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AN INDEPENDENT ASSESSMENT OF UNCERTAINTY FOR RADIOCARBON ANALYSIS WITH THE NEW GENERATION HIGH-YIELD ACCELERATOR MASS SPECTROMETERS

Published online by Cambridge University Press:  03 November 2020

A T Aerts-Bijma*
Affiliation:
Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen, Faculty of Science and Engineering, University of Groningen, Groningen, The Netherlands
D Paul
Affiliation:
Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen, Faculty of Science and Engineering, University of Groningen, Groningen, The Netherlands
M W Dee
Affiliation:
Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen, Faculty of Science and Engineering, University of Groningen, Groningen, The Netherlands
S W L Palstra
Affiliation:
Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen, Faculty of Science and Engineering, University of Groningen, Groningen, The Netherlands
H A J Meijer
Affiliation:
Centre for Isotope Research (CIO), Energy and Sustainability Research Institute Groningen, Faculty of Science and Engineering, University of Groningen, Groningen, The Netherlands
*
*Corresponding author. Email: [email protected].
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Abstract

The radiocarbon (14C) dating facility at the Centre for Isotope Research, University of Groningen went through a major upgrade in 2017 and this included installation of a MICADAS accelerator mass spectrometer (AMS). In the first 18 months, we performed 4000 sample and 3000 reference measurements. A careful evaluation of those measurement results is presented, to characterize the various sources of uncertainty and to ultimately assign, for every sample measurement, a realistic expanded uncertainty. This analysis was performed on the measurements of secondary references and sample duplicates in various phases of their processing steps. The final expanded uncertainty includes both the 14C measurement uncertainties and uncertainties originating from pretreatment steps. Where the 14C measurement uncertainty includes straightforward uncertainties arising from Poisson statistics, background subtraction, calibration on Oxalic Acid II and δ13C correction, the uncertainties originating from pretreatment steps are based on the spread of actual measurement results for secondary references and sample duplicates. We show that the 14C measurement uncertainty requires expansion, depending on the number of processing steps involved prior to a 14C measurement, by a maximum factor of 1.6 at our laboratory. By using these expansion (multiplication) factors, we make our reported uncertainty both more realistic and reliable.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© 2020 by the Arizona Board of Regents on behalf of the University of Arizona

INTRODUCTION

Ever since the first determinations of the age of archeological objects by radiocarbon (14C) in 1949 (Libby et al. Reference Libby, Anderson and Arnold1949; Arnold and Libby Reference Arnold and Libby1949), researchers have striven for easier and more accurate measurements. One of the first breakthroughs was the gas proportional counting technique using CO2, developed and applied by de Vries and Barendsen (Reference De Vries and Barendsen1952, Reference De Vries and Barendsen1954). In the 1980s, accelerator mass spectrometry (AMS) revolutionized the field: faster measurements and the capability to use orders of magnitude less sample made numerous new applications of 14C possible (for example Damon et al. Reference Damon, Donahue, Gore, Hatheway, Jull and Linick1989; Linick et al. Reference Linick, Damon, Donahue and Jull1989; Cook et al. Reference Cook, Wadsworth, Southon and van der Merwe2003; Meijer et al. Reference Meijer, Pertuisot and van der Plicht2006; Rasmussen et al. Reference Rasmussen, van der Plicht, Doudna, Nielsen, Hojrup, Stenby and Pedersen2009; Dee et al. Reference Dee, Wengrow, Shortland, Stevenson, Brock, Girdland Flink and Bronk Ramsey2013). Since then, innovations to the AMS technique have led to incremental but important improvements, mostly concerning the precision and accuracy achievable.

Such innovations are illustrated by the changes in equipment used for 14C measurement at the Centre for Isotope Research (CIO) of the University of Groningen. Proportional counters were in operation from the early 1950s until 2011. From 1994 until 2017 the CIO operated a 3 MV 14C-dedicated accelerator mass spectrometer “tandetron” (AMS) (High Voltage Engineering Europa, the Netherlands) (Gottdang et al. Reference Gottdang, Mous and van der Plicht1995). Since September 2017, a MICADAS (MIni CArbon DAting System, Ionplus, Switzerland) has been in operation (Synal et al. Reference Synal, Stocker and Suter2007; Wacker et al. Reference Wacker, Bonani, Friedrich, Hajdas, Kromer and Němec2010). The MICADAS outperforms the previous AMS in several respects, the most important being increased efficiency of the source (typically 5% compared to ≈1%, resulting in more counts) and besides the measuring on graphite, the additional ability to measure CO2 gas directly.

With the former generation of accelerator mass spectrometers, the number of individual counts acquired from a sample, nearly always determined the 14C measurement uncertainty limitation (a product of the underlying Poisson statistics) and in fact also the final reported uncertainty. All other contributions to the 14C measurement uncertainty (such as the background variability and the 13C correction), were much smaller, which meant in practice that they were both negligible and impossible to determine. However, with the new MICADAS machine this is no longer the case, thanks to the much higher count rates from the source as a result of its increased efficiency. As the Poisson uncertainties have now decreased dramatically, other variables in the measurement contribute to the 14C measurement uncertainty, and still this measurement uncertainty is much lower than before. In addition, contributions to the final reported uncertainty of the various preprocessing and processing steps are no longer negligible either. For a reliable and confident estimate of this final uncertainty, or with a better name the expanded uncertainty (as defined in JGCM 100 2008), we have to take all these contributions into account.

In this paper, we systematically evaluate those other contributions, such that in the end we obtain a reliable expanded uncertainty. With a total of approximately 7000 14C measurements in its first one and a half year of operation, we have gathered abundant information for this detailed uncertainty analysis.

We are, obviously, not the first to publish a manuscript discussing uncertainty analysis of 14C measurements. Stuiver and Polach (Reference Stuiver and Polach1977) did address the issue in their much-cited paper, and (Hedges et al. Reference Hedges, Law, Bronk and Housley1989) describe which sources contribute to the uncertainty. Scott et al. (Reference Scott, Cook and Naysmith2007) give a nice general overview of uncertainty calculation in radiocarbon dating. None of these papers, however, treat the subject in all the details that we show and explain in the present work.

In the coming sections, we demonstrate quantification of uncertainty sources of the various steps in the process from sample to 14C measurement as well as of the actual 14C measurements. To determine and quantify each uncertainty contribution in this whole process, the long-term performance of our secondary references is key. However, as these materials are all pure, homogeneous substances, uncertainty based on their analysis alone might be systematically too small. Therefore, in addition we monitored known-age samples and unknown sample duplicates in various phases of the preparation process. In this way, we could establish whether homogeneity, complicated combustion conditions, or contaminations from the environment (soil-derived compounds, CO2 from laboratory air, contamination through memory effect during combustion) play a significant role.

EXPERIMENTAL SETUP AND METHOD

The preparation of samples for 14C analysis is dependent on the type of material. Archaeological samples (wood, bone, charcoal, seeds) usually need chemical pretreatment, followed by combustion, whereas CO2 in air and in water only needs to be extracted in various ways (for example cryogenically or acidification of alkaline solutions). Still other samples, like carbonates, are treated with acid to convert them to CO2. The CO2 produced, or isolated, is subsequently graphitized (reduced to elemental carbon) and pressed into AMS sample holders (usually called cathodes), with which the actual measurement can be performed.

During all the steps from sample preparation to measurement, utmost care and attention are required to keep the contamination accumulated to a minimum, as the 14C variability will increase along with the amount of contamination. The accumulated contamination contributes to a greater expanded uncertainty.

In this paper, we restrict ourselves to samples with a regular graphite mass (2 mgC: mg of carbon). Gas measurements and small-sized (<0.6 mgC) graphite samples will be dealt with in a forthcoming publication. In the next section, we will briefly describe all the relevant preparation steps, with emphasis on the aspects that influence the 14C signal in the samples, and thus contribute to the final uncertainty.

Processes from Sample to 14C Measurement and Possible Contamination Sources

Sample

A 14C measurement is performed on a small portion of the original sample. Inhomogeneity in the sample material is an issue in providing reliable dates and it is an important source in the final reported uncertainty, and at the same time hard to quantify (only with duplicate or even multiple sampling, as we will show).

Chemical Pretreatment

Sample-specific chemical pretreatment, in other words the best way to collect an isotopically reliable carbon fraction from each type of material, has been and continues to be the subject of many publications, discussions, and round-robin tests between laboratories. The routine chemical pretreatments used in our laboratory were originally summarized by Mook and Streurman (Reference Mook and Streurman1983) and more recently by Dee et al. (Reference Dee, Palstra, Aerts-Bijma, Bleeker, Bruijn de, Ghebru, Jansen, Kuitems, Paul, Richie, Spriensma, Scifo, Zonneveld van, Verstappen-Dumoulin, Wietzes-Land and Meijer2020).

