Simple Method for High-Sensitivity Determination of Cosmogenic 35S

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A simple method for high-sensitivity determination of cosmogenic 35S in snow and water samples collected from remote regions Mang Lin, Kun Wang, Shichang Kang, and Mark H. Thiemens Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b05066 • Publication Date (Web): 03 Mar 2017 Downloaded from http://pubs.acs.org on March 14, 2017

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Analytical Chemistry

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A simple method for high-sensitivity determination of cosmogenic 35S in snow and

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water samples collected from remote regions

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Mang Lin1*, Kun Wang2,4,1, Shichang Kang2,3 and Mark H. Thiemens1

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1. Department of Chemistry and Biochemistry, University of California San Diego, La Jolla,

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California 92093, USA

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2. State Key Laboratory of Cryosphere Sciences, Northwest Institute of Eco-Environment and

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Resources, Chinese Academy of Sciences (CAS), Lanzhou 730000, China

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3. CAS Center for Excellence in Tibetan Plateau Earth Sciences, Beijing 100101, China

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4. University of CAS, Beijing 100049, China

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* Email: [email protected]

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Abstract

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Cosmogenic 35S is useful in understanding a wide variety of chemical and physical processes in

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the atmosphere, the hydrosphere and the cryosphere. The 87.4-day half-life and the ubiquity of

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sulfur in natural environments renders it an ideal tracer of many phenomena. Measurements of

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35

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of sample (>20 L) due to their high analytical activity background and low counting efficiency.

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Here, we present a new set of snow/water sample collecting and handling procedures for high-

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sensitivity determination of cosmogenic

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Laboratory experiments using diluted

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minute) showed a

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from the true value. Using this method, we successfully measured

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sample collected from a glacier on the Tibetan Plateau to be 47±7 mBq/L. Based on 35S activities

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in 9 natural samples measured in this study, a first proof-of-concept approximation for age

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determinations and source attributions was presented. This new method will provide a powerful

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tool in studying 35S in small volumes of snow and water samples, especially those from remote

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but climatically important regions such as the polar regions and the Tibetan Plateau and

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Himalayas. The measurements are particularly important as the radioactive sulfur provides an

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actual clock of glacial melting processes. With the growing rate of glacial loss, the need for

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measurements from remote locations becomes all the more important.

S in snow and water samples are scarce as existing analytical methods require a large volume

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35

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S using a low-level liquid scintillation spectrometer.

S standards (with activities of 20 L) is required. Such large volumes of water are difficult to obtain in the field,

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especially in the remote but climatically important region such as the polar regions and the

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Tibetean Plateau and Himalayas. For example, the Tibetean Plateau and Himalayas region,

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which is also widely known as the third pole because it contains the largest ice store outside the

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polar regions, provides fresh water supply to nearly 40% of the world’s populution.17-18 The

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glacier retreat and snow melting in this region play an crucial role in the hydrological cycle in

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Asia but are not well understood because the harsh environment restricts comprehensive field-

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based measurements. Therefore, a high-sensitive analytical method for measuring

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volumes of water sample is required to assist in such quantification.

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S in small

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Recently, Brothers et al.19 modified the sample preparation method for the low-level liquid

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scintillation counting technique and suggested to convert sulfur samples to aqueous

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Na2SO4/H2SO4. It was shown that counting aqueous Na2SO4/H2SO4 generated a high counting

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efficiency (up to ~95%) and a low background activity (~0.9 counts per minute, cpm). This

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optimizition made 35S measurements in small sizes of samples possible. Even though this method

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has led to a growing number of

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insights into the vertical and horizontal transport processes in the atmosphere,20-24 the utility of

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35

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preparation method for natural water. Although our previous studies successfully measured

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in small volumes (~3 L) of glacier snow and runoff samples collected from the Tibetan Plateau

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and Himalayas using ion exchange resins,25-26 the reliability of the sample handling method was

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not unambigously demonstrated and reported in detail, which resulted in uncertainties in data

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interpretation and restricted further comprehensive studies. In this study, a series of control

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experiments were conducted to evaluate the accuracy of previous measurements25-26 and develop

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a new, simple and economical method for collections of snow, ice and meltwater samples and

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the highly sensitive and accurate analysis of comosgenic 35S activity. The 35S activities in natural

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samples collected from a glacier on the Tibetan Plateau were determined using our newly

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developed method.

