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Article
Improved Separation of Pa from Th and U in marine Sediments with TK400 Resin Finn Süfke, Jörg Lippold, and Steffen Happel Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.7b04723 • Publication Date (Web): 19 Dec 2017 Downloaded from http://pubs.acs.org on December 20, 2017
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Analytical Chemistry
Improved Separation of Pa from Th and U in marine Sediments with TK400 Resin
1 2 3
Finn Süfke†*, Jörg Lippold†, and Steffen Happel‡
4 5 6
†
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*Corresponding Author: Finn Süfke (
[email protected])
Institute of Earth Science, Heidelberg University, Im Neuenheimer Feld 234, 69120 Heidelberg, Germany TrisKem International, 3 rue des champs Geons, 35170 Bruz, France
‡
8 9
Abstract
10
Protactinium-231 is a radio-nuclide of broad interest in paleoceanography and
11
paleoclimatology. This study describes an improved method for the purification and
12
separation of Pa from marine sediment samples using the new TK400 resin by TrisKem
13
International. The focus lies on the improvement of the separation of the abundant
14
from the Pa-fraction of the sample, which would reduce the peak tailing from
15
masses 231 and 233 during ICP-MS measurement. Furthermore, the reusability of TK400 has
16
been tested. For this purpose, the conventional method using Dowex AG1X8 for the
17
separation and purification of Pa has been compared to methods using the TK400 resin. A
18
combination of a Dowex AG1X8 prior to a TK400 column has shown most convincing results.
19
Based on our results we suggest a new efficient procedural method of analyzing 231Pa from
20
marine sediment samples using TK400. Chemical Pa yields for a Dowex-TK400 combination
21
are highest compared to the Dowex only method. Furthermore, the 232Th/231Pa ratio of the
22
Pa-fractions has been reduced by one order of magnitude compared to conventional
23
methods with Dowex AG1X8. Additionally, the reusability of TK400 resin up to nine times has
24
been proven. The usage of TK400 is only limited in the presence of samples with a high
25
matrix load (e.g. Fe). Therefore, matrix from sediment samples needs to be removed (here
26
using Dowex resin) before samples are loaded onto TK400. We also report series of
27
concentration measurements from standard reference materials (UREM-11, NIST 2702),
28
which have been used for 233Pa calibration.
29 30
Introduction
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Th
232
Th on
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31
With the improvement of measuring techniques, low concentrated trace-elements and their
32
isotopes have received increasing interest in ocean science. One set of these isotopes are
33
231
34
sedimentation and accumulation rates,1,2 paleoproductivity and boundary scavenging3,4,5 as
35
well as a proxy for ocean circulation strength (231Pa/230Th)6,7,8. Earliest studies were
36
performed with α and β spectrometry. While the inductively coupled plasma mass
37
spectrometry (ICP-MS) has emerged as the method of choice nowadays there also have
38
been successful attempts by TIMS9 and even AMS10.
39
Today ICP-MS is a widespread tool for the determination of isotopic composition. With its
40
high ionization efficiency this measuring technique allows the quantification of low
41
abundances.11 The concentration of 231Pa in marine sediments is typical in the order of very
42
few pg/g and decreases with age due to the relative short half-life of 32.5 ka12. But besides
43
the measurement method the preceding chemical preparation and separation of
44
bearing samples is essential to guarantee reliable results.
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In early studies13,14 Pa and Th have been separated from marine sediment samples using the
46
strong anion exchange resin Dowex AG1X8. Until today this resin represents the most
47
common agent for this purpose.15 With the development of new resins separation methods
48
have been improved and modified. In addition to Dowex other commonly used resins are
49
TRU,16,17 Silica gel,18 TEVA19 and UTEVA20. Separation methods have been modified for
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specific applications like sediment samples,20,21 seawater samples22,23 and nuclear material18.
Pa and
230
Th. In oceanography and paleoceanography they are applied as proxies for
231
231
Pa
Pa-
51 52
In particular, the chemical separation of Pa from marine sediments should fulfill following
53
requirements (a) good removal of sample matrix (b) separation of Pa from Th to prevent
54
peak tailing effects of
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separation of Pa from U to minimize the influence of the
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mother nuclide (d) and the chemical procedure should also be rapid and low-cost.
