Determinktion of Iodine to Compliment Mass Spectrometric Measurements

I D A H O NATIONAL E N G I N E E R I N G LABORATORY 1NEL-94/0068 November 1994 Determinktion of Iodine to Compliment Mass Spectrometric Measurements =>Loc/r/leed fdahotechnologies Company Work performed under DOE Contract NO.DE-AC07-94ID13223

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INEL94/0068 UC-510 Determination of Iodine to Compliment Mass Spectmmetric Measurements Frederick A. Hohorst November 1994 Lockheed Idaho Technologies Company PREPARED FOR M E DEPARTMENTOFENERGY IDAHO OPERATIONS OFFICE UNDER CONTRACT DE-AC07-941013223

DETERMINATION OF IODINE TO COMPLIMENT MASS SPECTROMETRIC MEASUREMENTS Frederick A. Hohorst Introduction: The dose of iodine-129 to facility personnel and the general public as a result of past, present, and future activities at DOE sites is of continuing interest. WINCO received about 160 samples annually in a variety of natural matrices, including snow, milk, thyroid tissue, and sagebrush, in which iodine-129 is determined in order to evaluate this dose. Currently, total iodine and the isotopic ratio of iodine-127 to iodine-129 are determined by mass spectrometry. These two measurements determine the concentration of iodine-129 in each sample. These measurements require at least 16 h of mass spectrometer operator time for each sample. A variety of methods are available which concentrate and determine small quantities of iodine.'82 A1 though useful, these approaches would increase both time and cost. The objective of this effort was to determine total iodine by an alternative method in order to decrease the load on mass spectrometry by 25 to 50%. The preparation of each sample for mass spectrometric analysis involves a common step--collection of iodide on an 1

ion exchange bed. would be applicable to all samples. This was the focal point of the effort since the results Background: Measurement of iodine-129 concentrations in environmental samples is a necessary activity in order to estimate the dose of this radioisotope to personnel at DOE facilities and to the general public. Iodine-129 is of continuing interest throughout the DOE complex because of, its long half-life (1.6 x 107years) and the ease with which this essential element is absorbed by the human body. Mass spectrometry is a sensitive tool for determination of the iodine-127 to iodine-129 ratio. To fully utilize this knowledge, the concentration of iodine in the sample, which is primarily iodine-127, must be known in order to interpret the data in relation to the body burden for iodine. Mass spectrometry can determine iodine-127 by isotope dilution techniques (IDMS) but it requires preparation of a second sample to which a known amount of natural iodine has been added. Remeasuring the ratio of iodine-127 to iodine-129 furnishes the information necessary to calculate the original i odi ne-127 concentration. The approach proposed would determine iodine-127 in the same sample being used for the mass spectrometric determination of the ratio. This eliminates preparation and manipulation of different aliquots of sample which is a 2

significant potential source of error. Furthermore, activation analysis of a concentrated iodine sample located on 0.5 cm3 of ion exchange resin i s less a p t t o generate significant waste. Experimental : A1 1 reagents used were analytical reagent grade unless otherwise stated. Deionized water was used. The anion exchange resin used i n this work was BioRad AGl-X8, 100-200 mesh, i n the acetate form. prepared from sodium iodide i n a solution 0.009 0.009 M in sodium sulfite. Iodine standards were i n sodium hydroxide and They were stored i n a desiccator over water t o minimize evaporative losses. A dual head, variable speed, p e r i s t a l t i c pumping system was used as received. Polyvinyl chloride t u b i n g was used i n pulling a sample through an in-house fabricated glass "Y" i n t o two 0.5 ml beds of anion exchange resin. These beds were held in 1000 pl HDPE pipette tips w i t h quartz wool. A second pipette t i p inserted i n t o the first kept the bed stationary. The target flows were about 0.5 ml min" and 0.1 ml min-' for the two legs of the "Y". Samples contacted only glass, quartz wool, and HDPE before encountering the anion exchange resin. Pump effluents were directed t o separate receptacles t o permit measurement of individual flows through each leg of the 'ly''. The sample s p l i t was calculated from the mass of these flows. After passage of a sample through a bed, t h a t bed was rinsed w i t h several 3 I

bed volumes of deionized water t o minimize the sodium content o f the bed. Excess water was drawn o f f, the second pipette t i p removed, and the bed heat sealed i n i t s pipette t i p. A sample number was imprinted i n t o a sealed end using clean steel numbering stamps before the sealed area cooled. These sealed tubes were then submitted for determination o f iodine by neutron activation analysis (NAA). Two "real" pairs of samples were included w i t h each s e t sent for NAA. These pairs had been prepared by the combustion of.citrus Leaves, NBS SRM 1572, i n an oxygen atmosphere followed by trapping i n a 0.1 0.1 sodium sulfite solution. fl sodium hydroxide - For the spiked samples, 10 pg of NaI was placed on the leaves before burning. These s o l u t i o n s were also processed as described above. Results: No iodine was detected i n a blank which consisted of a sealed pipette t i p containing quartz wool. The results of NAA of other samples are presented i n Table 1 and Table 2. Facility A was a commercial activation analysis facility. The t u r n around time from the date we shipped the samples u n t i l the time results were FAXed t o us was 11 calendar days. Facility B was a university based reactor; i t s t u r n around time was 65 calendar days. The tables compare the iodine added t o the net iodine found for each sample and report the percent difference. In the case of Facility A, the percent 4

difference was within 30% for the higher concentrations. This accuracy was considered acceptable for the proposed use of these analytical results. For Facility B, the percent differences were somewhat higher. The most significant result of these NAA determinations is the higher than anticipated concentration of iodine in the anion exchange resin matrix. The current experimental values are 0.50 to 1.2 pg per bed. The experimental value in 1979 as determined by NAA at the INEL's Advanced Test Reactor (ATR) was 0.16 pg per bed for this same bottle of resin. Concl usions: The submission of selected samples for neutron activation analysis is a cost effective method for determination of iodine. Prudence dictates that appropriate blanks and controls be submitted with each set of samples submitted. The higher than anticipated iodine blank for the anion exchange resin being used invites speculation. The cause may be inhomogeneous bottle contents, adsorption of airborne iodine, absorption of airborne iodine, or other unanticipated and unforeseen circumstances. This higher blank has raised the detection limits to a higher than anticipated level. The simplest solution appears to be purchasing a new bottle of resin and testing a representative sample of it for iodine by NAA. 5

TABLE 1 I r r a d i a t i on o f Sampl es a t Faci 1i t y A Samle 1 Net Iodine 00 (as) Iodine Added None' 2 Noneb 3 0.0932 4 0.361 5 None 6 Yes a Gross Iodine 0.520 k 0.094 0.506 2 0.049 0.665 k 0.086 0.840 k 0.092 1.20 k 0.12 2.85 k Diff 0.159 k 0.099 0.334 k 0.104 0.694 k 0.130 2.344 k 0.177 0.17 Anion exchange r e s i n i n a c e t a t e form, unused. was a t t r i b u t e d t o the presence o f chlorine. + 71-7 - 29-24 The high uncertainty Anion exchange resin, washed w i t h d i l u t e sodium hydroxide s o l u t i o n followed by deionized water, 4 0 0 ml each. Original solution contained a calculated 3.9 pg o f iodine; 25.2% o f s o l u t i o n (0.98 pg I ) passed through this bed. Original s o l u t i o n contained a c a l c u l a t e d 4.1 pg of iodine p l u s a 10 pg s p i k e o f NaI; 22.3% of s o l u t i o n (3.1 pg I ) passed through t h i s. bed. 6 _.

TABLE 2 I r r a d i a t i o n o f Samples a t Facility B Sample' Iodine Added O 1 2.65 Gross Iodine A Net Iodine A Diff (%I 1.15 3.80 2 b None 1.213 k 0.098 1.137 k 0.091 0.06 k 0.11-0.01 k 0.11 3 b None 1.102 k 0.103-0.05 k 0.12 4 0.0971 1.115 k 0.086-0.04 k 0.10 5 0.149 1.229 k 0.098 0.08 k 0.11 6 0.299 1.520 k 0.114 0.37 k 0.13 + 7 0.435 1.583 f 0.127 0.43 k 0.14-1 8 0.581 2.153 k 0.165 1.00 k 0.17 9 No 2.305 k 0.139 1.15 k 0.15 10 Yes + 96 + 31 + 77 ' Submitted cl ari t y. d 7.511 k 0.431 6.36 k 0.44 24 i n random order; reordered and renumbered here for Mean blank was 1.151?: 0.0561 pg iodine. Original s o l u t i o n contained a c a l c u l a t e d 3.8 pg o f iodine; 23.1% o f s o l u t i o n (0.88 pg I ) passed through this bed. Original s o l u t i o n contained a c a l c u l a t e d 4.0 pg o f iodine p l u s a 10 pg spike o f NaI; 25.9% o f s o l u t i o n (3.6 pg I ) passed through this bed. 7

The corollary t o this hypothesis is t o determine whether the iodine present on the resin i s extractable under the experimental conditions being used. I f i t i s extractable, corrections may have t o be applied i n order t o accurately determine results by IDMS. References: 1. R. R. Rao and A. Chatt, Determination of Nanogram Amounts of Iodine in Foods by Radiochemical. Neutron Activation Analysis, Analyst, 1993, 118, 1247. 2. S. Palagyi and T. Braun, Transport Extraction for Trace Element Separation and Preconcentrat ion, II. Preconcentration of iodine from Aqueous Solution, Fresenius J. Anal. Chem., 1993, 346, 905. 8