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S measurements in aerosol samples, which provide new

S in hydrologic studies remains limited, mainly due to a lack of sample collection and

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S

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Analytical Chemistry

Experimental Sections

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Ultra-Low-Level Liquid Scintillation Spectrometer and Counting Efficiency. In this study, an

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ultra-low-level liquid scintillation spectrometer (Quantulus 1220, PerkinElmer) was used to

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quantify cosmogenic

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Shape Analyzer and the Pulse Amplitude Comparator) on the Quantulus 1220 followed the

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default setting for

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decay of 35S (EMax = 167 keV) and 14C (EMax = 156 keV).5, 19 The 35S counting window was set as

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channel 1-450 to minimize the possible influence of

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sample was counted for 12 times (2-h counting for each cycle) and the average was reported.

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Potential outliers, if any, were identified by the Dixon’s Q-Test (99% confidence level) and

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rejected. In all measurements made in this study, no outlier was identified. Using the

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propagation-of-error method of the standard environmental counting statistics,27 the net counting

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error (95% confidence level) can be calculated as follows:

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S activity. The setting of two software selectable parameters (the Pulse

C because of the significant overlap between the energy spectra of the β-

 = 1.96 × (

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C (with peak at channel ~485). Each

 + )

 

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where S and B represent sample and background counting rates, respectively, and tS and tB

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represent elapsed counting times at which sample and background counting rates were measured,

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respectively. In this study, the long elapsed counting time (24-h = 2-h × 12) yields a small error

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(e.g., 0.09 cpm for a sample with a counting rate of 2.0 cpm). Given the standard environmental

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counting statistics also recommends to divide the total counting time into several equal cycles to

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check variability of counting rates,27 we carefully checked results for 12 counting cycles (see

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examples in Figure 1) and found that the standard variation of 12 counting rates (e.g., 0.16 cpm

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for a sample with an average counting rate of 2.0 cpm) was greater than the net counting error

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estimated previously. Therefore, the larger error (i.e., one standard deviation for 12 counting

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cycles) was reported in this study. This error was further propagated in subsequent arithmetic

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calculations (e.g. corrections for the background activity and the decay time).27-28

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Standard or sample was prepared in aqueous form (Na2SO4/H2SO4) instead of solid form 133

Ra,

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(BaSO4) to eliminate the potential contamination of other radionuclides (e.g.

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and their daughter products) in BaCl2 reagents.8,

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quantitatively transfer to a 20-mL plastic scintillation vial (Fisherbrand) and mixed with 10 mL

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of scintillation gel (Insta-Gel Plus, PerkinElmer). Plastic scintillation vials had a lower

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background activity (~0.15 cpm) than traditional glass vials which contain

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The mixed cocktail was shaken and vibrated vigorously prior to loading into the ultra-low-level

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liquid scintillation spectrometer.

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Ba,

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Ra

The pure Na2SO4/H2SO4 solution was

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K (~0.45 cpm).19

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The background and counting efficiency for various volumes of Na2SO4/H2SO4 samples are

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summarized in Table 1. Similar to our previous study,19 the counting efficiency of this method

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was greater than 90% if 1 mL of aqueous solution was used. However, such small volume of

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solution was potentially problematic in natural sample analysis because as little as ~0.1 M of

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SO42- can impede the formation of a stable microemulsion and cause phase instability due to the

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divalent charge and relative size of divalent anions.8, 29 In addition, if the aqueous solution was

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not completely clean, trace amount of organics from natural samples may also lead to color

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quench problems in such a small volume of solution.29 Table 1 shows that the counting

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efficiency dropped down to 79.0±0.4% when 2 mL of aqueous solution were used, but the

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further losses of counting efficiency due to using larger sample volume (5 mL) were marginal.

