Metrological capability of the Brazilian laboratories of analyses of radionuclides in environmental samples

Applied Radiation and Isotopes 56 (2002) 409–414

Metrological capability of the Brazilian laboratories of analyses of radionuclides in environmental samples L. Tauhata*, M.E.C. Vianna, A.E. de Oliveira, A.C.M. Ferreira, C.C.S. da Conceic-a* o ! Laboratorio Nacional de Metrologia das Radiac-oes * Ionizantes (LNMRI), Instituto de Radioprotec-ao * e Dosimetria (IRD), Comissao * Nacional de Energia Nuclear (CNEN) Av. Salvador Allende, s/n Recreio dos Bandeirantes - Rio de Janeiro C.E.P. 22780-160, Brazil Accepted 30 July 2001

Abstract The metrological capability of 24 Brazilian laboratories of radionuclide determinations in environmental samples was analysed for purposes to establish requirements for accreditation of laboratory for each radionuclide. For each type of analysis, the range of activity per unit mass or volume, the range of the reference value and its correspondent uncertainty were described. The accuracy was established using the statistical criteria of USE.P.A. for the laboratory performance classification. The precision of the analyses, expressed by its variation coefficient of the laboratory determinations, was classified in intervals of 5%. The data base was constituted by 3013 results of analyses obtained in 28 intercomparison runs performed from 1991 to 2000, for K, Th, Unat, gross alpha, gross beta, and other 27 radionuclides, in matrices of water, soil, vegetation, air filter and milk. The quality criteria established were the variation coefficient less than 5% and good performance in intercomparison runs. Results included from 5% to 10% are also considered, for special types of matrices and radionuclides. r 2002 Elsevier Science Ltd. All rights reserved.

1. Introduction The increasing of environmental samples analyses due to the exigency of quality control programs and studies of the environmental impact in many types of the human activities, claim to a fast response of the laboratories and the quality of the results assured by normative or accreditation organisms. The laboratories need to present results with accuracy and precision met recommendations of this type of institutions and, moreover, to submit its technical procedures for accreditation process. In the case of the laboratory analyses of radionuclide, it is important to note the necessity of an accreditation process for each kind of radionuclide. Large efforts are made in the past time to develop a reasonable quality *Corresponding author. Tel.: +55-2134-118185; fax: +552144-21605. E-mail address: [email protected] (L. Tauhata).

criteria to be applied in the classification of the laboratories and to evaluate its measurement performance. In the case of the laboratories that analyzing environmental samples the repeatability of measurements and their normalized standard deviation are seldom-included in performance evaluation, which should be included to study the long term stability of a laboratory performance. Then, one good criteria that can be obtained is to select the group that has the best performance over long period or many intercomparison runs. Another important requirement is related to the precision of the measurements, expressed by the variation coefficient. The low value of variation coefficient is, obviously, related to the low uncertainties of the results. By combining these two criteria, it is possible to establish the requirement to select the laboratories with confiability of measurement, for each radionuclide. Besides, it is important to take account of the main objective of the

0969-8043/02/$ - see front matter r 2002 Elsevier Science Ltd. All rights reserved. PII: S 0 9 6 9 - 8 0 4 3 ( 0 1 ) 0 0 2 2 3 - 8

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measurement, in respect of the precision need. Other exigencies, such as the difficulties of doing the analysis, the type of sample matrix, type of radiation of emitter, and measurement procedure should be also considered. Another important point is to assure the traceability of the laboratories measurements to the national and international metrology network and to the BIPM.

2. Methodology To evaluate the performance in terms of accuracy of 24 Brazilian laboratories, the statistical criteria of Environmental Protection Agency of United States, USE.P. A, was used for the laboratory performance classification (Jarvis and Siu, 1981). For each type of 100

100

80

Ac-228 : 24 Am-241: 25 Ba-133: 162 Bi-212: 18

60 40

Frequency (%)

Frequency (%)

80

0

0

0

5

10 15 20 Variation Coefficient (%)

Ac-228

Am-241

25

Ba-133

0

30

Ce-144

Co-57

20

25

Co-60

100 80 Cs-134: 187 Cs-137: 316 Gross alpha: 195 Gross beta: 225

60 40

Frequency (%)

Frequency (%)

10 15 Variation Coefficient (%)

Bi-214

80

20

H-3: 99 K-40: 71 Mn-54: 15 Pb-210: 97

60 40 20

0

0 0

5

Cs-134

10 15 Variation Coefficient (%)

Cs-137

20

Gross alpha

25

0

5

Gross beta

10 15 Variation Coefficient (%)

H-3

K-40

Mn-54

20

25

Pb-210

100

80

Pb-212: Pb-214: Pu-238: Pu-239:

60 40

Frequency (%)

100

Frequency (%

5

Bi-212

100

21 23 6 27

80 Ra-226: 186 Ra-228: 139 Ru-106: 166 Sb-125: 11

60 40 20

20

0 0

5

10 15 20 Variation coefficient (%)

Pb-212

Pb-214

Pu-238

25

0

30

5

10

15

20

25

Variation coefficient (%)