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Today’s method of accessing Pa and Th from marine sediments includes the total dissolution
58
of the sample material. Consequently, processed sediment solutions generally hold a very
59
high matrix load (dissolved ions). Matrix consists primarily of major elements like e.g. Si, Fe,
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Ca and Al which cause problems during separation and measuring of Pa due to their sheer
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abundance. During separation a high matrix load can occupy ion-binding sites in resins and
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prevent target ions like e.g. Pa from retention on the resin. Furthermore, if the matrix is not
232
Th on masses 231 and 233 during ICP-MS measurement (c)
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Pa decay product
233
U on its
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Analytical Chemistry
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removed before measurement, the large ion load can lead to major interferences when
64
using mass spectrometers.
65
Also a good separation between Th and Pa is essential for reliable measurements of the
66
231
67
measured using the ion counting mode of the ICP-MS at low resolution. Accordingly, both Pa
68
isotopes can be easily overprinted by a high 232Th peak tailing on masses 231 and 233 (Figure
69
1). The average
70
optimal separation of both elements is the foremost concern of every column
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chromatography approach.
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Most resins used today are expensive and thus the amount of potentially processed samples
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is limited. Furthermore, the quality of separation is linked to the amount of resin and acids,
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and the use of a large resin bed can result in a very time consuming procedure. In science
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cost and time should not be the limiting factor, but a proper method for daily use should be
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in a reasonable relationship to costs and time.
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In this study a modified separation method for Th, U and Pa is tested. Here the established
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Dowex AG1X8 resin is compared to the new TK400 resin (TrisKem) which comprised 1-
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octanol adsorbed to a semi-porous resin material24. The TK400 resin is expected to provide a
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good separation quality for Th and Pa25 but has not been tested with marine sediment
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samples yet. Here we assess the quality of the Pa separation from U and Th in marine
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sediments as well as the reusability of the TK400 resin as a factor for reducing costs.
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Experimental Section
84
Safety Considerations
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For microwave digestion of sediment samples 48 % HF has been used. HF should only be
86
handled following the compulsory laboratory rules in a fume hood connected to a washing
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system for acid fumes. Radioactive
88
emitter and should only be handled in appropriate laboratories designed and accredited for
89
radioactive substances.
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Standard Sample Solution
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All of the following described experiments have been performed using the same marine
92
sample material in order to guarantee unbiased comparability of the tested methods. For
Pa/233Pa ratio. Both Pa isotopes are present in very low concentrations and have to be
232
Th/231Pa ratio in marine sediments is in the range of ~ 2x106. Thus, an
237
Np used for the preparation of the
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Pa spike is a α-
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this purpose a composite of several deep sea sediment samples (~4 g in total) has been
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dissolved by microwave digestion and homogenized representing an average matrix solution
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typical for average deep sea marine sediments. This standard solution was enriched by few
96
ml of a 231Pa-solution obtained from sample remains from preceding 231Pa measurements in
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order to achieve reasonable high 231Pa levels. By this 250 ml of standard solution have been
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produced. 5 ml of this solution corresponds to ~100 mg of dried and mortared sediment and
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represents one sample for the following described method analyses. All samples and
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aliquots have exclusively been handled in PFA vials to prevent Pa from adhering to vial walls.
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Experiments
102
The TK400 resin has been tested with the marine sediment standard solution in three
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experimental sets. (1) TK400 resin has been directly compared to the conventional
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established separation method using Dowex AG1X8. (2) The reusability of already used
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TK400 resin has been tested. (3) Particle size of the TK400 resin and column geometry have
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been varied. Every test has been performed with at least two duplicates in order to ensure
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reliability of the results.
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(1) TK400 (100-150 µm) vs. Dowex AG1X8
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In a first experiment two subsequent applied Dowex AG1X8 columns following a method
110
slightly modified from published procedures21,14,26 have been compared to a method using
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one single TK400 column applying a slightly modified procedure suggested by Jerome et al.
