last source can be particularly bothersome since it can vary with time within wide limits depending on plot operating conditions.

2.

Count-Rate LoAmes. Calculation of the detector count rates for purposes of making dead time estimates requires that one calculate the total count rate, not only that due to U-235. Total count rate estimates for low-enrichment material must therefore take into account the relatively important background from U-238 gamma rays. If other radioactive materials are present within the sample, their contributions to the total count rate must also be considered.

Count-rate corrections can be made by determining the dead time or by making measurements for known

4 FWHM- full width of the spectrum peak at half its maximum height.

live-time s intervals. The pile-up or overlap of electronic pulses is a problem which also results in a loss of counts in the full-energy peak for Ge(Li) systems. A pulser may be used to monitor and correct for these losses.

Radiation which provides, no useful -information can be selectively attenuated by filters; e.g., a one-millimeter- thick cadmium filter will reduce x-ray interference, eliminating this source of count-rate losses.

3.

Instability in Detector Electronics. The gain of a photomultiplier tube is sensitive to changes in temperature, count rate, and magnetic field. Provision can be made for gain checks and/or gain stabilization for enrichment measurement applications.

Various gain stabilizers that automatically adjust the system gain to keep a reference peak centered between two preset energy limits are available.

C. REGULATORY POSITION

Passive gamma-ray spectrometry constitutes an acceptable means for nondestructively determining U-235 enrichment, if the following conditions are satisfied:

Range of Application

1.

All material to be assayed under a certain calibration should be of similar chemical form, physical form, homogeneity, and impurity level.

2.

The critical distance of the material should be determined.. Only those items of the material having dimensions greater than -this critical distance should- be assayed by this technique.

3. The material should be homogeneous in all respects on a mnacroscopic 6 scale.- The material should be homogeneous'with respect to uranium enrichment' on a microscopic

-wscale.

4.

The containers should all be of similar size, geometry, and physical and chemical composition.

System Requirements I.

Nal('I) scintillation detectors having a resolution of FWHM < 16% at the 185.7-keV peak of' U-235 are s"Live time" means that portion of the measurement period during which the instrument can record detected events.

Dead time refers to that portion of the measurement period during which the instrument is busy processing data already recehed anldcannot accept new dat

a. in order to compare

6fferent data for which dead times are appreciable, one must compare counts measured for equal live-time periods.

(actual measurement period) - (dead time) = live ,time

6 Macroscopic refers to distances greater than the critical distance; miuoscopic to distances les than the critical distance.

5.21-4

generally adequate for measuring the enrichment of uranium containing more than the natural (0.71%)

abundance of U-235. Crystals With a thickness of ~- 1.25 cm are recommended for optimum efficienc

y. If other

-1- radionuclides Which emit significant quantities of gamma radiation in an energy region E = 185.7 keV +/- 2 FWHM

at 185.7 keV are present:

a.

A higher-resolution detector. e.g., Ge(Li),

should be used, or b.

A peak stripping procedure should be used to subtract the interference. In this case, data should be provided to. show the range of concentration of -the interfering radionuclide, and the accuracy and precision of the stripping technique over this range.

2.

The detection system gain should be stabilized by monitoring a known reference peak.

3. The system should measure live time or provide a means of determining the count-rate losses based on the total counting rate.

4.

Design of the system should allow reproducible positioning of the detector or item being assayed..

5. The system should be capable of determining the gamma-ray activity in at least two energy regions to allow background subtraction. One region should encompass 185.7 keV, and the other region should be above this but not overlapping. The threshold and width of the regions should be adjustable.

6.

The ýsystem should have provisions for filtering low-energy radiation which could interfere with the

185.7-keV or background regions.

Data Reduction I. if the total counting rate is determined primarily by the 185.7-keV gamma ray, the counting rate should be restricted (absorbers, decreased geometrical efficiency)

below those rates requiring correction. The system sensitivity will be reduced by these measures and, if no longer adequate,' separate calibrations should be made in two or more enrichment regions.

Ifrthe total counting rate is determined primarily by events other than those due to 185.7-keV gamma rays, counting rate corrections should be made.

2. To determine the location and width of the

185.7-keV peak region and the background region(s),

the energy spectrum from each calibration standard (see Calibration, next section) should be determined and the position of the 185.7-keV peak and neighboring peaks noted. The threshold and width of each energy region should then be selected to avoid including any neighboring peaks, and to optimize the system stability and the signal-to-background ratio.

3.

The net response attributed to 185.7-keV gamma rays should be the accumulated counts in the peak region minus a multiple of the counts accumulated in a nearby background region(s). A single upper background region may be monitored or both a region above the peak region and one below may be monitored.

If only an upper background region is monitored, the net response, R, should be given by R = G-bB

where G and B are the gross counts in the peak region and the background region, respectively, and b is the multiple of the background to be subtracted. This net response, R, should then be proportional to the enrichment, E, given by E = C, R = C, (G-bB)

where C, is a calibration constant to be determined (see Calibration, next section). The gross counts, G and B,

should be measured for all the standards. The quantities G/E should then be plotted as a function of the quantities B/E and the slope of a straight line through the data determined. This slope is b, the multiple of the upper background region to be subtracted, i.e..

G/E = b(B/E) + I/CI

The data from all the standards should be used in determining this slope.

If both an upper and a lower background are monitored, the counts in each of these regions should be used to determine a straight line fit to the background.

Using this straight line approximation, the area or number of counts under this line in the peak region should be subtracted from the gross counts, G. to obtain the net response. An adequate technique based on this principle is described in the literature.

Calibration s

1. Calibration standards should be obtained by:

a.

Selecting items from the production material. A

group of the items selected should, after determination G. Gunderson, 1. Cohen, M. Zucker, "Proceedings: 13th Annual Meeting, Institute of Nuclear Materials Management,"

Boston, Mass. (1972) p. 221.

" None of the calibration techniques or data reduction procedures exclude the use of automated direct-readout systems for operation. The procedures described in this guide should be used for adjustment and calibration of direct-readout instruments.

5.21-5

of the gamma-ray response, be measured by an independent, more accurate technique traceable to, or calibrated with, NBS standard reference material, e.g.,

mass spectrometry. The other items should be retained as working standards.

b.

Fabricating standards which represent the material to be assyed in chemical form, physical form, homogeneity, and impurity level. TheU-235 enrichment of the material used in the fabrication of the standards should be determined by a technique traceable to, or calibrated with, NBS standard reference material, e.g.,

mass spectrometry.

2.

The containers for the standards should have a geometry, dimensions, and composition which approximate the mean of these parameters in the containers to be assayed.

3.

The values of enrichment for the calibration standards should span the range of values encountered in normal operation. No less than three separate standards should be used.

4.

Each standard should be measured at a number of different locations, e.g., for a cylinder, at different heights and rotations about the axis. The mean of these values should be used as the response for that enrichment. The dispersion in these values should be used as an initial estimate of the error due to material and container inhomogeneity.

5.

The data from the standards, i.e., the net response attributed to 185.7-keV gamma rays and the known uranium enrichment, should be used to determine the constants in a calibration function by a weighted least-squares technique.

Operations

1. The detection system and counting onometry (collimator and container-to-detector distance) should be identical to those used in calibration.

2. The data reduction technique and count-rate loss corrections, if included, should be identical to those used in calibration.

3.

Data from all measurements should be recorded in an appropriate log book.

4.

At least two working standards, should be measured during each eight-hour operating shift. The measured response should beý compared to the expected response (value used in calibration) to determine if the difference exceeds three times the expected standard deviation. If this threshold is exceeded, repeat measurements should be made to verify that the response is significantly different and that the system should be recalibrated.

5.

All containers should be agitated, or the material mixed in some manner, if possible, prior to counting.

One container from every ten should be measured at two different locations. Other items may be measured at only one position. (If containers am scanned to obtain an average -enrichment, the degree of inhomogeneity should still be measured by this method.)

The difference between the measurements at different locations should be used to indicate a lack of the expected homogeneity. If the two responses differ by more than three times the expected standard deviation (which should include the effects of the usual or expected inhomogeneity),

repeat measurements should be made to verify that an abnormal inhomogeneity exists. If the threshold is exceeded, the container should be rejected and investigated to determine the cause of the abnormal inhomogeneity. 9

6.

In the event that all containers are not filled to a uniform height, the container should be viewed at a position such that material fills the entire volume viewed by the detector. The procedure for determining the fill of the container should be recorded' e.g., by visual inspection at the time of filling and recording on the container tag.

7. The container wall thickness should be measured.

The wall thickness and location of the measurement should be indicated, if individual wall thickness measurements are made, and the gamma-ray measurement made at this location. If the containers are nominally identical, an adequate sampling of these containers should be representative. The mean of the measurements on these samples constitutes an acceptable measured value of the wall thickness which may be applied to all containers of this type or category.

8.

The energy spectrum from a process item selected at random should be used to determine the existence of unexpected interfering radiations and the approximate magnitude of the interference. The frequency of this test should be determined by the following guidelines:

a.

At leat one item in any new batch of material.

b.

At ieast one item if any chanps in the material procesing occur.

c. At least one item per material balance period.

If an interference appears, either a higher-resolution detector must be acquired or an adequate peak stripping routine applied. In both cases additional standards which include the interfering radiations should be selected and the system recalibrated.

The difference nmy also be due to a large variation in wall thickness.

Il

5.21-6

9.

No item should be assayed if the mesured response exceeds that of the highest enrichment standard by more than tvice the standard deviation in the reponse from this standard.

Error Anysis I.

A least4quares technique should be used to determine the uncertainty in the calibration constants.

2.

The measurement.to-measurement error should be determined by periodically observing the net response from the standards and repeating measurements on selected process items. Each repeat measurement should be made at a different location on the container surface, at different times of the day, and under differing ambient conditions.' "The standard deviation should be determined and any systematic trends corrected for.

'

The statistical error due to counting (Including backipound) and the erron due to inhomopamsity, ambient conditions, etc. will be include in this measurement- to-measurement error.

3.

The item-to-item error due to the uncertainty in wall thickness should be determined. The uncertainty in the wall thickness may be the standard deviation about the mean computed from measurements on randomly selected samples, or it may be the uncertainty in the thickness measurement of individual containers. This uncertainty in wall thickness should be multiplied by the effect of a unit variation in wall thickness on the measured

185.7-keV

response to determine this component uncertainty.

4. Item-to-item errors other that those measured, e.g.,

wall thickness, should be determined by periodically (see guidelines in paragraph 8. of the Operation Section)

selecting an item and determining the enrichment by an independent technique traceable to, or calibrated with, NBS

standard reference material. A recommended approach is to adequately sample and determine the U-235 enrichment by calibrated mass spectrometry. In addition to estimating the limit of error from these comparative measurements, the data should be added to the data used in the original calibration and new calibration constants determined.

5.21-7


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