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Therefore, we diluted the solution to a larger volume (5 mL) to eliminate the potential problems

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of phase instability and color quench. It should be noted that the sample should be counted as

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soon as possible after the sample-gel mixture was made, because we found that the counting

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efficiency for 5 mL of aqueous solution dropped down to 2 mmol of sulfate

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was added to cocktail. Based on the fitted polynomial curve (Figure 2b), an upper limit of 1.5

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mmol of sulfate is recommended for this method. If the analytical goal is to measure samples

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with low 35S SA, e.g. groundwater and seawater, converting sulfate to BaSO4 is required and a

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method recently developed by Uriostegui et al.8 is recommended.

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Standard Preparation. The

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S activities in environmental samples, which depend on the

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sample size and storage time, are usually less than 5 dpm. A H235SO4 standard (PerkinElmer),

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which was stored separately in a locker at the Radiation Division of the Environment, Health and

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Safety Department (EH&S) at the University of California San Diego (UCSD), was diluted to

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laboratory sub-standards with comparable activities (< 5 dpm) in the EH&S. These sub-standards

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were used to develop the sample extraction and purification method for

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sensitive, accurate and economical way. To prevent any possible cross-contamination in

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experiments, these sub-standards were stored in a different laboratory (instead of our wet

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chemistry laboratory).

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S analysis in a

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Concentrating SO42- in the Field Using Anion Exchange Resins. Previous methods using

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Amberlite IRA 400 anion exchange resins for large volumes of samples (>20 L) require the

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acidification of samples using concentrated hydrochloric acid (HCl) and the exchange efficiency

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enhancement using a pump or an industrial spinner.7-8 Such complicated concentration processes

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are conventionally performed in the laboratory. In this study, because the aqueous

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Na2SO4/H2SO4 method has a lower background activity and higher counting efficiency (Table

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1), only ~3 L of water is required. We utilized a Bio-Rad AG1-X8 anion exchange resin

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(analytical grade, 100-200 mesh, chloride form) to concentration sulfate, which adsorption

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efficiency and recovery percentage for anions in fresh water samples is greater than 98%.30 In

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this study, the focus is on the recovery percentage of 35S. This concentration method is relatively

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simple and straight forward and easily done in the field. It eliminates transporting large volumes

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of water (~3 L per sample) from the field to the laboratory. This method is especially convenient

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and economical for collecting samples from remote regions. Before using, the resin (3-4 mL)

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was filled into a plastic column (Bio-Rad; i.d. 0.8 cm, length 4 cm) and rinsed by 5 mL deionized

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(DI) water (18 MΩ·cm) for three times. Sulfate was collected by gravity dripping samples (or

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laboratory sub-standards with known

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capacity of the AG1-X8 anion exchange resin is 1.2 meq/mL, and therefore 3-4 mL of resin can

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handle most snow and melted water samples.

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S activities) through the resin column. The exchange

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Elution of SO42- from Anion Exchange Resins. Sulfate trapped in resins was eluted by gravity

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dripping 15 mL of 1 M hydrobromic acid (HBr) through the column in 5 mL increments. To

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quantitatively collect all samples trapped in resins, 15 mL of DI water was dripped through the

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column in 5 mL increments and collected after elution with HBr. Positive air pressure was

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applied to inject residual eluent/water using a clean 60-mL syringe. The 30 mL of eluent

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containing SO42-, NO3-, Cl- and Br- was collected by a 50-mL plastic centrifuge tube. After

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stripping, excess Br-/Cl- (~15 mmol) must be removed because such high concentrations of ions

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cannot be handled by the scintillation gel.

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Purification Using Ag2O and Preparation of Aqueous SO42 for Counting. Two sets of

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experiments were performed to remove excess Br-/Cl- ions in two different ways. In this set of

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experiments (set 1), excess Br-/Cl- were precipitated as AgBr/AgCl by slowly adding Ag2O (~2

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grams) in successive increments of ~0.4 grams. The pH of the solution was tested by pH paper to

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ensure that Br-/Cl- completed precipitation and the solution turned neutral (pH≈7). The

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AgBr/AgCl slurry was removed by a disposable vacuum-driven filtration system (with 0.22 um

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Millipore Express Plus Membrane, Steriflip, Millipore) and the filtrate was collected by another

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clean 50-mL centrifuge tube. An additional ~10 mL of DI water was used to wash any trace