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(2017)25 and Knight et al. (2016)24. Finally, a combination using one Dowex AG1X8 column
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followed by one column of TK400 applying the above mentioned methods has been tested.
114 115
For the first Dowex column a Bio-Rad Poly-Prep column is filled with 5 ml Dowex AG1X8. The
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resin is cleaned using 15 ml H2O (MQ-quality) and conditioned with 25 ml 8M HNO3. After
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loading the sample solution (5 ml) onto the column and elution of the matrix using 20 ml 8M
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HNO3, Th is eluted using 20 ml 9M HCl and 1 ml 9M HCl + 0.13M HF (4:1). Afterwards Pa is
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eluted with 10 ml 9M HCl + 0.13M HF (4:1). Finally, U can be eluted with H2O. The Pa fraction
120
is cooked to nearly dryness in concentrated HNO3 with drops of boracic acid to remove
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fluorides and then transferred into chloride form with concentrated HCl. Afterwards the Pa
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fraction is taken up in 9M HCl for the second Pa purification column. The column is filled
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with 3 ml Dowex AG1X8 and conditioned with 15 ml 9M HCl. After loading the sample, Th is ACS Paragon Plus Environment
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Analytical Chemistry
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removed with additional 15 ml of 9M HCl. Pa is eluted with 10 ml 9M HCl + 0.13M HF (4:1).
125 126
For the test using TK400 a modification of published protocols24,25 has been introduced. 2 ml
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TrisKem columns (AC-142-TK) have been filled with 2 ml TK400 (100-150 µm). The resin has
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been cleaned with one column volume (cv) of 1M HCl and one cv H2O (MQ-quality).
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Afterwards the resin has been conditioned with one cv 10M HCl before the sample has been
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loaded onto the resin. 20 ml of 10M HCl have been used to remove Th. Pa has been eluted
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with 20 ml of 1M HCl. After the elution of Pa the resin has been cleaned with two cv 1M HCl
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and one cv H2O (MQ-quality). Finally, the column including the resin has been stored in H2O
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for future use. This separation protocol does not allow the individual separation of a Th, U
134
and Pa fraction and was tested to evaluate the ability of TK400 separating Pa directly from a
135
sediment solution.
136 137
For this reason a combination of first applying a Dowex column followed by a TK400 column
138
for the purification of the Pa fraction has been tested.
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The first 10 ml of the Pa fraction from TK400 of all these experiments have been divided by
140
collecting the eluate in 2.5 ml steps to monitor the elution of the columns. The last 10 ml of
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the Pa fraction have been collected in 5 ml steps since Pa was expected to be present at low
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concentrations only here.
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(2) Reusability of TK400 (100-150 µm)
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In a second experiment the reusability of TK400 has been tested. For this purpose three
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individual columns have been used repetitively. One column has been run just with acid
146
without sample material. This blank-column was used to monitor changes in the resin due to
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stress from the recurring load with strong acid (10M HCl) and to monitor eventual
148
contaminations (Th and Pa) from the used chemicals or handling. The other two columns
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have been used with the standard sample solution three times in a row. Afterwards a blank
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run without sample solution has been performed to monitor an eventual memory effect of
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Pa in the resin. This procedure has been repeated three times. Overall TK400 has been
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tested nine times with the standard sample solution on two columns. For this experiment
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the afore described procedure has been applied (samples have been run first through a
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Dowex column before being loaded on TK400) with the exception that only 10 ml of the Pa
155
fraction have been collected in 5 ml steps. ACS Paragon Plus Environment
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(3) Change in particle size, resin volume and column geometry
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In a third experimental set the procedures of the first experiment have been repeated but
158
with modified TK400 column volumes or smaller particle sizes of the resin. The resin volume
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has been reduced to 1 ml to monitor if results from the first experiments can also be
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reproduced in shorter time and at lower costs. Further the geometry of the column has been
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changed to a wider column diameter. Finally, 2 ml of TK400 with a smaller particle size (50-
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100 µm) has been tested. This experiment was expected to be more time consuming but
163
may result in a better separation of Th and Pa as well as in higher chemical Pa yield.