Chemical pretreatment can affect the final isotopic composition of a sample and hence contribute to the expanded uncertainty in several ways, such as through the introduction of contamination with “foreign” carbon during sample handling, or the incomplete removal of contamination that was originally present in the sample.

CO2 Production

Different types of material need different techniques to produce CO2. The techniques currently being used at the CIO are described in Dee et al. (Reference Dee, Palstra, Aerts-Bijma, Bleeker, Bruijn de, Ghebru, Jansen, Kuitems, Paul, Richie, Spriensma, Scifo, Zonneveld van, Verstappen-Dumoulin, Wietzes-Land and Meijer2020). Combustion is performed with solid samples, like bones, seeds, charcoal, and wood, to produce CO2. Carbonates are converted to CO2 in an in-house glasswork manifold. It is described fully in Meijer (Reference Meijer2009). The method of extracting CO2 and measuring 14C in cremated bones samples was first reported in Lanting et al. (Reference Lanting, Aerts-Bijma and van der Plicht2001). CO2 in air is cryogenically extracted or chemically captured in a sodium hydroxide solution.

Possible contributions from the CO2 production to the expanded uncertainty are incomplete combustion, memory from one sample to the next (either in the combustion oven, or in the CO2 trap), contamination from the reagents (oven chemicals, helium, oxygen, and sodium hydroxide) and contamination during sample handling, for example not using ultraclean equipment and instruments. In addition, the exchange of CO2 with CO2 from a previous sample at the glass surface (wall absorption/desorption) and leakages can also cause contamination. The risk of contamination in various steps will lead to added uncertainty in the final result.

Graphitization Systems

The CO2 samples from all different sources will have to be reduced to elemental carbon (commonly referred to as graphitized) for 14C measurements with higher precision. Our graphitization set-up is described in Aerts-Bijma et al. (Reference Aerts-Bijma, Meijer and van der Plicht1997); De Rooij et al. (Reference De Rooij, van der Plicht and Meijer2010); and Dee et al. (Reference Dee, Palstra, Aerts-Bijma, Bleeker, Bruijn de, Ghebru, Jansen, Kuitems, Paul, Richie, Spriensma, Scifo, Zonneveld van, Verstappen-Dumoulin, Wietzes-Land and Meijer2020).

Possible contributions from the graphitization process to the expanded standard uncertainty are exchange with previous CO2 at the glass surface and the presence of contamination in the glasswork manifold or in the iron powder. We store the elemental carbon samples (graphite) produced in the reaction tubes in which they were formed, at room temperature and with Argon added up to atmospheric pressure. These samples are pressed just before measurement, into aluminum sample holders with an automated home-built press at approximately 1 MPa (Aerts-Bijma et al. Reference Aerts-Bijma, Meijer and van der Plicht1997).

During the graphitization process sample-to-sample contamination can also occur if the reactors are not cleaned sufficiently. Furthermore, experience has taught us that the pressed graphite-iron mixture is susceptible to carbon uptake from air, and even while at vacuum in the ionization chamber (Paul et al. Reference Paul, Been, Aerts-Bijma and Meijer2016).

14C Measurements

We performed all the relevant 14C measurements on our MICADAS. In our routine operation, a regular batch consists of five Oxalic Acid II references, necessary for the calibration of the batch (the tuning of the machine also requires one additional Oxalic Acid II reference), four sample-specific background references (14C-free material, resembling the sample materials as much as possible), two secondary references and 28 samples (unknowns). Approximately forty minutes of measurement time per sample yields typically 750,000 14C counts for the Oxalic Acid II calibration material.

Input Data for the Uncertainty Analysis

As part of our general quality control and assurance procedures, (secondary) reference materials and background materials are processed alongside the samples, and these materials are selected to resemble the various sample types as closely as possible. The results for these various materials are of course a valuable source of information for our uncertainty assessment. In addition, sample duplicates are also frequently analyzed.

Samples Analyzed as Duplicates

In our routine operation, we regularly prepare sample duplicates. The sample is divided into two portions and then the chemical pretreatment, the CO2 extraction, the graphitization and the 14C measurement are performed on different days, as if they were two different unknowns. Thus, everything in the whole process is performed as independently as possible. These full duplicates yield a wealth of information about the expanded uncertainty. As they are pretreated and measured in different batches, their uncertainties are to a large extent independent.

To discriminate these “full” duplicates from other partial duplicates (see below) we call them pretreatment duplicates. In order to enhance the readability of this paper we divided the different kinds of duplicate also into categories from 1 to 4. These pretreatment duplicates are from now on called category (cat.) 4 duplicates, as all four steps from chemical pretreatment, CO2 preparation, graphitization and 14C measurement are different for these duplicates.

A special cat. 4 duplicate is the VIRI F Horse bone. In some series of bones, which have to be pretreated, leftover material from the VIRI intercomparison (Scott et al. Reference Scott, Cook and Naysmith2010), the VIRI F horse bone, is pretreated as well. This sample is considered a known-age cat. 4 duplicate, because many 14C laboratories have dated this material.

CO2 preparation duplicates are samples divided into different portions after the chemical pretreatment, which are then separately handled further, so these duplicates share the chemical pretreatment, but not the following three steps (CO2 preparation, graphitization, and 14C measurement). These duplicates are thus cat. 3 duplicates.

For the graphitization duplicates, CO2 from one CO2 preparation process is divided into two or three portions, and each portion is separately graphitized, making them cat. 2 duplicates.

A cat. 1 14C measurement duplicate means that the graphite formed is split into two portions (so all parts of the process before are common). Such duplicates rarely occur.

All duplicates contribute to a better understanding of the contributions of the different preparation steps to the expanded uncertainty. The different duplicates are further clarified in Figure 1.

Figure 1 A schematic overview of different categories of duplicates. A higher category number refers to a higher number of independent steps in the total process.

Background Materials

Several sample-specific 14C-free (“dead”) materials are available in our laboratory for identification of the “background”; that is, the modern carbon contamination, accumulated during the process from chemical pretreatment until 14C measurement. Background wood (“bgw”, Kitzbuhel I, Tirol, Austria) and background collagen (“bgc”, Latton Quary LQH 12) (Cook et al. Reference Cook, Higham, Naysmith, Brock, Freeman and Bayliss2012) have been selected for measuring the combustion background. Both materials are known to be far older than the detection limit of 14C. The background material for carbonates (shells and cremated calcined bones) is named GS-35 (grained marble from a stonemasonry in Groningen). The graphitization background gas is Rommenhöller CO2, a fossil gas of geological origin (Linde gases).

Secondary References

Besides the sample duplicates and background materials, several secondary references are combusted and graphitized together with the samples and treated as “samples of known 14C content”, to monitor the total process. As the secondary references are all pure substances, they form the basis for determining and quantifying each uncertainty contribution in the whole process. These secondary references are IAEA-C8, IAEA-C7 (oxalic acid, Le Clercq et al. Reference Le Clercq, van der Plicht and Groning1998), and GS-51 (Groningen Standard, cane sugar). For these references, extensive measurement records over more than 20 years have been compiled. This present study is, however, based on data measured with the MICADAS only.

These secondary reference materials are treated in two separate ways. The first involves them being combusted in large quantities, yielding five to ten liters of pure CO2 collected in small cylinders (called “bulk”). Thanks to the large quantities of gas, we can use them to prepare many samples over the years, which then do not contain combustion-induced variability (in analogy to the different types of sample duplicates, we can call them cat. 2 secondary references). Therefore, these cylinder gas analyses can monitor the variability induced by the graphitization process and the subsequent measurement alone. However, we also use these secondary reference materials as individual samples, where they are combusted in small amounts (2 mgC) and serve as combustion references (cat. 3 secondary references).

CALCULATION OF OUR BEST ESTIMATE FOR THE 14C MEASUREMENT UNCERTAINTY

The 14C content of a sample is expressed as Fraction Modern (Reimer et al. Reference Reimer, Brown and Reimer2004). Because the original batch of the calibration material, Oxalic Acid I is exhausted, Oxalic Acid II is the international calibration reference (cal) with assigned values for F 14Cn $ \equiv $ 134.066% and δ13CVPDB $\equiv $ –17.8‰.

Every measured sample is calibrated using:

(1) $${F^{14}}{C_n} = {\bf{134}}.{\bf{066}}*{{{{{(^{14}}C{/^{12}}C)}_{sample}} - {{{(^{14}}C{/^{12}}C)}_{bg}}} \over {{{{(^{14}}C{/^{12}}C)}_{cal}} - {{{(^{14}}C{/^{12}}C)}_{bg}}}}*{{{{\left( {{{0.975} \over {1 + {\delta ^{13}}{C_{sample}}}}} \right)}^2}} \over {{{\left( {{{0.975} \over {1 + {\delta ^{13}}{C_{cal}}}}} \right)}^2}}}$$

The subscript sample, bg and cal refers to sample, background and Oxalic Acid II respectively; $\delta {}^{13}{C_{sample}}$ is the value measured by the MICADAS; its $\delta {}^{13}C$ scale is calibrated using the assigned Oxalic Acid II value of δ13CVPDB = –17.8‰.

The uncertainty in a 14C measurement is then derived from the partial derivatives of F 14Cn with respect to each of the variables and is called dF 14Cn.

Every measured quantity in Eq. (1) has its own uncertainty. The uncertainty in the (14C/12C)sample is the statistical uncertainty (Poisson counting statistics). The uncertainty in (14C/12C)cal, is the uncertainty in the mean of the calibration reference (Oxalic Acid II). The uncertainty in the mean value for the calibration material, and not the standard deviation, is the right choice, as this uncertainty in the mean is relevant for the accuracy of the calibrated scale. Instead of dealing with this uncertainty on a per batch basis, we use the average of the uncertainty in the mean over a considerable number of batches (over the preceding 4 months, typically, under normal circumstances, 50 batches) to avoid the statistical fluctuations in our estimate of the 14C measurement uncertainty. In the first phase of operation, we did not do that, which led to an underestimation of this uncertainty (see Appendix 1). The relevant uncertainty in the next variable, (14C/12C)bg, is the spread (standard deviation) in the background, also over the preceding 4 months. This spread is relevant for the variability in the individual backgrounds and thus also for the samples. The 4-monthly values are closely monitored for sudden or gradual changes on a monthly basis. The uncertainty in the variable δ13Csample (the δ13C from the sample measured by AMS) is the uncertainty derived from the raw measurements. The standard error of the mean of the independent raw measurements (in normal routine, 8 independent measurements) for each graphite sample, is calculated and serves as the uncertainty in δ13Csample. For the last variable, δ13Ccal, we again need the uncertainty in the mean, and the typical value is ± 0.1‰ (which makes this uncertainty source negligible in practice).

The quadratic sum of the above-mentioned components times their partial derivatives results in the 14C measurement uncertainty (dF 14Cn ).

(2) $$\displaylines{ d{F^{14}}{C_n} = \left\{ {{{\left( {{{{\sigma _{poisson}}} \over {{{{(^{14}}C{/^{12}}C)}_{sample}} - {{{(^{14}}C{/^{12}}C)}_{bg}}}}} \right)}^2} + {{\left( {{{{{\bar \sigma }_{\left( {OxII,4\;months} \right)}}} \over {{{{(^{14}}C{/^{12}}C)}_{cal}} - {{{(^{14}}C{/^{12}}C)}_{bg}}}}} \right)}^2}} \right. \cr + {\left( {{{{\sigma _{\left( {bg,4\;months} \right)}}.({{{(^{14}}C{/^{12}}C)}_{sample}} - {{{(^{14}}C{/^{12}}C)}_{cal}})} \over {\left( {{{{(^{14}}C{/^{12}}C)}_{sample}} - {{{(^{14}}C{/^{12}}C)}_{bg}}} \right).\left( {{{{(^{14}}C{/^{12}}C)}_{cal}} - {{{(^{14}}C{/^{12}}C)}_{bg}}} \right)}}} \right)^2} \cr {\left. { + {{\left( {{{2.{\sigma _{{\delta ^{13}}{C_{sample}}}}} \over {1 + {\delta ^{13}}{C_{sample}}}}} \right)}^2} + {{\left( {{{2.{\sigma _{{\delta ^{13}}{C_{cal}}}}} \over {1 + {\delta ^{13}}{C_{cal}}}}} \right)}^2}} \right\}^{0.5}}*{F^{14}}{C_n} \cr} $$

This calculation, using the partial derivatives-approach, is a classical, linearized approximation of the real value of the 14C measurement uncertainty. Correlations between the uncertainties in the different variables are ignored. We compared the outcome of this calculation to a Monte Carlo approach using the NIST Uncertainty Machine (NIST 2019). This is a web-based application for evaluating the measurement uncertainty associated with an output quantity defined by a measurement model of the form y = f(x0,…,xn) (Lafarge and Possolo Reference Lafarge and Possolo2015). The Uncertainty Machine provides a numerically calculated probabilistic estimate of the uncertainty. The differences between the linearized approximation via the partial derivatives and the calculation via Monte Carlo turned out to be negligible (this is basically caused by the small size of the uncertainties relative to the values, making the linear approximation a very good one). Therefore, we preferred the ease of using the analytical method of the partial derivatives.

Researchers often report uncertainties in their results that do not contain all relevant sources of uncertainty. Therefore, their uncertainty estimates are usually too low. This is mostly caused by the fact that some of the uncertainty sources are very hard to estimate properly. This approach holds also for the analysis software from the MICADAS for data reduction, called BATS (Wacker et al. Reference Wacker, Christl and Synal2010a). This data analysis package is provided with the MICADAS, and it is a very powerful and versatile tool, so most groups operating a MICADAS use this package, including us. The 14C measurement uncertainty the BATS package provides is based on the Poisson statistics, the so-called molecular correction (13C+ resulting from broken-up molecules), and the scatter of the blank samples. As the true 14C measurement uncertainty is underestimated by this combination (and the programmers realize that, of course), in BATS an additional, arbitrary size error can be added by the user. This approach is in line with the “dark uncertainty” philosophy (see below). However, we prefer to explicitly account for all the uncertainty contributions as explained above, such that we produce the most reliable estimate for the expanded uncertainty in our 14C measurement results.

For our approach, it is of course essential to be able to check if the 14C measurement uncertainty (dF 14Cn) that we calculate is indeed a good measure of that uncertainty. Therefore, we monitor the relationship between those calculated uncertainties and the realized uncertainties, where the latter are determined from the spread in (long) time series of various reference materials. Ideally, their ratio should be around 1.

This approach dates back to Birge (Reference Birge1932). The 14C measurement uncertainties, as we calculate them along with the measurands, are called “internal errors”, whereas the uncertainties observable from the spread in measurands, are called “external errors”. The internal errors are then the expectation; the external errors are the realization of the uncertainty (Birge Reference Birge1932) calls these the “prediction” and “answer to the prediction”, respectively). Their ratio is the reduced $\chi _{red}^2$ (“chi-squared”). If the predicted internal error is correct, the value of $\chi _{red}^2$ will be 1 within a certain statistical variability. However, if certain sources of uncertainty have not been accounted for in the internal error, $\chi _{red}^2$ will be larger than 1. This is often the case in interlaboratory intercomparisons. The apparent extra source of uncertainty is called “dark uncertainty,” and there are different approaches for its calculation. The option in BATS to add extra uncertainty is in fact a possibility to account for this dark uncertainty. The “error multiplier” that has been used in the radiocarbon world can be interpreted along the same lines (Scott et al. Reference Scott, Cook and Naysmith2007).

Birge’s (Reference Birge1932) original work has been taken up and extended by statisticians since then, for recent developments see for example (Rukhin Reference Rukhin2009, Koepke et al. Reference Koepke, Lafarge, Possolo and Toman2017, Merkatas et al. Reference Merkatas, Toman, Possolo and Schlamminger2019). For the sake of completeness, we give the expressions for the necessary quantities (weighted means, internal and external errors) in the Appendix 2.

In our attempt to account for all sources of uncertainty, we strive for the absence of “dark uncertainty”. Nevertheless, it is very possible, even likely, that such uncertainty still exists, as we cannot account quantitatively for variability in the chemical preparation and combustion, even though some of this variability is contained in the standard deviation of the background material, and in the calibration error.

We have two sources available with which we can check the completeness of our uncertainties. The secondary references provide long records, the spreads of which deliver the external errors. Sample duplicates on the other hand provide only two independent 14C measurements, F 14Cn 1 and F 14Cn 2, each with their individual 14C measurement uncertainty dF 14Cn 1 and dF 14Cn 2. The quadratic sum of the individual measurement uncertainties gives the uncertainty dF 14Cn(duplicates), the difference between those two measurements gives ${\Delta _{duplicates}}$ .

The ratio between ${\Delta _{duplicates}}$ and dF 14Cn(duplicates)

(3) $${f_\sigma } = {{{\Delta _{duplicates}}} \over {d{F^{14}}{C_{{n_{duplicates}}}}}}$$

is a value that should scale according to Gaussian expectations: for a large number of duplicates the average value of ƒσ should be ≈0, and the σ(ƒσ) should be ≈ 1, and thus in 68% of the cases, the value should be between –1 and 1. If the standard deviation of this distribution of ƒσ, is in general too large, this would imply that the calculated 14C measurement uncertainties are too low, and some “dark uncertainty” is present. This ƒσ, is calculated for all duplicates, and the spread of this distribution, σ(ƒσ) is a measure for the expanded uncertainty for each of the various types of duplicates.

RESULTS FOR OUR UNCERTAINTIES

For our previous HV AMS, the calculated uncertainty according to the propagation of uncertainties from Eq. (1) has proven to be an adequate estimate for the expanded uncertainty from all different sources in the total process from chemical pretreatment until measurement. This was no surprise, however, as all contributions that could not be accounted for (chemical pretreatment variability) were overshadowed by the Poisson statistics contribution to the calculated 14C measurement uncertainty.

For the MICADAS, however, this Poisson contribution is much smaller than for the HV AMS, due to the increased overall efficiency. When this pure measurement uncertainty decreases, further investigation of the other contributions to the expanded uncertainty is possible, and in fact necessary.

The expanded uncertainty in the final result is composed of four major contributions. These contributions, consecutively from latest to earliest in the sample handling process, are as follows: the contribution from the actual 14C measurement (Eq. 1), from the graphitization, from the CO2 preparation and from the chemical pretreatment. The first contribution, the 14C measurement uncertainty (dF 14Cn, Eq. 2) is the minimum uncertainty and is present in all the 14C determinations. As this study is restricted to measurements on graphite cathodes, the extra uncertainty of the graphitization step, the second contribution, is automatically also incorporated in all measurements from background materials, secondary references (cat. 2) and sample duplicates (cat. 2). The third contribution from the CO2 extraction is visible in the combustion background materials wood (bgw) and collagen (bgc), in the individually combusted secondary references (cat. 3), and in the CO2 preparation sample duplicates (cat. 3, same chemical pretreatment, three different following steps). Finally, the fourth contribution, the uncertainty added in the chemical pretreatment, can be investigated with the pretreatment sample duplicates (cat. 4, where everything in the total process is different, see Figure 1). These four major contributions to the expanded uncertainty will be treated in the following texts.

As mentioned before, the first major contribution, the uncertainty in a 14C measurement, is derived from the partial derivatives of F 14Cn with respect to each of the variables (dF 14Cn ). Figure 2 shows the typical contribution of the uncertainty in each variable from a representative measurement batch to this calculated 14C measurement uncertainty. The quadratic sum of those components results in the 14C measurement uncertainty (line f, black).

Figure 2 14C measurement uncertainty contributions (slightly smoothed) due to the partial derivatives of the variables in Eq. (1) for a representative measurement batch. The quadratic sum of those components results in the 14C measurement uncertainty (dF14Cn, line f, black). The uncertainty in (14C/12C)sample is the statistical uncertainty (Poisson counting statistics) (line a, grey). The Poisson counting statistics is still the largest contribution to dF14Cn. The uncertainty in (14C/12C)cal (line b, magenta, calibration material is Oxalic Acid II) has practically no influence on samples with a low (14C/12C)sample, but the contribution increases for samples with a higher (14C/12C)sample. For samples with a low (14C/12C)sample, the uncertainty is dominated by the spread in (14C/12C)bg (line c, green). Line d (red) and line e (blue) are the contribution due to the partial derivatives of, respectively, δ13Csample (measured by MICADAS) and δ13Ccal (Oxalic Acid II). The latter one is practically negligible. (Please see electronic version for color figures.)

The uncertainty in the (14C/12C)sample is the statistical uncertainty (Poisson counting statistics) (line a, gray). The Poisson counting statistics is still the largest contribution to dF 14Cn. For low 14C activities, the uncertainty is dominated by the spread in the background materials (line c, green).

This calculated 14C measurement uncertainty needs to be put to the test. We expect it to be a valid uncertainty for pure gas samples, but for samples requiring pretreatment some extra “dark” uncertainty probably plays a role.

The first thorough check on our calculated uncertainties is given by the long-term spread of our secondary references. Table 1 provides the summary statistics for those secondary references. The references with a graphitization step only (cat. 2), are Rommenhöller (background), IAEA-C8 (bulk), IAEA-C7 (bulk), GS-51 (bulk), and Oxalic Acid II (bulk). Table 1 contains both the external and internal standard deviations (for the calculation equations see Appendix 2), and also $\chi _{red}^2$ . The last column of Table 1 gives the probability that the difference between both standard deviations is significant (based on the statistics of the $\chi _{red}^2$ distribution).

Table 1 Long-term data of cat. 2 and cat. 3 secondary reference materials, from 1-7-2018 until 1-4-2019. N represents the number of measurements. The measured Fraction Modern F14Cn is an averaged result weighted by the individual uncertainties (dF14Cn). The calculated 14C measurement uncertainty dF14Cn is averaged. The squared external standard deviation (σext) divided by the squared dF14Cn leads to the reduced Chi square ( $\chi _{red}^2$ , for equations see Appendix 2). Cat. 2 references show a $\chi _{red}^2$ smaller than 1, implicating that dF 14Cn is slightly overestimated. Cat. 3 references do have a $\chi _{red}^2$ larger than 1, implicating that the combustion process contributes to a higher spread in the data. The last column gives the probability that the difference between both standard deviations is significant (based on the statistics of the $\chi _{red}^2$ distribution).

* When the significant digit is between 1 and 4 an extra digit is shown.

** Recently a memory problem in the bulk combustion line was discovered to which IAEA-C7 and IAEA-C8 were vulnerable. This is the reason why the measured 14C values of those cat. 2 secondary references are slightly different from the assigned values. For the purpose of this paper this has no further consequences.

*** For every batch the mean value of the Oxalic Acid II references is calibrated to become the assigned value of 134.066%. Therefore, its overall spread is not representative.

For four of the five graphitization references (cat. 2), $\chi _{red}^2$ is <1, implying (with on average ≈ 85% probability) that the realized, external measurement uncertainty is somewhat smaller than the calculated, (internal) uncertainty. In other words, our calculated uncertainty (dF 14Cn) might be slightly overestimated.

The contribution from combustion is quantified by the secondary references that are individually combusted (cat. 3). Those are also listed in Table 1, and they have $\chi _{red}^2$ values somewhat larger than 1, indicating that the calculated dF 14Cn is a slight underestimation, and that there is some “dark” uncertainty present. Oxalic acid has a $\chi _{red}^2$ much smaller than 1. However, the spread of the Oxalic Acid II is not representative, because this is used as calibration material and therefore for every batch the mean value is calibrated to become the assigned value of 134.066%.

The background wood (bgw) and background collagen (bgc) samples were chemically pretreated in large quantities, but individually combusted. Therefore, this pretreatment cannot influence their spread and those background references can be used as CO2 preparation duplicates (cat. 3). For bgw, we indeed get a result comparable to the other cat. 3 materials. For background collagen, however, we observe the highest $\chi _{red}^2$ of all materials: 1.7. The reason for this high, and significant value is not well understood and more data are needed as this value is calculated from only 12 data points.

Uncertainty estimates leads to maximum ages measurable in a system. The standard deviation of background collagen implies that the minimum F 14Cn distinguishable from background values, is two times 0.05%, so 0.1% on graphite samples (Stuiver and Polach 1977; van der Plicht and Hogg Reference van der Plicht and Hogg2006). This corresponds to 55,000 years BP. However, as the absolute F 14Cn values for the background wood and the background collagen are 0.23–0.25%, even though these materials are known to be of infinite age, we never report ages older than corresponding to these activities (48,000 years BP) (van der Plicht and Palstra Reference van der Plicht and Palstra2016).

Figure 3 visualizes the average results over the first full year of measurements from the secondary references. The calculated 14C measurement uncertainty (from Eq. 2, dF 14Cn, averaged data of last one and a half year), is shown in black again (line a). The long-term spread of our secondary CO2 references (cat. 2), contains contributions from the actual 14C measurement and the graphitization, but no further variability due to individual combustion, and dF 14Cn is expected to be a good estimate of their uncertainty (see above). The standard deviation of the cat. 2 references is shown in blue (line b). The realized spread in the long-term measurements is lower than line a, and, for higher F 14Cn values, even approaching the Poisson statistics uncertainty (which is shown as the gray line (a) in Figure 2).

Figure 3 Long-term (≈ 1 year) standard deviation of cat. 2 (b) and cat. 3 (c) secondary references versus the Fraction Modern (14C content). For comparison, the calculated 14C measurement uncertainty is shown (averaged dF 14Cn for last one and a half year) (a, black solid line). b. Spread of category (cat.) 2 secondary references (blue dashed line). These secondary references are Rommenhöller gas, IAEA-C8, IAEA-C7 and GS-51 (Groningen Standard, cane sugar). c. Spread of cat. 3 secondary references (red dotted line). These secondary references are background wood, IAEA-C8, IAEA-C7 and GS-51 (Groningen Standard, cane sugar).

Figure 4 References measured with a very long 14C measurement time in order to determine the optimal measurement time for a sample. The standard deviation from seven Oxalic Acid II references (a) and eight IAEA-C8 (b) (all cat. 2, blue) versus a measurement time of more than 10,000 seconds (3.5 × 106 accumulated counts for Oxalic Acid II). The calculated 14C measurement uncertainty (dF 14Cn) is displayed in black. The shaded area around the standard deviation (blue) and dF 14Cn (black) is the confidence band (1σ, 68%). The pink line shows the routine measurement time of 2400 seconds.

The standard deviation of cat. 3 secondary references is shown by line c (red) in Figure 3. Six combustion references from Table 1 (cat. 3, not oxalic acid) are used to construct this line. The displayed spread at zero percent F 14Cn, is the spread of bgw. In practice there are many more bgw than bgc measurements, therefore bgc measurements are disregarded. The GS-35 measurements are disregarded in Figure 3 as well, as this material is a carbonate and therefore not combusted.

The differences between the external standard deviation of the secondary references, that have only a graphitization step (cat. 2), and the secondary references, that have both a graphitization and a combustion step (cat. 3), are significant (line b and c in Figure 3) and amount to ≈ 30%. As expected, the combustion process contributes to a greater spread in the data. $\chi _{red}^2$ is the ratio of the squared external standard deviation and the squared 14C measurement uncertainty (dF 14Cn 2 ). The average $\chi _{red}^2$ for cat. 3 references is 1.3. To represent the uncertainty in these combusted references, our calculated (internal errors) dF 14Cn (line a) need to be multiplied by ≈ 1.15 (which is the square root of the average $\chi _{red}^2$ of the appropriate samples in Table 1).

The next source of information about contributions to the expanded uncertainty comes from sample duplicates in various phases of the process (see Figure 1). Data from air samples from our atmospheric station at Lutjewad (the station is described in Van der Laan-Luijkx et al. Reference van der Laan-Luijkx, Karstens, Steinbach, Gerbig, Sirignano, Neubert, van der Laan and Meijer2010) provide information about quantification of the graphitization uncertainty (cat. 2 duplicates). CO2 is dissolved in an alkaline solution during the sampling of atmospheric air and for 14C measurement, this CO2 is released again by using acid. The released CO2 fraction is divided into three equal portions, which makes these samples graphitization triplicates. The average spread in these triplicates is 0.18%, which compares favorably to the calculated 14C measurement uncertainty of 0.16%.

The unknown sample CO2 preparation duplicates (cat. 3) provide information about the third major contribution to the expanded uncertainty, the contribution from combustion. For the CO2 preparation duplicates of unknown samples, the standard deviation of the distribution of ƒσ, σ(ƒσ), is on average 1.4, meaning the dF 14Cn had to be increased by 40% to match the spread (See Table 2). As mentioned before, when comparing secondary references from cat. 3 (c from graph 3) dF 14Cn should be enlarged by approximately 15%. We attribute this large difference between sample duplicates and secondary references to inhomogeneity in the samples and connected to this inhomogeneity the chance of success in homogeneously removing exogenous contaminants in the samples. It illustrates that the CO2 preparation from inhomogeneous samples will contribute much more to the expanded uncertainty than the CO2 preparation from pure materials. If unaccounted for, this would lead to “dark uncertainty” in our results, which would come to light for example in intercomparisons. Our attempt to quantify this extra uncertainty is thus by randomly re-measuring samples on a regular basis.

Table 2 Comparison of the observed differences of two 14C measurements for various duplicates from unknown samples, with the expected uncertainty. (The expected uncertainty is the quadratic sum of the individual measurement uncertainties.) The spread of the ratio ƒσ, (Eq. 3), σ(ƒσ), indicates in how far the observed uncertainty deviates from our calculated one. If σ(ƒσ) is larger than 1, the calculated 14C measurement uncertainties (dF14Cn) are too low, and some “dark uncertainty” is present. For random solid materials, like bone and charcoal and wood samples, σ(ƒσ) is on average 1.6, meaning dF14Cn had to be increased by 60% to match the spread. dF14Cn from more homogeneous materials like ${\rm{\alpha }}$ -cellulose had to increased by 40% to match the spread. For a cat. 2 duplicate this increase is 10%.

All described secondary references do not require a chemical pretreatment, because the references are pure materials. Therefore, the fourth major contribution to the expanded uncertainty can only be quantified by sample pretreatment duplicates (cat. 4) (among which the known sample VIRI F, horse bone). Monitoring the pretreatment duplicates (cat. 4) revealed that the expanded uncertainty for unknown random samples (bones, charcoal, wood) is dF 14Cn, increased by a factor of 1.6 (see Table 2). Splitting the pretreatment duplicates into different materials would be desirable but is impeded by the low number of measurements.

Interestingly, all the VIRI F Horse bone pretreatment duplicates (cat. 4) (paired in two) show a smaller σ(ƒσ) of 1.2, suggesting a lower expanded uncertainty. The VIRI F measurements were paired in duplicates to allow us a direct comparison with duplicates we do randomly on unknown samples. Since a data set of nine pairs is small, we also calculate ƒσ by comparing the standard deviation of all VIRI F measurements with the average calculated dF 14Cn. The result is similar to the paired method (as it should). The reason for this smaller σ(ƒσ) is unknown; maybe this bone sample was less contaminated compared to other samples. The sample duplicates from tree-rings where the fraction α-cellulose was extracted (cat. 4), also showed a smaller σ(ƒσ) of 1.4 compared to various other unknown samples (of which σ(ƒσ) is 1.6 as mentioned earlier). The reason for this is probably that during pretreatment most of the contaminants and other naturally occurring compounds were removed, as the extracted α-cellulose is a more uniform biopolymer. As σ(ƒσ) of cat. 4 from more homogeneous materials hardly differs with the σ(ƒσ) of cat. 3 duplicates, it indicates that the additional sample handling from the chemical pretreatment does not contribute to the increase of the expanded uncertainty. The increase of σ(ƒσ) for cat. 4 pretreatment duplicate samples of 1.6 is, therefore probably merely due to inhomogeneity of the sample material and, perhaps related to that, the variability of the success rate of the chemical pretreatment. The expanded uncertainties for various processes and samples, using the calculated dF 14Cn and the σ(ƒσ) factors are shown in Table 3. The use of σ(ƒσ) factors is in fact an error multiplier approach (Scott et al. Reference Scott, Cook and Naysmith2007). Of course, it would be preferable to also quantify and include all other uncertainty sources, but as these are next to impossible to determine, this pragmatic solution is acceptable. Still, multiplication factors should be as close to unity as possible, otherwise the uncertainty analysis apparently fails to include the major sources of uncertainty.

Table 3 Minimum final reported uncertainties (expanded uncertainties) for various processes and samples, using the calculated dF14Cn and the multiplication factors from Table 2. The results are shown in Fraction Modern (%) and in 14C years (years BP). These uncertainties are valid for single measurements. The last column shows samples, which undergo the full pretreatment (chemical preparation, combustion, graphitization and 14C measurement). Columns to the left represent fewer steps in the sample handling process. As an example, when a bone sample is pretreated, combusted, graphitized, has its radiocarbon activity measured, and the date is calculated to be 1800 years BP, the minimum achievable uncertainty is 23 14C years BP. On the other hand, a contemporary atmospheric CO2 sample (F14Cn = 100%) is reported with an uncertainty of 0.18%, which is the equivalent of 14 14C years BP.

* α-cellulose pretreatment is an exception (see Table 2), for which we can use the data in the 4th column.

During the early phases of measuring with the MICADAS, a realistic determination of the expanded uncertainty was not possible due to limited available data and so to encompass uncertainties arising from various sources, we used a provisional multiplication factor of 1.5 for the 14C measurement uncertainty for every sample. Our present assessment showed that this “educated guess” was quite appropriate.

Attempts to Reduce the Expanded Uncertainty

The main goal of this study was to determine the expanded uncertainty of a 14C measurement and to quantify the contributions to this uncertainty. As an extension of the project while performing and analyzing all the measurements that were described in this paper, we also tried to reduce this expanded uncertainty. One obvious possibility is to improve the counting statistics by increasing the measurement time. The Poisson uncertainty will of course gradually decrease by collecting more counts during a longer measurement time, but at the same time other uncertainty sources in the measurement (calibration stability, 13C signal stability) might increase, and after a certain point will outbalance the Poisson gain.

We tried this out by performing an experiment where we measured a batch with a net measurement time exceeding 10,000 seconds per sample. The batch contained (among others) seven Oxalic Acid II references and eight IAEA-C8 references, all produced from CO2 from their respective bulk materials (thus cat. 2).

In this experiment with very long measurement times, we calculated the measurement standard deviation after 1700, 2300, 3500 until 10,000 seconds measurement time per sample. These results provided important insights into the optimum measurement time, but as the same cathodes were analyzed for the comparison, the data are not independent of each other.

The main conclusion is that in contrast to the Poisson uncertainty from individual references that obviously decreased with measurement time, the observed spread in the Oxalic Acid II references (a) did not significantly improve for measurement times over 4000 seconds. The random contribution to the spread due to the different graphitization reactions, causing spread in the 13C stability is a plausible reason. In all cases, a longer measurement time obviously leads to a decrease in (the calculated) dF 14Cn. On the other hand, the standard deviation of IAEA-C8 (b) still does decrease with time. However, the gain in years from 2400 sec measurement time (magenta line) to 4000 sec is only 5 years (BP) for IAEA-C8 (for Oxalic Acid II only 2 years BP). This improvement is hardly ever worth the investment of doubling of the measurement time. Therefore, our routine measurement time of 2400 seconds is optimally chosen.

We conducted several independent batches with various measurement times as well. The calculated 14C measurement uncertainty (dF 14Cn) for those independent measurements also revealed no significant improvement after 2400 seconds. All measurements in this paper were conducted at 2400 seconds.

Table 1 (comparison of secondary references from cat. 2 and 3) and Figure 3 (line b and c) showed the influence from the combustion process to the expanded uncertainty. A possible, although unlikely, cause might be a memory effect from one combustion to another in the combustion set up and cryogenic collection system. Experiments with blank (background material) combustions after Oxalic Acid II references did not show a significant memory effect in the combustion set up. Still, to be absolutely sure, we recently started to combust an empty tin capsule before every individual combustion to see whether we could more definitively understand and even determine the size of this potential memory effect. The extra oxygen pulse should reduce possible leftover material that was not completely converted into CO2. Further data collection is needed to determine if the additional blank combustions improve the final reported uncertainty. The other contamination source could be the cryogenic collection system. This system is more than 20 years old, and the constant freezing and heating of the glass may have introduced micro cracks that function as active adsorption spots for the exchange of CO2 and thus increase the memory from sample to sample. Regular refreshing of the glass system may reduce this contamination and hence, the contribution to the expanded uncertainty. The replacement of all the glass components of the cryogenic collection system will be a major operation; therefore, further research will be needed to see, whether this will indeed reduce the contribution to the expanded uncertainty.

The contribution from chemical pretreatment is visible in Table 2 for cat. 4 sample duplicates, but also for cat. 3 sample duplicates, where the multiplication factor is considerably larger than for pure substances (Table 1, ~1.15). A large part is apparently due to the inhomogeneity or intractable contamination of the sample and therefore it is not easily possible to reduce this contribution. Obviously, running duplicate (or multiple) samples would help to some extent, as inhomogeneities and the varying success of removing contaminants would average out. However, for the vast majority of samples this is not an option due to the increased costs involved (and sometimes the need for more material). An experiment on the automation of pretreatment, as a means of standardizing the process, and reducing random errors will be investigated in the near future.

DISCUSSIONS AND RECOMMENDATIONS

The new generation of high-yield accelerator mass spectrometers delivers very small measurement uncertainties, due to higher count rates. The reported uncertainty in the final outcome, however, must be the expanded uncertainty, a firm measure of the spread that can be expected in case of multiple analyses of the same material, by one or more laboratories.

When performing sample duplicates in the same laboratory, and monitoring the spread in the data, it is already clearly apparent that the 14C measurement uncertainty is too small to serve as the reported uncertainty. Therefore, in the field of 14C measurements it is very common to use a multiplying factor of the 14C measurement error for the uncertainty in the final outcome (Scott et al. Reference Scott, Cook and Naysmith2007). This is in line with the “dark uncertainty” concept, well known from intercomparison of results between different laboratories (Koepke et al. Reference Koepke, Lafarge, Possolo and Toman2017; Merkatas et al. Reference Merkatas, Toman, Possolo and Schlamminger2019).

However, we deemed it necessary to achieve a better and more thorough understanding of the build-up of uncertainty in the whole chain from chemical pretreatment to the final measurement, such that we can report a reliable expanded uncertainty in our publications, and to our customers. To report such a reliable uncertainty is obviously very important for participation in round robin tests and other intercomparisons.

For laboratories in the field of 14C, we recommend measuring full duplicates on all the kinds of samples that are normally measured; noting, of course, that most laboratories already have such protocols implemented. A nice example of such a practice was described in a recently published work by Sookdeo et al. (Reference Sookdeo, Kromer, Büntgen, Friedrich, Friedrich and Helle2019), where in addition to process duplicates, the authors also emphasize including process backgrounds for high-quality measurements. The results of the measured duplicates give a very good insight in the quality of the measurements. This protocol of measuring duplicates is especially useful when participating in intercomparisons. In the optimal case, where all participants estimate their expanded uncertainty well, the “dark uncertainty” would be minimal. Weighting the data for averaging with the expanded uncertainty would then make sense. Therefore, we recommend that in future intercomparisons a report should be added on the basis used for the stated uncertainty.

For quality improvement and thus reduced expanded uncertainty in the final outcome, it is recommended to measure secondary references in the various steps of the process from CO2 preparation up to the actual 14C measurement. This gives insights into where improvements in quality can be achieved and which steps are limiting the further reduction of the expanded uncertainty. Using homogeneous materials has the advantage that the effects are clear. On the other hand, one should not claim the results of such homogeneous secondary references as valid for the real samples, as our work has shown that “real samples” show larger spread, most likely due to variability in the success of removing contamination in the pretreatment process.

CONCLUSIONS

After detailed uncertainty analysis using measurements from secondary references and sample duplicates during the first year and a half of MICADAS operation in Groningen, we are confident that we can report an expanded uncertainty that is representative of the real uncertainty in our final 14C measurements. This expanded uncertainty incorporates contributions from the chemical pretreatment, the CO2 preparation, the graphitization and the 14C measurement. We systematically evaluate the contributions to the 14C measurement uncertainty. This uncertainty is the basis for the expanded (final) uncertainty. As our work has shown, for samples, like bone, wood or charcoal, which undergo chemical pretreatment, combustion, graphitization, and 14C measurement, the calculated 14C measurement uncertainty must be multiplied by factor 1.6 to get the expanded uncertainty.

For more homogeneous samples, like a one-year tree ring sample where $\alpha $ -cellulose is collected, this multiplication factor is 1.4. Similarly, for CO2 samples collected from air, this factor is 1.1.

The achievement of this present work is twofold: first that the we have checked our carefully calculated 14C measurement uncertainty and shown that it is a reliable basis for reporting the final uncertainty, and second that we have established evidence-based multiplication factors for the various sample types. Future ring tests will benefit from this method of uncertainty estimate.

ACKNOWLEDGMENTS

We would like to thank the staff of the Centre for Isotope Research in Groningen, Dicky van Zonneveld, Henk Been, Marc Bleeker, Fsaha Ghebru, Berthe Verstappen-Dumoulin, Sven de Bruijn, Regina Linker, Henk Jansen, Margot Kuitems, Janette Spriensma, and Patricia Wietzes for their work. Without them we could not have performed this study (or run a 14C laboratory at all). We would like to thank Antonio Possolo (NIST) for pointing us to papers providing statistical background. We would also like to thank the two anonymous referees for their careful review and valuable suggestions for improvement.

APPENDIX 1 Comparison of 14C uncertainty calculation with MICADAS batch averages and calculations with four-monthly averages

During the first months of operation of the MICADAS, from September 2017 until July 2018, the calculation of the 14C measurement uncertainty (Eq. 2, dF 14Cn) was performed using the same methodology as with our former HV accelerator, namely based on daily or batch values for the error in the mean of the Oxalic Acid II references and the daily or batch values for the spread in the backgrounds. Table 4 provides the summary statistics for two background materials, namely background wood and Rommenhöller gas, for both situations (the data for the period after July 2018 is also shown in Table 1). From the data, it is apparent that the calculation of the 14C measurement uncertainty before July 2018 for background materials gives an uncertainty that underestimates the spread of the data. The internal error is too small (by a factor of 3). After July 2018 the uncertainty calculation is based on four-monthly averaged values, instead of the daily (batch) values. The four-monthly average value of the background is more reliable as a typical background for the samples, and the spread in these data of the last four months, is more realistic in comparison with the spread from only four backgrounds in one batch. In other words, the variability between batches is larger than the variability within one batch.

Table 4 Comparison of the calculation of the 14C measurement uncertainty (Eq. 2, dF14Cn) using daily values and four-monthly-averaged values for the error in the mean of the Oxalic Acid II references and for the spread in the backgrounds.

The actual external standard deviations of the measurements are approximately the same for both periods, as they should be, as the actual measurements were performed in the same way before and after that date.

APPENDIX 2 Calculations of weighted means, internal and external errors and $\chi _{red}^2$

To calculate the weighted average ( ${\bar x_w}$ ) of data from the secondary references, the weighting factor ( ${w_i}$ is given by the reciprocal of the variance (that is the square of the calculated 14C measurement uncertainty, dF 14Cn of the 14C measurement value (n is number of measurements and i represents a single measurement).

(4) $${w_i} = {\rm{ }}{1 \over {{\sigma _i}^2}}$$

The weighted mean in this case is (where x i is a single measurement):

(5) $${\bar x_w} = {\rm{ }}{{\sum\nolimits_{i{\kern 1pt} = {\kern 1pt} 1}^n {{w_i}} .{x_i}} \over {\sum\nolimits_{i{\kern 1pt} = {\kern 1pt} 1}^n {{w_i}} }}$$

The external standard deviation is calculated according to:

(6) $${\sigma _{ext}} = {\rm{ }}\sqrt {((} {{\sum\nolimits_{i{\kern 1pt} = {\kern 1pt} 1}^n {{w_i}} .x_i^2} \over {\sum\nolimits_{i{\kern 1pt} = {\kern 1pt} 1}^n {{w_i}} }} - {\bar x_w}^2)*\left( {{n \over {n - 1}}} \right))$$

The external error in the mean σ m,ext is calculated by dividing the external standard deviation by the square root of the number of measurements:

(7) $${\sigma _{m,ext}} = \sqrt {((} {{\mathop \sum \nolimits_{i = 1}^n {w_i}.x_i^2} \over {\mathop \sum \nolimits_{i = 1}^n {w_i}}} - {\bar x_w}^2)*\left( {{1 \over {n - 1}}} \right)\Big),\quad\,{\rm{or}}\,\quad{\sigma _{m,ext}} = {{{\sigma _{ext}}} \over {\sqrt n }}$$

The internal error in the mean σ m,int , (also called standard error of the weighted mean (SEWM)) is given by:

(8) $${\sigma _{m,int}} = \sqrt {{1 \over {\mathop \sum \nolimits_{i = 1}^n {w_i}}}} $$

Their ratio:

(9) $$\chi _{red}^2 = {\left( {{{{\sigma _{m,ext}}} \over {{\sigma _{m,{\mathop{\rm int}} }}}}} \right)^2} = \mathop \sum \nolimits_{i = 1}^n ({w_i}*{\left( {{x_i} - {{\bar x}_w}} \right)^2})*{1 \over {n - 1}}$$

References

REFERENCES

Aerts-Bijma, AT, Meijer, HAJ, van der Plicht, J. 1997. AMS sample handling in Groningen. Nuclear Instruments and Methods in Physics Research B 123(1–4):221225.CrossRefGoogle Scholar
Arnold, JR, Libby, WF. 1949. Age determinations by radiocarbon content: checks with samples of known age. Science 110(2869):678680.CrossRefGoogle ScholarPubMed
Birge, RT. 1932. The calculation of errors by the method of least squares. Physical Review 40(2):207227.CrossRefGoogle Scholar
Cook, AC, Wadsworth, J, Southon, JR, van der Merwe, NJ. 2003. AMS Radiocarbon dating of rusty iron. Journal of Archaeological Science 30(1):95101.CrossRefGoogle Scholar
Cook, GT, Higham, TFG, Naysmith, P, Brock, F, Freeman, SPHT, Bayliss, A. 2012. Assessment of infinite-age bones from the Upper Thames Valley, UK, as 14C background standards. Radiocarbon 54(3–4):845853.CrossRefGoogle Scholar
Damon, PE, Donahue, DJ, Gore, BH, Hatheway, AL, Jull, AJT, Linick, TW, et al. 1989. Radiocarbon dating of the Shroud of Turin. Nature 337(6208):611615.CrossRefGoogle Scholar
Dee, M, Wengrow, D, Shortland, A, Stevenson, A, Brock, F, Girdland Flink, L, Bronk Ramsey, C. 2013. An absolute chronology for early Egypt using radiocarbon dating and Bayesian statistical modelling. Proceedings of the Royal Society A 469:0395.Google ScholarPubMed
Dee, M, Palstra, SWL, Aerts-Bijma, A Th, Bleeker, MO, Bruijn de, S, Ghebru, F, Jansen, HG, Kuitems, M, Paul, D, Richie, RR, Spriensma, JJ, Scifo, A, Zonneveld van, D, Verstappen-Dumoulin, BMAA, Wietzes-Land, P, Meijer, HAJ. 2020. Radiocarbon dating at Groningen: new and updated chemical pretreatment procedures. Radiocarbon 62(1):6374.CrossRefGoogle Scholar
De Rooij, M, van der Plicht, J, Meijer, HAJ. 2010. Porous iron pellets for AMS 14C analysis of small samples down to ultra-microscale size (10–25 μgC). Nuclear Instruments and Methods in Physics Research B 268(7–8):947951.CrossRefGoogle Scholar
De Vries, HL, Barendsen, GW. 1952. A new technique for the measurement of age by radiocarbon. Physica XVIII (8–9):652.CrossRefGoogle Scholar
De Vries, HL, Barendsen, GW. 1954. Measurements of age by the carbon-14 technique. Nature 174:11381141.CrossRefGoogle Scholar
Gottdang, A, Mous, DJW, van der Plicht, J. 1995. The HVEE 14C system at Groningen. Radiocarbon 37(2):649656.CrossRefGoogle Scholar
Hedges, REM, Law, IA, Bronk, CR, Housley, RA. 1989. The Oxford accelerator mass spectrometry facility: technical developments in routine dating. Archaeometry 31(2):99113.CrossRefGoogle Scholar
Joint Committee for Guides in Metrology 2008. Evaluation of measurement data—guide to the expression of uncertainty in measurement (Gum 1995 with minor corrections). JCGM 100:2008.Google Scholar
Koepke, A, Lafarge, T, Possolo, A, Toman, B. 2017. Consensus building for interlaboratory studies, key comparisons, and meta-analysis. Metrologia 54(3):S34S62.CrossRefGoogle Scholar
Lafarge, T, Possolo, A. 2015. The NIST uncertainty machine. NCSLI Measure Journal of Measurement Science 10(3):2027.CrossRefGoogle Scholar
Lanting, JN, Aerts-Bijma, AT, van der Plicht, J. 2001. Dating of cremated bones. Radiocarbon 43(2A):249254.CrossRefGoogle Scholar
Le Clercq, M, van der Plicht, J, Groning, M. 1998. New 14C reference materials with activities of 15 and 50 pMC. Radiocarbon 40(1):295297.CrossRefGoogle Scholar
Libby, WF, Anderson, EC, Arnold, JR. 1949. Age determination by radiocarbon content: World-wide assay of natural radiocarbon. Science 109(2827):227228.CrossRefGoogle ScholarPubMed
Linick, TW, Damon, PE, Donahue, DJ, Jull, AJT. 1989. Accelerator mass spectrometry: the new revolution in radiocarbon dating. Quaternary International 1:16.CrossRefGoogle Scholar
Merkatas, C, Toman, B, Possolo, A, Schlamminger, S. 2019. Shades of dark uncertainty and consensus value for Newtonian constant of gravitation. Metrologia 56:054001:116.CrossRefGoogle Scholar
Meijer, HAJ, Pertuisot, MH, van der Plicht, J. 2006. High-accuracy 14C measurements for atmospheric CO2 samples by AMS. Radiocarbon 48(3):355572.CrossRefGoogle Scholar
Meijer, HAJ. 2009. Stable isotope quality assurance using the “Calibrated IRMS” strategy. Isotopes in Environmental and Health Studies 45(2):150163.CrossRefGoogle ScholarPubMed
Mook, WG, Streurman, HJ. 1983. Physical and chemical aspects of radiocarbon dating. Proceedings of the First International Symposium 14C and archaeology, Groningen 1(8):3155.Google Scholar
NIST. 2019. The NIST uncertainty machine. https://uncertainty.nist.gov, last accessed 20/03/09.Google Scholar
Paul, D, Been, HA, Aerts-Bijma, AT, Meijer, HAJ. 2016. Contamination on AMS sample targets by modern carbon is inevitable. Radiocarbon 58(02):407418.CrossRefGoogle Scholar
Rasmussen, KL, van der Plicht, J, Doudna, G, Nielsen, F, Hojrup, P, Stenby, EH, Pedersen, CT. 2009. The effects of possible contamination on the radiocarbon dating of the Dead Sea Scrolls II: empirical methods to remove castor oil and suggestions for redating. Radiocarbon 51(3):10051022.CrossRefGoogle Scholar
Reimer, PJ, Brown, TA, Reimer, RW. 2004. Discussion: reporting and calibration of post-bomb 14C data. Radiocarbon 46(3):12991304.Google Scholar
Rukhin, AL. 2009. Weighted means statistics in interlaboratory studies. Metrologia 46(3):323331.CrossRefGoogle Scholar
Scott, EM, Cook, GT, Naysmith, P. 2007. Error and uncertainty in radiocarbon measurements. Radiocarbon 49(2):427440.CrossRefGoogle Scholar
Scott, EM, Cook, GT, Naysmith, P. 2010. A Report on Phase 2 of the Fifth International Radiocarbon Intercomparison (VIRI). Radiocarbon 52(3):846858.CrossRefGoogle Scholar
Sookdeo, A, Kromer, B, Büntgen, U, Friedrich, M, Friedrich, R, Helle, G, et al. 2019. Quality dating: a well-defined protocol implemented at ETH for high-precision 14C-dates tested on late glacial wood. Radiocarbon 33:19.Google Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of 14C data. Radiocarbon 19(3):355363.CrossRefGoogle Scholar
Synal, H-A, Stocker, M, Suter, M. 2007. MICADAS: a new compact radiocarbon AMS system. Nuclear Instruments and Methods in Physics Research B 259(1):713.CrossRefGoogle Scholar
van der Laan-Luijkx, IT, Karstens, U, Steinbach, J, Gerbig, C, Sirignano, C, Neubert, REM, van der Laan, S, Meijer, HAJ. 2010. CO2 , δO2/N2 and APO: observations from the Lutjewad, Mace Head and F3 platform flask sampling network. Atmospheric Chemistry and Physics 10(21):1069110704.CrossRefGoogle Scholar
van der Plicht, J, Hogg, A. 2006. A note on reporting radiocarbon. Quaternary Geochronology 1:237240.CrossRefGoogle Scholar
van der Plicht, J, Palstra, SWL. 2016. Radiocarbon and mammoth bones: What’s in a date. Quaternary International 406:246251.CrossRefGoogle Scholar
Wacker, L, Christl, M, Synal, HA. 2010a. Bats: a new tool for AMS data reduction. Nuclear Instruments and Methods in Physics Research B 268(7–8):976979.CrossRefGoogle Scholar
Wacker, L, Bonani, G, Friedrich, M, Hajdas, I, Kromer, B, Němec, M, et al. 2010. MICADAS: routine and high-precision radiocarbon dating. Radiocarbon 52(2):252262.CrossRefGoogle Scholar
Figure 0

Figure 1 A schematic overview of different categories of duplicates. A higher category number refers to a higher number of independent steps in the total process.

Figure 1

Figure 2 14C measurement uncertainty contributions (slightly smoothed) due to the partial derivatives of the variables in Eq. (1) for a representative measurement batch. The quadratic sum of those components results in the 14C measurement uncertainty (dF14Cn, line f, black). The uncertainty in (14C/12C)sample is the statistical uncertainty (Poisson counting statistics) (line a, grey). The Poisson counting statistics is still the largest contribution to dF14Cn. The uncertainty in (14C/12C)cal (line b, magenta, calibration material is Oxalic Acid II) has practically no influence on samples with a low (14C/12C)sample, but the contribution increases for samples with a higher (14C/12C)sample. For samples with a low (14C/12C)sample, the uncertainty is dominated by the spread in (14C/12C)bg (line c, green). Line d (red) and line e (blue) are the contribution due to the partial derivatives of, respectively, δ13Csample (measured by MICADAS) and δ13Ccal (Oxalic Acid II). The latter one is practically negligible. (Please see electronic version for color figures.)

Figure 2

Table 1 Long-term data of cat. 2 and cat. 3 secondary reference materials, from 1-7-2018 until 1-4-2019. N represents the number of measurements. The measured Fraction Modern F14Cn is an averaged result weighted by the individual uncertainties (dF14Cn). The calculated 14C measurement uncertainty dF14Cn is averaged. The squared external standard deviation (σext) divided by the squared dF14Cn leads to the reduced Chi square ($\chi _{red}^2$, for equations see Appendix 2). Cat. 2 references show a $\chi _{red}^2$ smaller than 1, implicating that dF14Cn is slightly overestimated. Cat. 3 references do have a $\chi _{red}^2$ larger than 1, implicating that the combustion process contributes to a higher spread in the data. The last column gives the probability that the difference between both standard deviations is significant (based on the statistics of the $\chi _{red}^2$ distribution).

Figure 3

Figure 3 Long-term (≈ 1 year) standard deviation of cat. 2 (b) and cat. 3 (c) secondary references versus the Fraction Modern (14C content). For comparison, the calculated 14C measurement uncertainty is shown (averaged dF14Cn for last one and a half year) (a, black solid line). b. Spread of category (cat.) 2 secondary references (blue dashed line). These secondary references are Rommenhöller gas, IAEA-C8, IAEA-C7 and GS-51 (Groningen Standard, cane sugar). c. Spread of cat. 3 secondary references (red dotted line). These secondary references are background wood, IAEA-C8, IAEA-C7 and GS-51 (Groningen Standard, cane sugar).

Figure 4

Figure 4 References measured with a very long 14C measurement time in order to determine the optimal measurement time for a sample. The standard deviation from seven Oxalic Acid II references (a) and eight IAEA-C8 (b) (all cat. 2, blue) versus a measurement time of more than 10,000 seconds (3.5 × 106 accumulated counts for Oxalic Acid II). The calculated 14C measurement uncertainty (dF14Cn) is displayed in black. The shaded area around the standard deviation (blue) and dF14Cn (black) is the confidence band (1σ, 68%). The pink line shows the routine measurement time of 2400 seconds.

Figure 5

Table 2 Comparison of the observed differences of two 14C measurements for various duplicates from unknown samples, with the expected uncertainty. (The expected uncertainty is the quadratic sum of the individual measurement uncertainties.) The spread of the ratio ƒσ, (Eq. 3), σ(ƒσ), indicates in how far the observed uncertainty deviates from our calculated one. If σ(ƒσ) is larger than 1, the calculated 14C measurement uncertainties (dF14Cn) are too low, and some “dark uncertainty” is present. For random solid materials, like bone and charcoal and wood samples, σ(ƒσ) is on average 1.6, meaning dF14Cn had to be increased by 60% to match the spread. dF14Cn from more homogeneous materials like ${\rm{\alpha }}$-cellulose had to increased by 40% to match the spread. For a cat. 2 duplicate this increase is 10%.

Figure 6

Table 3 Minimum final reported uncertainties (expanded uncertainties) for various processes and samples, using the calculated dF14Cn and the multiplication factors from Table 2. The results are shown in Fraction Modern (%) and in 14C years (years BP). These uncertainties are valid for single measurements. The last column shows samples, which undergo the full pretreatment (chemical preparation, combustion, graphitization and 14C measurement). Columns to the left represent fewer steps in the sample handling process. As an example, when a bone sample is pretreated, combusted, graphitized, has its radiocarbon activity measured, and the date is calculated to be 1800 years BP, the minimum achievable uncertainty is 23 14C years BP. On the other hand, a contemporary atmospheric CO2 sample (F14Cn = 100%) is reported with an uncertainty of 0.18%, which is the equivalent of 14 14C years BP.

Figure 7

Table 4 Comparison of the calculation of the 14C measurement uncertainty (Eq. 2, dF14Cn) using daily values and four-monthly-averaged values for the error in the mean of the Oxalic Acid II references and for the spread in the backgrounds.