Ra-226

Pu-239

Ra-228

Ru-106

Sb-125

100

100

Sr-89: Sr-90: Th-232: Th-234:

60 40

6 89 93 17

20

Frequency (%)

80

80 Frequency (%)

Co-60: 239 40 20

20

0

Bi-214: 24 Ce-144: 10 Co-57: 15

60

U-234: 23 U-238: 27 U-nat: 295 Zn-65: 162

60 40 20

0

0 Variation coefficient (%)

Sr-89

Sr-90

Th

Th-234

0

5

10 15 Variation coefficient (%)

U-234

U-238

U-nat

20

25

Zn-65

Fig. 1. Uncertainty distributions of the measurements of Brazilian Laboratories analyzing low level radionuclides in different types of environmental samples.

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L. Tauhata et al. / Applied Radiation and Isotopes 56 (2002) 409–414

analysis, the range of activity per unit mass or volume, the range of the reference value and its correspondent uncertainty were described. The results of analyses were classified using the normalized standard deviation, D; defined as the difference between the laboratory mean % and value of three independent determination results, X; the reference value, U; normalized to the standard deviation of the reference value, sU ; divided by the square root of the number of independent determinations n: Then D¼

ðX%  UÞ pffiffiffi : sU = n

When the value of D is within 72 the laboratory have Good performance. The results fall in the intervals of 3oDo  2 or þ2oDo þ 3 are considered to be Acceptable, and for data with Dp  3 or DX þ 3 are considered as Out of control and the performance is not acceptable. The precision of each analysis can expressed by the variation coefficient for each type of radionuclide analyses, s VC ¼ % X%

where X% is the mean value of 3 independent determinations and s is the correspondent standard deviation. The quality criteria to determine good laboratory performance was the variation coefficient less than 5% in intercomparison runs. Results between 5% and 10% are also considered to be acceptable, for special types of matrices and radionuclides.

3. Results and discussion Samples were prepared with activity range per unit mass from 0.37 to 2.22 Bq/kg, except for 3H, from 111 to 555 Bq/kg and distributed by LNMRI. Samples with milk, vegetation and soil matrices were distributed in technical cooperation with Environmental Protection Agency, E.P. A and Environmental Measurements Laboratory, EML, of the United States. The activity range per unit mass of these samples are variable, but less than 1 kBq/kg, except for 137Cs and 40K. Fig. 1 shows the radionuclides analyzed in the intercomparison program, the activity range per unit mass for samples prepared and distributed by LNMRI, the number of analyses of each radionuclide and the occurrence frequency in each percentual range of

Table 1 Laboratories classified using accuracy and precision criteria, by radionuclide analyzed and number of participation intercomparison runs, with respective type of sample matrices Nuclide

Lab.

Intercomparison participation and sample matrix Water

Am-241 Ba-133

Co-60

LC AX BC CG DY EF EK NB PI QZ RA ZT AX CG DY EF EK LC PI QZ RA ZT

Milk

Air filter

Soil

Vegetation

1

4

4

11 6 17 9 11 8 24 22 7 16 20 11 22 9 13 8 24 7 16 22

1

1

3 1

1 1

6

4 1

1

6 6

4

6 6

D%

VC (%)

Good accuracy

Precision (%) o5

0.15 0.58 0.05 0.41 1.11 0.62 0.90 1.06 0.69 1.55 0.26 1.04

9.93 3.96 4.51 1.97 4.29 2.61 9.38 3.50 5.80 6.29 2.89 2.32

X X X X X X X X X X X X

1.07 0.05 0.81 0.37 0.94 0.35 0.44 1.98 0.28 0.20

5.45 2.13 4.35 2.78 9.31 4.62 4.75 5.42 3.59 2.14

X X X X X X X X X X

o10 X

X X X X X X X X X X X X X X X X X X X X X

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L. Tauhata et al. / Applied Radiation and Isotopes 56 (2002) 409–414

Table 1 (continued) Nuclide

Lab.

Intercomparison participation and sample matrix Water

Cs-134

Cs-137

Gross alpha

Gross beta

H-3

Pb-210

Ra-226

AX BC CG DY EF NB PI RA ZT

11 6 21 9 12 25 24 16 21

AX BC CG DY EF FB LC PI QZ RA SP ZT

11 6 21 9 12 2 24 7 16 5 21

BC NB RA QZ ZT

6 4 14 11 18

DY QZ RA SK

9 11 14 24

NB PI RA ZT LC PI RA

27 24 16 17

AX EF EK LC RA SL

14 6 7 18 15 8

AXa CG EK LC LG MCa

29 7 8 26 26 38

Milk

Air filter

Soil

D%

VC (%)

