INTRODUCTION
The radiocarbon AMS laboratory in Novosibirsk started its operation in 2011 after installing the 1 MV AMS facility built by the Budker Institute of Nuclear Physics (BINP) (Parkhomchuk and Rastigeev Reference Parkhomchuk and Rastigeev2011). In the first years of work, graphite targets were made by cryogenic distillation of CO2 with a subsequent reduction of carbon dioxide to graphite, requiring much time and human resources and, therefore, unsuitable for multiple biomedical samples. However, using AMS in biomedical applications seemed extremely promising (Arjomand Reference Arjomand2010; Synal Reference Synal2013; Parkhomchuk et al. Reference Parkhomchuk, Petrozhitskiy, Ignatov, Kuleshov, Kalinkin, Prokopyeva, Kutnyakova and Parkhomchuk2022), and we were forced to develop our own graphitization system. The graphitization method using an elemental analyzer to gasify the sample and AGE-3 to reduce the generated CO2 (Wacker et al. Reference Wacker, Nemec and Bourquin2010) was available only in Moscow, 3000 km from our laboratory. To simplify and reduce the running costs of the graphitization procedure, we proposed a new approach based on the fast catalytic combustion of the sample followed by “inverted” carbon dioxide purification, which is a one-step CO2 separation from oxidation products by the selective sorption and subsequent reduction by H2 (Lysikov et al. Reference Lysikov, Kalinkin, Sashkina, Okunev, Parkhomchuk, Rastigeev, Parkhomchuk, Kuleshov, Vorobyeva and Dralyuk2018). After optimizing parameters such as the amounts of sorbent and sample weight, gas flow rate, types of catalyst and amounts needed for organic matter combustion and CO2 reduction, and setup automation, the absorption-catalytic setup (ACS) was installed in 2015 (Figure 1) and started to operate together with BINP AMS. The proposed method was found to be reproducible according to the results for the OX-I and OX-II standards measured from 2015 to 2018. This method was successfully used for dating different types of samples, including CO2 dissolved in natural waters (Novikov et al. Reference Novikov, Kopylova, Pyryaev, Maksimova, Derkachev, Sukhorukova, Dultsev, Chernykh, Khvashchevskaya, Kalinkin and Petrozhitsky2023) and methane from seeps (Sabrekov et al. Reference Sabrekov, Terentieva, McDermid, Litti, Prokushkin, Glagolev, Petrozhitskiy, Kalinkin, Kuleshov and Parkhomchuk2023), and showed consensus with the data from some other laboratories (Molodin et al. Reference Molodin, Nenakhov, Mylnikova, Parkhomchuk, Reinhold, Kalinkin, Parkhomchuk and Rastigeev2019; Rudaya et al. Reference Rudaya, Krivonogov, Słowinski, Cao and Zhilich2020). With the ACS, BINP AMS was applied for studying the penetration of organic aerosols inhaled by laboratory mice at ultra-low concentration ca. 103 cm–3. For this purpose, we synthesized polystyrene beads composed of radiocarbon-labeled styrene to be tested as model organic aerosols (Parkhomchuk et al. Reference Parkhomchuk, Gulevich, Taratayko, Baklanov, Selivanova, Trubitsyna, Voronova, Kalinkin, Okunev, Rastigeev, Reznikov, Semeykina, Sashkina and Parkhomchuk2016; Parkhomchuk et al. Reference Parkhomchuk, Prokopyeva, Gulevich, Taratayko, Baklanov, Kalinkin, Rastigeev, Kuleshov, Sashkina and Parkhomchuk2019). Since the ACS has proven successful for both ancient and 14C-enriched samples, we have installed and are currently operating two identical ACSs located 1.5 km apart in order to avoid cross-contamination.
Figure 1 Photograph of the ACS for sample graphitization: 1 – sample placement, 2 – combustion zone, 3 – zone of water vapor freezing; 4 – CO2 absorption on the CaO, 5 – CO2 desorption, 6 – CO2 collecting with liquid nitrogen, 7 – drying zone, 8 – pressure sensor, 9 – valves for automatic procedures: hydrogen addition, evacuation, CO2 collecting. The furnace for graphitization is not shown.
The MICADAS-28 (Synal et al. Reference Synal, Stocker and Suter2007) with AGE-3 was supplied to Novosibirsk State University (NSU) in December 2019 and on May 29, 2020, based on the Agreement signed by the rector of NSU and the directors of three institutions of the Novosibirsk Scientific Center (the Budker Institute of Nuclear Physics, the Institute of Archeology and Ethnography and the Boreskov Institute of Catalysis), AMS Golden Valley was created, with the name given after the place where the Novosibirsk Akademgorodok was founded.
This was the first time that our laboratory participated in the radiocarbon intercomparison. To test all possible toolkits during the Glasgow International Radiocarbon Intercomparison, we conducted three series of experiments: (1) AGE-3 + MICADAS-28, (2) ACS + MICADAS-28, (3) AGE-3 + BINP AMS, using the maximum possible number of samples. This work presents the results of AMS dating of the first and second series. The analysis of the GIRI results of the first and third series of experiments used to reveal the comparative characteristics of BINP AMS and MICADAS-28 can be found in the paper of Petrozhitskiy et al. (Reference Petrozhitskiy, Parkhomchuk and Ignatov2024).
MATERIALS AND METHODS
In November 2021, AMS Golden Valley received two sets of GIRI samples, including a total of seventeen natural substances such as wood, bone, cellulose, humic acid, and barley mash (Table 1). The volume of material in set 1 was sufficient to make a few repeat measurements. Set 2 (samples O and P) was sufficient to run multiple measurements and to be used for internal quality assurance. Three humic acid samples (B, D, and O) and one cellulose sample (M) pre-treated before being sent to the laboratory were graphitized without any pre-treatment, with remaining samples requiring pre-treatment. Eight samples were offered for earlier intercomparisons. The results were sent to Glasgow on April 18, 2022, and our report was presented at the 24th Radiocarbon Conference in September 2022 in Zurich.
Table 1 Results of GIRI samples graphitized by two devices, AGE-3 and ACS, and then measured on MICADAS-28 together with data on δ13C measured by MICADAS-28 and Delta-V-Advantage. F = the measured fraction modern with fractionation correction applied to both the sample and blank samples and corrected for background. Uncertainties represent 1 sigma.
1 – mean value ± stdev
2 – pretreatment not required
3 – δ15N = 12.8 ‰; C/N = 3.2
4 – δ15N = 12.7 ‰; C/N = 3.2
5 – given as F
Sample Preparation
Wood
Wood samples H, I, and P were subjected to multistage extraction purification on an automatic extraction unit ASETM350 (Accelerated Solvent Extractor - Dionex Corporation): 4 times with C2H2Cl2 : C2H5OH = 2 : 1, then 5 times with C2H5OH, and 6 times with distilled water until a colorless solution was obtained. The samples were dried at 60°C. Then, delignification was performed by a catalytic method in an acidic medium: 0.15 g of NaWO4 was dissolved in 40 mL of distilled water, dried wood samples were added to the resulting solution, 4 drops of concentrated sulfuric acid and 40 mL of 1% H2O2 were added, heated to 80°C, and kept for 4 hours. Then, the precipitate was separated from the solution, distilled water was added, boiled for 15 minutes, washing was repeated 3 times, 1% H2O2 was added, heated to 80°C, kept for 1 hour, and boiled again in distilled water for 15 minutes three times. The catalytic procedure was repeated twice. Then, 0.1M NaOH solution was added to the precipitate, kept at 70°C for 15 minutes, washed twice with distilled water, poured with 0.1 M NaOH solution, kept at 70°C for 45 minutes, washed twice with distilled water, and poured again with 0. 1 M NaOH solution. The precipitate was kept at 70°C for 60 minutes and washed 4 times with distilled water. Next, 1% H2O2 was added to the precipitate, kept at 75°C for 1 hour, then at room temperature for 12 hours, and washed twice with distilled water. The procedure was repeated 4 times under the same conditions, except for the NaOH concentration: 0.5 M instead of 0.1 M. Next, the precipitate was treated with 1 M HCl at 80°C for 1 hour and washed 4–5 times until pH = 7. A total of 9.4 mL of distilled water, 600 µl of 10% sodium chlorite, and 400 µl of 1 M HCl were added to the separated samples, kept at room temperature for 4 hours, washed with distilled water 2–3 times, and the procedure was repeated until a colorless solution and snow-white cellulose were obtained. Cellulose was separated from the solution, washed with distilled water about 15 times until the chlorine smell disappeared, and dried at 70°C.