164
233
165
To monitor the
166
from 237Np using silica gel columns11. For the determination of the original 231Pa content of
167
the standard solution a few samples have been spiked before column chemistry. All other
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samples have been spiked after column chemistry in order to define the chemical yield of
169
the various chemical treatments. In theory uncertainties in the yield calculation may arise
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from the ingrowth of
171
treatment as no chemical separation of 233U and 233Pa has been applied. However, because
172
measurements have been performed within less than one week after chemical procedures
173
and because of all experiments have been performed with the identical spike solution all
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results are highly comparable and distortions from 233U are thus negligible.
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The 233Pa spike was calibrated against an in-house pitchblende standard28. The reliability and
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the trueness of the obtained concentrations have been monitored by co-measuring of the
177
UREM-11 standard material29. According to Hansen and Ring (1983)30 UREM-11 is in
178
radioactive equilibrium featuring a certified uranium concentration of 58.48 ppm. From this
179
value a
180
repeatedly
181
term mean obtained in the years 2009 to 2017 is 34.00 ± 0.36 Bq/kg in reasonable
182
agreement to the expected value (Figure 2). However, two disadvantages of UREM-11 as a
183
standard material for measuring 231Pa/230Th from marine sediments becomes obvious: First,
184
its
185
Figure 2) and close only to very young and deep sediments from the opal rich Southern
186
Ocean31,32,3. Due to its high concentration very little net weight (max. 50 mg) of UREM-11
Pa-Spike calibration and Yield Calculation
231
231
231
Pa recovery, samples have been spiked with 233Pa.
233
U from
233
Pa has been milked
233
Pa (t1/2: 26.975 d)27 for samples spiked after chemical
Pa concentration of 33.5 ± 0.3 Bq/kg can be deduced29,20. The results of the 231
Pa-measurements of UREM-11 in Heidelberg is shown in Figure 2. The long-
Pa-concentration is way higher than that of typical deep-sea sediment (see green bar
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Analytical Chemistry
231
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has been used per sample. This, however, may lead to variations in the measured
188
concentration due to faint but obvious inhomogeneous distributions of
189
material. When using higher quantities of UREM-11 (e.g. >100 mg) these inhomogeneities
190
are tend to be averaged out. This behavior is also recognizable for 232Th and 230Th values of
191
UREM-11. That’s why other marine standard material might be more appropriate in order to
192
monitor the quality of the obtained isotopic concentrations from marine sediments. The
193
most comprehensive attempt so far providing a marine-based
194
been performed by an international inter-lab-calibration in the framework of GEOTRACES
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distributing siliceous ooze sediment to a large number of laboratories23. The average
196
concentration of this material among the contributing laboratories yielded 20.83 ± 2.33
197
Bq/kg in good agreement to subsequent measurements at Heidelberg University (21.63 ±
198
0.23 Bq/kg, Figure 2). Other established sediment reference materials are rarely certified
199
and/or intercalibrated for 231Pa concentrations. For guidance here we provide values of 231Pa
200
concentrations for the commonly used NIST SRM 2702 measured in our lab within the last
201
years (Figure 2)33,34.
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A third disadvantage of UREM-11 as a standard material for measuring
203
excess (that is the fraction of both radioisotopes produced in-situ from the decay of 235U and
204
234
231
U) from marine sediments is given by the lack of a certified 232
Pa-
231
Pa within the
Pa-reference material has
232
231
Pa- and
231
230
Pa
Th-
Th-concentration for this
205
standard material. Knowledge about the
206
sample is required in order to correct for lithogenic contributions35,36. Here we report a value
207
based on 55 individual repetitive measurements of the UREM-11
208
yielding an average of 42.87 ± 0.34 Bq/kg (supplementary information).