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amount of sample left in the original 50-mL centrifuge tube and the filter membrane into the new

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50-mL centrifuge tube in successive increments of ~5 mL, bringing the sample volume to ~40

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mL. This large volume of solution must be concentrated for further processing. It is noted that

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H2SO4 reacts with Ag2O to form Ag2SO4,31 which is minimally soluble in water (0.83 g / 100 mL

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at 25°C). To minimize the possible losses of

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sample, 5 mL of 1000 ppm Na2SO4 solution containing no

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solution was evaporated and dried in a clean oven (80°C) overnight. After drying, the sample

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was re-dissolved by adding 2 mL of DI water to the 50-mL centrifuge tube and was subjected to

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sonication for 1 hour.

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S during handling small volume (~1 mL) of 35

S was added to the solution. The

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The subsequent cleaning procedure followed the protocol developed by Brothers et al.19: the 2

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mL of solution was passed through a polyvinylpyrrolidone (PVP) column and a Ag-cartridge

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(Dionex OnGuard II) to remove organics and any remaining Cl- (or Br-), respectively, and was

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collected by a 15-mL centrifuge tube. An additional ~8 mL of DI water was used to wash trace

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amount of sample left in the 50-mL centrifuge tube, the PVP column and the Ag-cartridge into

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the 15-mL centrifuge tube in successive increments of ~2 mL. The 15-mL centrifuge tube

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containing ~10 mL solution was put in a freeze-dryer overnight. After freeze-drying, the sulfate

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sample (white crystalline solid) was re-dissolved again by added 1 mL of DI water and was

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sonicated for 1 hour. If any remaining dirty residue was observed in this step, ~2 mL of

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hydrogen peroxide (H2O2) was added to remove organics and PVP-cleaning and freeze-drying

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should be repeated. Following this cleaning procedure, the sample was ready to transfer to a

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plastic scintillation vial for preparing the sample-gel mixture. To quantitatively transfer, the

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“empty” 15-mL centrifuge tube was washed with 1 mL DI water and transferred into the

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scintillation vial and this procedure was repeated for four times. The sample-gel mixture was

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prepared and sent to the Quantulus 1220 following the procedure described in the previous

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section (Ultra-Low-Level Liquid Scintillation Spectrometer and Counting Efficiency).

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Our results show that the recovery percentage of

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S was ~90% in this set of experiments

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(Table 2). It is noted that the sulfur carrier (Na2SO4) is important because without adding Na2SO4

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the recovery percentage was less than 50% (i.e., the measured 35S was more than -50% deviation

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from the true value) (set 0) (Table 2). Since our previous pilot study25 did not notice the

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importance of the sulfur carrier, the measured

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processing) may be underestimated. Another concern is the cost of Ag2O (Fisher Scientific,

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current price: ~900 US$ for 100 grams). Previous studies used 15 mL of 3 M HCl as eluent to

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strip NO3- and SO42- samples from AG1-X8 resins, which required ~6.5 grams of Ag2O (~60

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US$) to remove excess Cl- for each sample.30 Even though 15 mL of 1 M HBr was used as the

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eluent in this study, which can significantly cut down the required amount of Ag2O without

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reducing the recovery percentage of anion because the relative selectivity of Br- for AG1-X8

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resin is more than 2 times greater than Cl- (AG1, AG MP-1 and AG2 Strong Anion Exchange

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Resin

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rad.com/webroot/web/pdf/lsr/literature/9114_AG_1.pdf), the cost for each sample remained high

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(~18 US$). Therefore, we developed another set of experiments to remove Br-/Cl- without using

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Ag2O.

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Instruction

S activities (without the sulfur carrier during

Manual:

http://www.bio-

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Improved Purification Method Using H2O2. In this set of experiments (set 2), 5 mL of 30%

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H2O2 was added to eluent to oxidize HBr/HCl to Br2/Cl2. The color of solution immediately

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changing from colorless to yellow characterizes the formation of Br2. The H2O2 can also help to

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remove organics in the solution. Following adding H2O2, 5 mL of 1000 ppm Na2SO4 containing

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no

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vapor pressure: