Introduction
Radiocarbon (14C) analysis by high-precision accelerator mass spectrometry (AMS) is an increasingly active area of research in dendrochronology and the Earth sciences. Radiocarbon analysis of tree-ring time series is used to construct 14C calibration curves (Hogg et al. Reference Hogg, Heaton, Hua, Palmer, Turney, Southon, Bayliss, Blackwell, Boswijk and Bronk Ramsey2020; Hua et al. Reference Hua, Turnbull, Santos, Rakowski, Ancapichún, De Pol-Holz, Hammer, Lehman, Levin and Miller2021; Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Bronk Ramsey, Butzin, Cheng, Edwards and Friedrich2020), which enable determination of the calendar age of a sample (e.g., a prehistory artifact) from its 14C age. Furthermore, tree-ring radiocarbon analysis can provide information about solar activity during the pre-telescope period, such as long solar cycles, and therefore contributes to a better understanding of the physical basis of the sun’s activity (Damon and Sonett Reference Damon, Sonett, Sonett, Giampapa and Mattheus1991; Suess Reference Suess1980; Stuiver and Braziunas Reference Stuiver and Braziunas1993; Usoskin et al. Reference Usoskin, Solanki, Krivova, Hofer, Kovaltsov, Wacker, Brehm and Kromer2021). In addition, exceptional increases in tree-ring 14C abundance, as observed for events in the years 774 AD and 993 AD, may indicate past occurrences of solar super-flares (Büntgen et al. Reference Büntgen, Wacker, Galván, Arnold, Arseneault, Baillie, Beer, Bernabei, Bleicher and Boswijk2018; Miyake et al. Reference Miyake, Nagaya, Masuda and Nakamura2012, Reference Miyake, Masuda and Nakamura2013; Usoskin et al. Reference Usoskin, Kromer, Ludlow, Beer, Friedrich, Kovaltsov, Solanki and Wacker2013; Uusitalo et al. Reference Uusitalo, Arppe, Hackman, Helama, Kovaltsov, Mielikäinen, Mäkinen, Nöjd, Palonen and Usoskin2018).
Cellulose is commonly utilized in tree-ring based isotope analysis. As a major structural component of xylem cell walls, cellulose does not migrate between tree rings and is therefore unambiguously linked to the year of tree-ring formation (Leavitt and Danzer Reference Leavitt and Danzer1993). Cellulose composition is comparatively simple, thus avoiding potential bias due to varying proportions of constituents between tree-rings (Rinne et al. Reference Rinne, Boettger, Loader, Robertson, Switsur and Waterhouse2005). Early studies recommended the use of α-cellulose for radiocarbon analysis since α-cellulose only contains D-glucose monomers (Head Reference Head1979; Hoper et al. Reference Hoper, McCormac, Hogg, Higham and Head1998; Stuiver and Quay Reference Stuiver and Quay1981). However, more recent studies have shown that 14C abundance of holocellulose is not systematically different from α-cellulose (Capano et al. Reference Capano, Miramont, Guibal, Kromer, Tuna, Fagault and Bard2018; Hajdas et al. Reference Hajdas, Hendriks, Fontana and Monegato2017; Lange et al. Reference Lange, Nordby, Murphy, Hodgins and Pearson2019; Michczyńska et al. Reference Michczyńska, Krąpiec, Michczyński, Pawlyta, Goslar, Nawrocka, Piotrowska, Szychowska-Krąpiec, Waliszewska and Zborowska2018; Southon and Magana Reference Southon and Magana2010; Staff et al. Reference Staff, Reynard, Brock and Bronk Ramsey2014). Since holocellulose extraction from wood is less labor-intensive than α-cellulose extraction, holocellulose has become the preferred analytical substrate for reconstructing interannual atmospheric 14C content (Büntgen et al. Reference Büntgen, Wacker, Galván, Arnold, Arseneault, Baillie, Beer, Bernabei, Bleicher and Boswijk2018; Brehm et al. Reference Brehm, Bayliss, Christl, Synal, Adolphi, Beer, Kromer, Muscheler, Solanki and Usoskin2021, Reference Brehm, Christl, Knowles, Casanova, Evershed, Adolphi, Muscheler, Synal, Mekhaldi and Paleari2022; Güttler et al. Reference Güttler, Wacker, Kromer, Friedrich and Synal2013; Wacker et al. Reference Wacker, Güttler, Goll, Hurni, Synal and Walti2014).
To extract cellulose (either holocellulose or α-cellulose) from wood materials is a central step in the preparation of tree-ring samples for radiocarbon analysis. Cellulose extraction involves the removal of resins and lignin via organic solvent extraction and chlorination (Green Reference Green and Whistler1963; Leavitt and Danzer Reference Leavitt and Danzer1993), or alkaline extraction and chlorination (Rinne et al. Reference Rinne, Boettger, Loader, Robertson, Switsur and Waterhouse2005; Wieloch et al. Reference Wieloch, Helle, Heinrich, Voigt and Schyma2011). The cellulose extraction process requires repeated addition and removal of reagents as well as washing and is, therefore, a highly labor-intensive process. Consequently, dendro-scientists have developed various devices to facilitate batchwise extraction of cellulose. These include filter bags (Cullen and Macfarlane Reference Cullen and Macfarlane2005; Leavitt and Danzer Reference Leavitt and Danzer1993), filter tubes or funnels with or without polytetrafluorethylene (PTFE) drainage blocks (Andreu-Hayles et al. Reference Andreu-Hayles, Levesque, Martin-Benito, Huang, Harris, Oelkers, Leland, Martin-Fernández, Anchukaitis and Helle2019; Harada et al. Reference Harada, Watanabe, Nakatsuka, Tazuru-mizuno, Horikawa, Sugiyama, Tsuda and Tagami2014; Loader et al. Reference Loader, Robertson, Barker, Switsur and Waterhouse1997; Fogtmann-Schulz et al. Reference Fogtmann-Schulz, Kudsk, Adolphi, Karoff, Knudsen, Loader, Muscheler, Trant, Østbø and Olsen2021; Wieloch et al. Reference Wieloch, Helle, Heinrich, Voigt and Schyma2011), and plate splines with PTFE punching sheets (Kagawa et al. Reference Kagawa, Sano, Nakatsuka, Ikeda and Kubo2015; Li et al. Reference Li, Labbé, Driese and Grissino-Mayer2011). With regard to radiocarbon analysis, however, all currently available devices carry the potential risk of external contamination and internal cross-sample-contamination due to either direct contact between tree-ring samples (plate splines) or their interconnected storage spaces (filter bags and funnels). For instance, Santos et al. (Reference Santos, Granato-Souza, Barbosa, Oelkers and Andreu-Hayles2020) report that the extraction procedure designed by Andreu-Hayles et al. (Reference Andreu-Hayles, Levesque, Martin-Benito, Huang, Harris, Oelkers, Leland, Martin-Fernández, Anchukaitis and Helle2019) can result in modern carbon contamination and suggest it is unsuitable for analyses of preglacial samples. This is a significant concern, especially because Sookdeo et al. (Reference Sookdeo, Kromer, Büntgen, Friedrich, Friedrich, Helle, Pauly, Nievergelt, Reinig and Treydte2020) recommend that, for high-precision radiocarbon analysis, cellulose extraction for tree-ring samples should be performed simultaneously with blank samples. Thus, a device for high-throughput extraction of tree-ring cellulose suitable for radiocarbon analysis (i.e., mitigating the risk of external and internal contamination) is currently unavailable.
To fill this gap, we adapted the batchwise cellulose extraction device developed by Wieloch et al. (Reference Wieloch, Helle, Heinrich, Voigt and Schyma2011), known as “multiple sample isolation system for solids” (MSISS) to radiocarbon analysis. First, to prevent cross-sample-contamination, we redesigned the drainage module to enable independent removal of chemical waste from each individual sample funnel. Second, to reduce the risk of external contamination, we added covers to the sample funnels. In the following sections, we start with a detailed illustration of the modified device, followed by an evaluation of its suitability for tree-ring cellulose extraction for radiocarbon analysis.
Description of the device
Two key modifications were implemented to adapt the original MSISS:
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1. Independent drainage channels: In the original MSISS, the drainage channels were interconnected. This bears the risk of transferring chemicals and contaminants among tree-ring samples. However, in the modified version, each tree-ring sample has its own separate drainage channel, which prevents cross-sample-contamination (Figure 1a).
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2. Funnel covers: In the original MSISS, the funnels are uncovered during entire experiment. This bears the risk of external contaminants entering the funnels. To address this issue, PTFE covers have been added to each funnel in the modified device (Figure 1a–d). These covers effectively prevent contaminants from falling into the funnel during the extraction process (Figure 1e). Additionally, the covers minimize volatilization of ClO2 and Cl2 gases produced during the acid NaClO2 treatment step. Each cover is equipped with a short handle for effortless lifting and replacing.
The modified device has an inverted T-shaped drainage module with staggered L-shaped drainage channels inside. The upper part of the drainage channel functions as an outlet (Figure 1a-d). On both sides of the drainage module, 18 funnels are arranged with PTFE covers. Numbers 1 to 18 are engraved next to the corresponding funnel for easy identification. Prior to chemical treatment, wood samples are placed into the funnels. Subsequently, chemical reagents are manually added to the funnels using a pipette gun. Once the chemicals are added, the funnels must be covered immediately to prevent contaminants from entering the system. Removing chemical waste from funnels can be achieved using a vacuum pump to create a negative pressure environment inside the drainage module. The silicone tube is attached to the outlet, allowing chemical waste to flow automatically into a collecting bottle. The covers do not need to be adjusted while chemical waste is pumping out because they are not air-tight seals. A filter disc (ca. 30–50 μm aperture size) is fixed at the base of each funnel, keeping the wood samples inside funnels during pumping (Figure 1c, f). The process of pumping chemical waste from each funnel just takes 3 to 5 seconds when using a vacuum pump with a suction rate of 10 L/min. With six drainage modules in a water bath (length: 600 mm; width: 300 mm; height: 130 mm), 108 tree-ring samples can be processed simultaneously (Figure 1d). The entire procedure must be conducted under a fume hood, since harmful gases are released during cellulose extraction.
Overall, these modifications are shown to significantly reduce the risk of contamination during cellulose extraction while maintaining the high efficiency of the existing device. For more information on the device design and availability, please refer to Text S1.
Materials and methods
Wood samples
Five wood samples of different ages were used to assess the suitability of the modified device for radiocarbon analysis (Table 1). The samples are IAEA-C9, a subfossil kauri wood from peat bogs in New Zealand (Hogg et al. Reference Hogg, Higham, Robertson, Beukens, Kankainen, McCormac, van der Plicht and Stuiver1995); NF142, a fossil pine wood from the late Miocene layer in Xianfeng Basin, Yunnan, China (Wang et al. Reference Wang, Oskolski, Jacques, Wang and Zhou2017); KB, a kauri wood from Marine Isotope Stage 7 in New Zealand (Sookdeo et al. Reference Sookdeo, Kromer, Büntgen, Friedrich, Friedrich, Helle, Pauly, Nievergelt, Reinig and Treydte2020); LWQ1796, a tree-ring sample of known age (1796 AD) from an absolutely dated spruce tree-ring-width chronology (LWQ; Figure S1; Chen et al. Reference Chen, Shang, Panyushkina, Meko, Li, Yuan, Yu, Chen, He and Luo2019) from Riwoche County in Xizang, China; AD1515, an architecture oak wood with a known age (1515 AD) from A. Bayliss of Historic England (Bayliss et al. Reference Bayliss, Howard and Tyers2023).
* Infinite ages denote ages that lie beyond the 14C dating limit (Taylor and Bar-Yosef Reference Taylor and Bar-Yosef2016). The 14C abundance of an infinite-aged sample is indistinguishable from background values.
Holocellulose extraction
The protocol for holocellulose extraction was conducted according to the revised Base-Acid-Base-Acid-Bleaching procedure as shown in Figure 2 (Němec et al. Reference Němec, Wacker, Hajdas and Gäggeler2010; Sookdeo et al. Reference Sookdeo, Kromer, Büntgen, Friedrich, Friedrich, Helle, Pauly, Nievergelt, Reinig and Treydte2020). Prior to chemical processing, the glass funnels and 10 mL glass vials were heated at 500°C for 4 hr in a Muffle oven (Lindberg/Blue M™, Thermo Scientific™, USA) to remove carbon contaminants. To attain the desired level of cleanliness, the glass funnels, PTFE drainage modules, silicone tubes, and covers were immersed for 24 hr in 1M HNO3 and ultrapure water respectively. To ensure an efficient chemical extraction of cellulose, all wood samples were sliced into grains of ca. 3×3×0.5 mm3 (Figure 1g). To reduce the corrosive effects of alkaline solution on the sintered glass filter discs inside the funnels, the first step was executed in the glass vials inside an oven (DHG-9123A, SANFA®, China). Subsequent steps were performed in a water bath environment using our modified extraction devices. The procedure is carried out under a fume hood, due to the release of harmful gases during cellulose extraction. In general, the second base step and the bleaching step should be repeated 3 times. However, fossil wood samples typically require more repetitions than other samples. The samples need to be rinsed in ultrapure water 3 times after the base steps and the first acid step, and 6 times after the bleaching step.
After chemical processing, the treated samples were transferred to clean glass vials, homogenized using an ultrasonic cell crusher (JY96-IIN, LICHEN®, China) and then subjected to lyophilization for 48 hr using a freeze dryer (Alpha 1-4 LSCbasic, Christ™, Germany). Subsequently, FTIR (Nicolet™ iS50, Thermo Scientific™, USA) was used to test the holocellulose purity (Kagawa et al. Reference Kagawa, Sano, Nakatsuka, Ikeda and Kubo2015; Schollaen et al. Reference Schollaen, Baschek, Heinrich, Slotta, Pauly and Helle2017). Extracting holocellulose from 108 samples was completed in less than a week. Since the system is scalable, higher sample throughputs are possible.
Radiocarbon analysis
Each treated sample (2.4 ± 0.1 mg) was wrapped in a tin foil vessel. The sealed samples were combusted at 920 °C in an organic elemental analyzer (vario ISOTOPE SELECT, ELEMENTAR™, Germany) and graphitized at 580 °C with hydrogen gas and iron powder in an automated graphitization system (AGE3, IONPLUS™, Switzerland). F14C (Reimer et al. Reference Reimer, Brown and Reimer2004) measurements were performed on graphitized samples at the Laboratory of AMS Dating and the Environment at Nanjing University on a compact radiocarbon AMS system (MICADAS, IONPLUS™, Switzerland; Wacker et al. Reference Wacker, Bonani, Friedrich, Hajdas, Kromer, Němec, Ruff, Suter, Synal and Vockenhuber2010a). Fractionation and background correction was conducted automatically using the BATS program (Wacker et al. Reference Wacker, Christl and Synal2010b) based on results of standard (OXII, NIST SRM 4990C) and 14C-blank (Phthalic Acid, PhA, Sigma Aldrich®, PN-320064-500g) samples. ΔF14C, which is defined as the deviation between the measured F14C of each replicate and their weighted mean (Santos et al. Reference Santos, Komatsu, Renteria, Brandes, Leong, Collado-Fabbri and De Pol-Holz2023) was calculated to demonstrate scatter of the replicates. Reduced χ2 (χ2 red, i.e., MSWD; Wendt and Carl Reference Wendt and Carl1991) was used to check the consistency of replicates.
Results
The FTIR results of both untreated and treated wood sample (LWQ1796) along with the international standard cellulose reference sample IAEA-CH3 are shown in Figure 3. In contrast to the wood spectrum, absorption peaks caused by resin lignin (dotted lines, 1596 cm–1, 1510 cm–1, 1455 cm–1, 1265 cm–1 and 1227 cm–1; Pandey and Pitman Reference Pandey and Pitman2003; Schollaen et al. Reference Schollaen, Baschek, Heinrich, Slotta, Pauly and Helle2017) are absent in the spectrum of treated sample. The spectrum of treated sample agrees with that of IAEA-CH3, confirming that lignin had been removed using our modified device. Notably, the absorption peak related to hemi-cellulose (dashed line, 1735 cm–1; Schollaen et al. Reference Schollaen, Baschek, Heinrich, Slotta, Pauly and Helle2017) is not obvious in the spectrum of treated sample, indicating a very low content of hemicellulose in our chemically treated sample. Similar result was produced by Khumalo et al. (Reference Khumalo, Svarva, Zurbach and Nadeau2024). However, we referred to the chemically treated sample as holocellulose because it did not undergo the standard α-cellulose extraction procedure involving alkaline treatment with 17.5% (w/v) NaOH solution (Anchukaitis et al. Reference Anchukaitis, Evans, Lange, Smith, Leavitt and Schrag2008; Gaudinski et al. Reference Gaudinski, Dawson, Quideau, Schuur, Roden, Trumbore, Sandquist, Oh and Wasylishen2005; Němec et al. Reference Němec, Wacker, Hajdas and Gäggeler2010).
The results of the radiocarbon analysis on treated 14C-blank wood samples are shown in Figure 4a–b (the data are listed in Table S1). NF142 and KB, which currently lack reference values, are compared directly with PhA without background correction (Figure 4a). The F14Cwm values (weighted mean of F14C values) for NF142 and KB are 0.0023 ± 0.00003 (n = 10) and 0.0019 ± 0.00005 (n = 4), respectively, which are comparable to PhA (0.0021 ± 0.00004, n = 6). The F14Cwm value of IAEA-C9 is 0.0021 ± 0.0002 (n = 8; i.e., 0.21 ± 0.02 pMC; Figure 4b), which concurs with previously reported reference values (0.12 to 0.21 pMC, Hogg et al. Reference Hogg, Higham, Robertson, Beukens, Kankainen, McCormac, van der Plicht and Stuiver1995; 0.2 ± 0.05 pMC, Scott Reference Scott2003). The ΔF14C of IAEA-C9 varies in the range −0.0006 to 0.0004. The χ2 red value of the IAEA-C9 replicates is 0.5, indicating that the replicated radiocarbon measurements are consistent. These results demonstrate that the 14C-blank wood samples were not influenced by other samples and confirm that no modern contamination was introduced during cellulose extraction.
Figures 4c–f show the results of our radiocarbon analysis on wood samples of known age. The ΔF14C of LWQ1796 and AD1515 varies within the range −0.0022 to 0.0032 (n = 9; Figure 4c) and −0.0012 to 0.0014 (n = 4; Figure 4d), respectively. The χ2 red values of LWQ1796 and AD1515 replicates is 0.7 and 0.2, respectively. According to ΔF14C and χ2 red, the replicates of both LWQ1796 and AD1515 are not significantly different. Although all AD1515 replicates have higher F14C values than the reference (F14Cref = 0.95805 ± 0.00014; Brehm et al. Reference Brehm, Bayliss, Christl, Synal, Adolphi, Beer, Kromer, Muscheler, Solanki and Usoskin2021), they are still in statistical agreement. The calibrated ages of LWQ1796 and AD1515 correspond to their known calendar ages (Figure 4e–f). These results indicate that our adapted device and methods are suitable for high-precision radiocarbon analysis.
Discussion
Exogenous contamination, possibly arising from inadequate cleaning of devices or use of inappropriate reagents, can impact high precision radiocarbon dating (Gaudinski et al. Reference Gaudinski, Dawson, Quideau, Schuur, Roden, Trumbore, Sandquist, Oh and Wasylishen2005; Anchukaitis et al. Reference Anchukaitis, Evans, Lange, Smith, Leavitt and Schrag2008). According to Santos et al. (Reference Santos, Granato-Souza, Barbosa, Oelkers and Andreu-Hayles2020), the use of current batchwise devices for tree-ring cellulose extraction yielded sub-optimal results for blank samples. This implies that substances originating from introduced contaminants and/or other wood samples inside the device may taint the blank samples. In this study, the original MSISS is adapted to extract holocellulose for radiocarbon analysis by converting the drainage channel from interconnected to independent, and adding funnel covers. The FTIR results show that our modified device can produce pure holocellulose, while the radiocarbon analysis revealed that there are no effects of contaminates on the blank or reference samples.
Pumping chemical waste out for each sample individually with our modified device requires more operations compared to the original MSISS, which has the capability of pumping dozens of samples simultaneously (Wieloch et al. Reference Wieloch, Helle, Heinrich, Voigt and Schyma2011). However, pumping out chemical waste for individual samples is still labor-saving compared to pipetting chemical waste from test tubes (Santos et al. Reference Santos, Komatsu, Renteria, Brandes, Leong, Collado-Fabbri and De Pol-Holz2023; Southon and Magana Reference Southon and Magana2010). Fogtmann-Schulz et al. (Reference Fogtmann-Schulz, Kudsk, Adolphi, Karoff, Knudsen, Loader, Muscheler, Trant, Østbø and Olsen2021) designed a system that is comparable to ours but contains more intricate and bigger funnels with valves. The smaller funnels of our device enable the simultaneous extraction of more samples. Meanwhile, our modification enables a laboratory currently equipped with MSISS to manufacture the new drainage modules and covers, while the glass funnels, silicone tubes, and vacuum pump remain unchanged. This is more convenient and economical than ordering and designing new devices.
In summary, the adapted tree-ring cellulose extraction device has considerable benefits in reducing contamination and saving labor in the removal of chemical waste. Although the adapted device was initially designed for radiocarbon analysis, considerable benefits can be conducted to ascertain its applicability to cellulose extraction for other plant tissues and stable isotope analysis.
Conclusions
An adapted device for cellulose extraction was developed at the Laboratory of AMS Dating and the Environment at Nanjing University. It is particularly suitable for radiocarbon analysis of large numbers of tree-ring samples based on the following innovations:
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(a) Independent drainage channels prevent cross-contamination among samples.
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(b) Funnel covers prevent sample contamination from the outside and enhance the efficiency of the NaClO2 treatment step.
The suitability of the adapted device for radiocarbon analysis is confirmed by FTIR and a number of radiocarbon test analyses. Researchers in related disciplines, such as stable isotope analysis, should find the device useful, particularly when there is an increased risk of error due to sample contamination.
Supplementary material
Information about the device design and availability is referred to Text S1. The LWQ tree-ring chronology and the radiocarbon data in Figure 4 are shown in Figure S1 and Table S1.
For supplementary material accompanying this paper visit https://doi.org/10.1017/RDC.2024.83
Acknowledgments
We thank Dr. Irka Hajdas (ETH Zurich, Switzerland) for her valuable comments as well as supplying the wood samples KB and AD1515. We are also grateful to Prof. Tao Su (Chengdu University of Technology, China) for supplying the wood sample NF142. We feel thankful to Prof. Michael Meadows (Nanjing University, China) for his contribution to improve the language. We would like to thank Editor-in-Chief, Prof. Timothy Jull, Associate Editor Prof. Steven Leavitt and two anonymous reviewers for their insightful comments. This research is supported by the National Natural Science Foundation of China (42171155; 42011530119; 42201014), the “GeoX” Interdisciplinary Research Funds for the Frontiers Science Center for Critical Earth Material Cycling, Nanjing University (2023300297) and “Formas - a Swedish Research Council for Sustainable Development” (2022-02833).