209
Measurement
210
Radionuclides
211
Element2 single collector ICP-MS at the Institute of Earth Sciences, Heidelberg University,
212
Germany with an APEX IR desolvating system. To prevent clogging all samples have been
213
filtered before being placed in the auto-sampler. All isotopes were measured in low
214
resolution mode by ion counting. Washing steps after each sample comprised a 2M nitric
215
acid solution doped with traces of HF to efficiently remove Th and Pa from hoses and reduce
216
memory effects (washs). The washs have been used for background corrections, but never
217
reached more than 0.5 % of average sample signal on
218
influence of
231
232
Pa,
232
Th,
233
Pa and
236
Th concentration of the examined sediment
232
Th concentration,
U have been measured using a Thermo Finnigan
231
Pa. In order to monitor the
Th peak tailing on masses 231 and 233 a Th-standard solution without ACS Paragon Plus Environment
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231
Pa and 233U/233Pa has been measured in intervals. Instrumental drift has
219
contributions of
220
been monitored by using an in-house synthetic 231Pa-233U solution.
221 222
Results and Discussion
223
Chemical Yield and Purity
224
The standard sample solution had a
225
concentrations of the collected
226
0.052 pg/g ± 0.001 for Dowex-columns to 0.087 pg/g ± 0.002 for a Dowex-TK400
227
combination (Figure 3a).
228
Accordingly, chemical Pa yield is 27 ± 4 % for two successive Dowex columns implying that a
229
single Dowex column recovers 9M) HCl. Indeed, our TK400 (100-150 µm)
255
tests yielded
256
eluted with 1M HCl. Results for the first eluted 5 ml are clearly better with 232Th/231Pa ratios
257
even below 30. Since this first 5 ml contains the majority of Pa, elution is recommended to
258
be stopped at this point if an exceptionally clean Pa fraction is wanted, however at the
259
expense of slightly lower recovery.
260
Furthermore, experiments with less resin or finer particle sized (50-100 µm) TK400 have
261
obtained slightly worse results with 232Th/231Pa ratios ranging between 100 and 600, but still
262
better than separation with Dowex. Accordingly, summarizing all of the here presented
263
results the method applying 2 ml TK400 with a particle size of 100-150 µm seems the most
264
effective procedure for separating Pa from Th.
265
In order to monitor the separation of Pa from U, samples have been spiked after the first
266
Dowex column with a
267
respectively. The initial
268
reduced this ratio down to 236U/231Pa ~4-6 in the first collected 10 ml. Therefore, Dowex and
269
TK400 appear to be equally efficient in the separation of U and Pa.
270
Reusability
271
In a further experiment the reusability of TK400 resin (100-150 µm) has been tested. The
272
limit of reuse is monitored by the recovered amount of 231Pa in the collected Pa fraction as
273
well as the 232Th/231Pa ratio. The Pa fraction has been collected in two 5 ml steps. The first 5
274
ml of the Pa fractions, which hold the predominant portion of the eluted Pa as seen from
275
prior experiments, have been spiked with
276
are on a very constant level (average 0.061 ± 0.004 pg/g, Figure 5). Furthermore, even after
277
the ninefold use of the same TK400 resin chemical yields are still clearly better than found
278
for the Dowex column used only once. This indication for good reusable is also confirmed by
279
the 232Th/231Pa ratios repeatedly below 80 for the first 5 ml of the collected Pa fraction and
232
Th/231Pa ratios always below 200 for the collected 10 ml of the Pa-fraction
236 236
U spike for both TK400 and Dowex as the second column
U/231Pa ratio before the second column was ~4,400. Both resins
233
Pa.
231
Pa concentrations of the spiked aliquots
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Page 10 of 24
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below 120 for the complete Pa fractions (Figure 5). These results are in the same order as
281
seen in the first experiments when testing TK400 (100-150 µm) versus Dowex performance.
282
All these results suggest that TK400 (100-150 µm) is a robust resin that shows no loss of
283
performance even after multiple use. Although notably the column flow through extended
284
by one hour from the first to the ninth repetition with the standard sample solution.
285
The cleaning procedure has been monitored by collecting and measuring blank solutions
286
rinsed through the cleaned resin. All Blanks did show no measurable accumulation of Pa in
287
the TK400 resin. Counts on 231Pa and 233Pa in the blanks have been negligibly low and can be
288
interpreted as artefacts (