Good accuracy

Precision (%) o5

Vegetation 1.13 0.37 0.05 0.80 0.35 0.23 0.47 0.27 0.84

7.12 5.16 2.37 4.44 2.59 5.42 5.65 4.79 3.40

X X X X X X X X X

0.47 1.24 0.38 0.04 0.13 0.22 0.68 0.49 1.48 0.73 0.51 0.54

4.87 4.06 2.41 3.87 4.99 1.84 1.85 4.52 6.42 3.03 4.28 1.54

X X X X X X X X X X X X

7 1 2

1.15 1.63 0.01 0.12 0.67

9.56 6.77 8.02 8.17 6.30

X X X X X

1 2 1 7

1.83 0.30 0.28 1.12

5.11 4.16 5.1 9.03

X X X X

0.32 0.43 1.32 0.79 0.05 0.78 1.03

3.37 4.75 4.18 4.54 4.81 1.97 5.92

X X X X X X X

X X X X X X X

1.38 0.31 0.06 1.00 0.36 1.98

7.79 3.01 2.88 1.94 4.76 3.82

X X X X X X

X X X X X

0.01 0.43 0.19 0.47 0.90 0.14

6.37 6.29 3.75 1.74 4.6 6.99

X X X X X X

1 1 2 1 1 3

1

1 1 2 3 1

7

4 6 4

2 1 3 6 1 2 7 7

1

7 4 7

6

1

6 2 6 6

6

6

7 7 7

1

1 1

6 6 6

o10 X X

X X X X X X X X X X X X X X X X X X X X X X X X X X X X

X

X X X X X X

413

L. Tauhata et al. / Applied Radiation and Isotopes 56 (2002) 409–414 Table 1 (continued) Nuclide

Lab.

Intercomparison participation and sample matrix Water

Precision (%) o5

Vegetation X X

X

7 23 13 10

1.35 0.65 1.80 1.59

3.74 4.54 9.39 9.0

X X X X

X X

AX BC CG DY EF EK NB PI RA ZT

9 6 17 9 11 8 25 22 16 20

1.58 0.33 0.16 1.18 1.65 1.63 1.38 1.03 0.19 0.76

5.97 9.63 2.20 8.48 4.79 6.40 5.42 7.52 6.52 2.67

X X X X X X X X X X

X

Sr-90

RA

16

0.55

3.91

X

X

Th-232

AC EK LC MC OV RA

9 7 13 13 10 13

0.68 0.89 1.11 0.29 0.76 0.27

3.15 3.69 2.27 3.99 1.54 2.88

X X X X X X

X X X X X X

U-234

LC

4

6

0.17

5.95

X

U-238

LC SL

3

6 6

0.05 1.58

8.71 3.62

X X

0.90 0.33 0.21 0.54 1.17 0.22 0.42 0.89 0.73 0.13

2.87 6.58 3.71 2.36 5.33 1.39 2.95 8.58 2.6 3.41

X X X X X X X X X X

0.01 0.03 1.05 0.82 1.23 0.57 0.21 0.28 0.44

4.78 2.15 5.28 4.86 9.07 5.14 6.41 4.22 1.70

X X X X X X X X X

U-nat

Zn-65

a

CG LC LG QZ

Soil

Good accuracy

6.03 6.94

Ru-106

16 9

Air filter

VC (%)

0.18 1.02

Ra-228

RA SL

Milk

D%

AC AX EF LC MC OV RA SK SP ZT

12 31 22 27 10 16 22 10 22

BC CG DY EF EK NB PI RA ZT

6 17 9 11 8 25 22 16 20

1

1

1 1

3

3 1 5 3 4

6

6 3 7 5 7

6

o10 X

X X X X X X X X X X X

X X X X X X X X X X X X X X X X X X X X X

Laboratories which present intercomparison participation above 28 have requested additional samples for comparing different analytical techniques.

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L. Tauhata et al. / Applied Radiation and Isotopes 56 (2002) 409–414

precision measurements. The best performance were for Th with 83.7% of the reported values having uncertainty less than 5%, 3H with 78.8%, and gamma emitters radionuclide determinations in water with 73% as mean value. The poor results were associated to 241 Am in soil and vegetation matrices, with 20% of results included in the quality indicator and 32% greater than 20%. Applying the quality criteria to the results of 3013 analyses obtained from 28 intercomparison runs performed from 1991 to 2000 for K, Th, U-nat, gross alpha, gross beta, and 27 other radionuclides in matrices of water (75.9%), soil (11.4%), vegetation (4.4%), air filter (7.7%) and milk (0.6%), we obtain the final results shows in Table 1. The laboratories participant in PNI are represented by its code name: AC, AX, BC, CG, CX, DY, EF, EK, FB, GF, LC, LG, MC, NB, OV, PI, QZ, RA, RL, SK, SL, SP, TW, ZT.

4. Conclusions These results suggest a detail examination and reduction of the uncertainty sources in measurement procedures and show the need of standardization of accreditation criteria of laboratory analyses. As the methodology used to evaluate the results of laboratories measurements depends on the reference value and its uncertainty for each radionuclide and its traceability to absolute standards and to BIPM, this type of intercomparison program contribute to establish the metrological network in the country.

References Jarvis, A.N., Siu, L., 1981. Environmental Radioactivity Laboratory Intercomparison Studies Program, EPA-600/481-004, EMSL-USEPA, Las Vegas.