Wood samples E, G, J, and Q were subjected to the same cleaning procedure, except for the H2O2 concentration during the catalytic treatment was 2.5% for samples E and Q and 5% for samples G and J, and the NaOH concentration from 0.5 to 1 M during the repeated alkaline treatment. Lower concentrations were used in case of doubts about the good preservation of the material to prevent the substance from being wasted.
Wood sample N also underwent a procedure similar to that described above, except for an additional acid treatment procedure (the precipitate was treated with 1 M HCl at 80°C for 1 hour and washed 4–5 times until pH = 7) after the catalytic stage before the alkaline treatment.
Bone
Bone sample K was washed with distilled water 7 times, dried, and ground on a Freezer/Mill cryogenic homogenizer to obtain 1.538 g of powder. The sample was divided into two parts, with one part (sample K(2)) subjected to extraction with dichloromethane at room temperature on an ASETM350 and dried at 70°C and the second part (sample K(1)) left without preliminary purification from insoluble organic components. Next, 1 M HCl was added to the samples and kept at room temperature (pH about 1–1.5) for 2 days. Then the precipitate was separated from the solution by centrifugation and washed with distilled water until pH = 7 was reached. Collagen was purified with a 0.1 M NaOH solution for 20 minutes until a colorless solution was obtained, then the precipitate was washed with distilled water to pH = 7. The precipitate was again immersed in a 1 M HCl solution for 20 minutes and then washed with distilled water to obtain a suspension with pH = 3. The resulting suspensions were thermostated at 70°C for 24 hours, with solutions separated from the precipitates by centrifugation. Collagen solutions were dried in a FreeZone freeze dryer (Labconco) to obtain collagen powder. The samples were then analyzed for δ13C, δ15N, and C/N levels. Afterward, the collagen underwent graphitization using AGE-3 and ACS.
Barley Mash
Barley mash samples A, C, and F were subjected to a modified ABA (acid-base-acid) treatment followed by pulp bleaching with sodium chlorite according to the following procedure. The ground samples were repeatedly treated with a solution of 1 M HCl at 80°C for 1 hour for each treatment until a light yellow solution was obtained. The first solution appeared dark brown, but it became brighter with each subsequent treatment. Then the samples were separated from the solution by centrifugation and washed with distilled water until the pH reached 7. Next, the samples were filled with 0.1 M NaOH solution and kept at 80°C for 30 minutes. The solution turned black-brown and was drained. A fresh 0.1 M NaOH solution was added and kept at 80°C for 30 minutes. The procedure was repeated 2 times until a light yellow solution was obtained. Then, the precipitates of all the samples were washed with distilled water, 1 M HCl was added, and the samples were kept at 80°C for 1 hour. After that, the samples were washed with distilled water until the pH was 7. Samples C and F yielding intensely colored solutions were again treated with alkali. The resulting precipitates were poured with 0.25 M NaOH and kept at 70°C for 15 minutes. This treatment was repeated twice more. Next, 1 M HCl was added at 80°C and kept for 1 hour. The precipitates were washed with distilled water, 60 µl of 10% sodium chlorite solution and 40 µl of 1 M HCl were added to 20 mL of an aqueous suspension, kept at 60°C, and the procedure was repeated several times until a colorless solution and snow-white cellulose were obtained. The cellulose samples obtained from barley samples were washed with distilled water and dried at 70°C.
Humic Acid
Humic acid samples B, D, and O and cellulose sample M were not chemically pre-treated before graphitization.
Graphitization
The conversion of the samples to graphite, including combustion, sorption of carbon dioxide on a selective sorbent, desorption, and catalytic reduction of CO2 with hydrogen (Figure 1) was performed using the ACS procedure (Lysikov et al. Reference Lysikov, Kalinkin, Sashkina, Okunev, Parkhomchuk, Rastigeev, Parkhomchuk, Kuleshov, Vorobyeva and Dralyuk2018). The combustion of a sample (4–10 mg) on the ACS was conducted in the oxygen flow on an aluminum-copper-chrome catalyst at 900°C to support total oxidation. Immediately after the combustion zone, water vapor was frozen out by an ice-salt mixture at –25ºC to avoid CO2 isotope fractionation in the gas flow. Absorption on the selective CO2 sorbent, CaO, was performed at 550°C, then the line was evacuated, and the sorbent was moved to a hot zone at 920°C for CO2 desorption. The released CO2 was frozen with liquid nitrogen in a quartz or Pyrex tube containing 7–8 mg of α-Fe powder (Aldrich-325 mesh). The gas pressure was measured, a 20% excess relative to the stoichiometric amount of hydrogen was introduced, and graphitization was performed at 550°C and a total pressure of about 1.2 bar for 5–6 hours. Prior to this procedure, the tube with Fe-catalyst was evacuated, filled with H2 to 1 bar, and kept at 550ºC for 30 minutes. The cold zone (at room temperature) of the tube contained a desiccant, magnesium persulfate, or silica gel impregnated with sulfuric acid, used to remove the resulting water and shift the equilibrium towards the elemental carbon formation. After the process was completed, 2 mg of the powder was obtained, and 1 mg of the powder was pressed into targets and sent for analysis to the MICADAS-28 or BINP AMS.
Another portions of the same samples were graphitized with an AGE-3 (Wacker et al. Reference Wacker, Nemec and Bourquin2010), followed by powder pressing into targets for MICADAS-28.
Given that we performed this intercomparison for the first time, we prepared two or even more graphites from most samples provided there was enough material to avoid any doubt in the sample quality. Samples H, L, and Q of single rings and a sample of Kauri wood I had enough material only for one device. Thus, we could not prepare graphite targets from them by ACS (Table 1).
Measurements
In addition to the data on δ13C for graphite samples from MICADAS-28, the measurements of δ13C and δ15N (the latter only for the bone sample K) for non-graphitized samples were also performed on a Delta-V-Advantage mass spectrometer (Thermo Scientific). These measurements were performed in the continuous helium flow mode (high purity grade 6.0) for the samples weighing 0.150–0.250 mg in CO2 and N2, obtained by the decomposition of the substance at 1020°C, relative to CO2 obtained from the ANU sucrose and IVA Urea standards, respectively, under the same conditions. The results were normalized to the VPDB scale. The reproducibility of the values was at the level of ± 0.2 ‰. C/N was measured by Flash 2000 (Thermo Scientific) in the continuous helium flow mode (purity grade A/B) for collagen samples weighing 1.5–2.5 mg and decomposed at 850°C, with respect to Urea standard.
AMS measurements for all graphite targets followed a routine measurement sequence designed in MICADAS. ОX-I (SRM 4990B) was used as a modern standard material, and Polyethylene STD (BN 268530 Thermo Scientific) was used as a background reference material. The MICADAS-28 results were analyzed using the BATS program (Wacker et al. Reference Wacker, Nemec and Bourquin2010).
RESULTS AND DISCUSSION
To determine the analysis tactics for wood samples containing several annual rings, we studied macroscopic features of the samples E, G, N, and P in reflected light on a Stemi 508 with a camera AxioCam HRc (Carl Zeiss) with 2× and 3.2× magnification to determine the number of rings in the sample. The maximum number of rings in the samples did not exceed 40 pieces, and all annual rings in one sample were averaged for each wood sample during the pre-treatment and the subsequent AMS analyses. Samples E, G, and P were represented by the oak, larch, and oak tree species, respectively. Shown in Figure 2 are the photographs of various tree species sections corresponding to samples E, G, N, and P.
Figure 2 Photograph of sections of GIRI wood samples, taken by the Stemi 508 with a camera AxioCam HRc: 1 – oak (sample E), 2 – larch (sample G), 3 – Kauri wood (sample N), 4 – oak (sample P). Imaging was carried out in reflected light with 2× (1, 4) and 3.2× (2, 3) magnification.
Table 1 presents the results on GIRI samples, graphitized by AGE-3 and ACS, and then measured on MICADAS-28 together with data on δ13C, measured by MICADAS-28 for graphite targets, and by Delta-V-Advantage before graphitization. The δ13C data obtained on MICADAS-28 for graphites were used for calculating F14C. Since there was no possibility of manual input of fractionation value on MICADAS, no corrections were made for the standard OXI samples. The deviations of δ13C measured by MICADAS-28 varied from 0.2 to 3.2 and from 0.2 to 22‰ for graphite targets, made on AGE-3 and ACS, respectively, showing that concentrating CO2 by equilibrium sorption from the gas flow (on ACS) gives higher isotopic fractionation than that one by chromatographic separation followed by the collection on the zeolite (on AGE-3). The slight variations in δ13C measurements between MICADAS-28 and Delta-V-Advantage indicate that isotopic fractionation does not significantly affect the chromatographic concentration of CO2 followed by graphitization. We noticed that if water was not removed from the gas stream after burning the samples, the isotope fractionation could reach 40% relative to the initial concentration of 14C due to the isotope separation in the gas stream and sorbent capture of only part of the stream: with the head part captured, 14C depletion was observed; with the tail part captured, 14C enrichment was observed. Therefore, for this process to be minimized in the ACS, after combusting the sample, water was frozen out with a salt mixture at approximately −25ºC. To account for the significant variations in the isotopic shift in the graphites obtained from ACS, we prepared several samples from one sample at this facility, if possible, to obtain an average of the F14C values. The issue of “memory” or cross-contamination on the ACS is not as acute as it is on AGE-3 due to two reasons. Firstly, CaO is a material with meso- and macropores (d > 2 nm), which does not impose diffusion restrictions on CO2, unlike zeolite with micropores < 1 nm. Secondly, CaO can be easily and daily substituted with a fresh portion of the material.
It can be seen from Table 1 that for most GIRI samples, the discrepancy between repeated measurements of graphites after both graphitization methods is less than the 1-sigma uncertainty for a single measurement. The sigma was adjusted according to the deviations in repeated measurements of graphites obtained from OXI. Interestingly, the deviation depends to some extent on the type of substance being graphitized. In the course of our work, we came to the conclusion that oxalic acid had the greatest discrepancy while coal and collagen had the lowest. However, the reasons for this issue are still unclear. In this regard, when 2–4 graphites for one sample were obtained, F14C values were averaged by the following way:
$$\overline F = {{\mathop \sum \nolimits_{i = 1}^N {F_i}/\sigma _i^2} \over {\mathop \sum \nolimits_{i = 1}^N 1/\sigma _i^2}}$$
$$stdev = \sqrt {{1 \over {\mathop \sum \nolimits_{i = 1}^N 1/\sigma _i^2}}} $$
In those cases when stdev was less than a variance (s) of mean F, the error of F was taken equal to the s:
$$s = \sqrt {{{\mathop \sum \nolimits_1^N {{\left( {{F_i} - \overline F} \right)}^2}} \over {N - 1}}.} $$
For example, for graphites of sample B produced on AGE-3 stdev calculated by (2) is 0.0008, and s calculated by (3) is 0.0002, while for graphites produced on ACS stdev calculated by (2) is 0.0024, and s calculated by (3) is 0.0029 (Table 1S). Formula (2) was used for samples A, B, D, E, F, H, J, M, Q, O, P, while formula (3) was used for samples G, I, K, L and N among the AGE-3 series. Among the ACS series formula (2) was used for samples D, E, G, K, M, N, O, P, and formula (3) was used for samples B and C. Thus, the highest value among the counting, systematic, and experimental deviations was taken as the error of the averaged value of F. The initially obtained values of F14C for individual graphites are presented in Table 1S, and the calculated averaged values of F14C and radiocarbon ages, produced from these values, − in Table 1.
Given the good convergence of the results obtained for AGE-3 and ACS on GIRI samples (Table 1), as well as the reproducibility of the results for standards (Fig. 3), a simple method of combustion and selective sorption of CO2 proved to be quite suitable for AMS dating. However, unlike graphites made by AGE-3, the ACS has a limitation in measuring ancient samples: background results of blank samples (polyethylene, PE) were 0.0024 ± 0.0009 (82 measurements) and 0.012 ± 0.003 (5 measurements) for AGE-3 and ACS, respectively. The values of F14C for PE graphitized by the ACS were 0.0131±0.0002, 0.0148±0.0002, 0.0063±0.0001, 0.0153±0.0002, and 0.0106±0.0002. We had only five because we do not usually use the ACS for MICADAS measurements, not including the experiments with GIRI samples. F14C for ANU standard, graphitized by AGE-3, was 1.5059±0.0037 (104 measurements), which is in perfect agreement with IAEA-C6 value (150.61 pMC).
Figure 3 F14C (×100), measured on MICADAS-28, for the oxalic acid (OX-I) standard, graphitized on AGE-3 and ACS, blank (PE) and sucrose (ANU), graphitized on AGE-3 (red line shows mean values).
The most suitable samples for the ACS are biological tissues, sulfurous samples such as oils, bottom sediments, soil samples, 14C labeled substances, and others. The ACS is less affected by impurities, has easily replaceable components, and is easier to maintain. However, due to the relatively high background— F14C from 0.005 to 0.03 measured by BINP AMS (A.V. Petrozhitskiy et al. Reference Petrozhitskiy, Parkhomchuk and Ignatov2024), and without special efforts to renew all the components of the ACS and prevent CO2 excess during its sorption from the flow, the upper limit of the radiocarbon age for routine measurements with ACS does not exceed 35,000 years. For example, the GIRI samples J and M, prepared by the ACS, were indicated as >35,000 years old. However, the measured fraction modern corrected for background for sample J was measured quite adequately (Table 1). The relatively large background fluctuations in the ACS and the need to correct the F14C for background may lead, in some cases, to a slight sample over aging, such as that observed for sample K. Probably the same reason caused some underestimation of the F14C value in modern samples A, C, F.
CONCLUSIONS
The AMS Golden Valley laboratory has participated in radiocarbon intercomparison for the first time and tested the procedures during the Glasgow International Radiocarbon Intercomparison. Here, we present the results of testing two different graphitization systems with AMS measurement using MICADAS-28. Both systems proved to complement each other perfectly, providing the possibility of measuring ancient and labeled samples, biological tissues, and those contaminated with various impurities, as well as those in various states of aggregation. Based on the simple principles of selective CO2 sorption, the ACS has been found to be less susceptible to poisoning by sulfur and halogens. However, due to its simple design and inexpensive consumables, this method is most suitable for multiple routine experiments and can be used for the traditional dating of objects no older than 35,000 years. The mean values of the background F14C were 0.0024 ± 0.0009 and 0.012 ± 0.003 for the AGE-3 and ACS, respectively, both methods giving reproducible results for OXI. The results obtained allow us to recognize the sufficient reproducibility of the results and the remarkable consistency of the experimental determinations.
ACKNOWLEDGMENTS
The work was conducted with the financial support of the Ministry of Science and Higher Education of the Russian Federation: Priority 2030 program, The Russian Academic Excellence Project 5-100, NSU program FSUS-2020-0036, and IAET program FWZG-2022-0007.
The authors are grateful to M.O. Filatova for optical microscopic analyses and to M.A. Kuleshova, O.V. Ershova, U.V. Sryvkina, E.V. Kuznetsova, and K.K. Kuznetsova for their participation in the work. We are especially grateful to Professor Marian Scott for providing the manusript with preliminary GIRI results and permission to make a comparison.
Supplementary material
To view supplementary material for this article, please visit https://doi.org/10.1017/RDC.2024.46
