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A NEW RAMPED PYROXIDATION/COMBUSTION FACILITY AT 14CHRONO, BELFAST: SETUP DESCRIPTION AND INITIAL RESULTS

Published online by Cambridge University Press:  28 June 2021

Evelyn M Keaveney*
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Archaeology & Palaeoecology Building, Queen’s University Belfast, 42 Fitzwilliam Street, BelfastBT9 6AX, United Kingdom
Gerard T Barrett*
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Archaeology & Palaeoecology Building, Queen’s University Belfast, 42 Fitzwilliam Street, BelfastBT9 6AX, United Kingdom
Kerry Allen
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Archaeology & Palaeoecology Building, Queen’s University Belfast, 42 Fitzwilliam Street, BelfastBT9 6AX, United Kingdom
Paula J Reimer
Affiliation:
14CHRONO Centre for Climate, the Environment and Chronology, Archaeology & Palaeoecology Building, Queen’s University Belfast, 42 Fitzwilliam Street, BelfastBT9 6AX, United Kingdom
*
*Corresponding authors. Emails: e.keaveney@qub.ac.uk, g.barrett@qub.ac.uk
*Corresponding authors. Emails: e.keaveney@qub.ac.uk, g.barrett@qub.ac.uk
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Abstract

The Belfast Ramped Pyroxidation/Combustion (RPO/RC) facility was established at the 14CHRONO Centre (Queen’s University Belfast). The facility was created to provide targeted analysis of bulk material for refined chronological analysis and carbon source attribution for a range of sample types. Here we report initial RPO results, principally on background material, but also including secondary standards that are routinely analyzed at 14CHRONO. A description of our setup, methodology, and background (blank) correction method for the system are provided. The backgrounds (anthracite, spar calcite, Pargas marble) reported by the system are in excess of 35,000 14C years BP with a mean age of 39,345 14C years BP (1σ = 36,497–43,800 years BP, N=44) with F14C = 0.0075 ± 0.0032. Initial results for standards are also in good agreement with consensus values: TIRI-B pine radiocarbon age = 4482 ± 47 years BP (N=13, consensus = 4508 years BP); IAEA-C6 ANU Sucrose F14C= 1.5036 ± 0.0034 (N=10, consensus F14C = 1.503). These initial tests have allowed problematic issues to be identified and improvements made for future analyses.

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
© The Author(s), 2021. Published by Cambridge University Press for the Arizona Board of Regents on behalf of the University of Arizona

INTRODUCTION

The new Belfast Ramped Pyroxidation/Combustion (RPO/RC) facility was set up to provide analysis of archaeological and environmental (bulk) samples. Radiocarbon dating bulk material is problematic due to samples such as sediment, soil or peat comprising multiple carbon sources (Grimm et al. Reference Grimm, Maher and Nelson2009; Keaveney et al. Reference Keaveney, Reimer and Foy2015; van der Plicht et al. Reference van der Plicht and Palstra2016; Bao et al. Reference Bao, McNichol, McIntyre, Xu and Eglinton2018). In addition, the presence of contamination is also an issue due to burial conditions or preservation protocols with conserved materials (Higham Reference Higham2019). Bulk material often has to undergo stringent pre-treatment procedures leading to loss of material and low carbon yields. Even with these intensive methods, the date may be younger or older than expected depending on the age of the individual fractions.

The RPO/RC method (Rosenheim et al. Reference Rosenheim, Day, Domack, Schrum, Benthien and Hayes2008, Reference Rosenheim, Santoro, Gunter and Domack2013; Hemingway et al. Reference Hemingway, Rothman, Rosengard and Galy2017; Zigah et al. Reference Zigah, Minor, McNichol, Xu and Werne2017; Bao et al. Reference Bao, McNichol, McIntyre, Xu and Eglinton2018) was developed at The National Ocean Sciences Accelerator Mass Spectrometry (NOSAMS) and the University of South Florida. With the help of colleagues from these institutions, a ramped pyroxidation/combustion system was constructed in the 14CHRONO Centre, Queen’s University Belfast, with the capability of switching between RPO and RC modes. RPO is a method that incrementally heats a bulk sample and allows for the separation of material into its composite fractions according to their thermal stability. The RPO products are then oxidized, and the resulting CO2 is collected cryogenically by an automated valve system. The CO2 collected is transferred under vacuum to a connected graphitization line for conversion to graphite, which is then analyzed for radiocarbon content. By using RPO, we can acquire a profile of the CO2 produced over different temperature intervals, providing an indication of the composition of the bulk material as well as a suite of radiocarbon values from the respective individual CO2 fractions. Here we report initial RPO and radiocarbon analysis of background and secondary standards commonly analyzed at the 14CHRONO Centre.

METHODS

Ramped Pyroxidation Configuration

The ramped pyroxidation/combustion furnace arrangement is presented in Figure 1 and was designed and constructed following RPO setups used elsewhere (e.g., Rosenheim et al. Reference Rosenheim, Santoro, Gunter and Domack2013; Hemingway et al. Reference Hemingway, Galy, Gagnon, Grant, Rosengard, Soulet, Zigah and McNichol2017; Zigah et al. Reference Zigah, Minor, McNichol, Xu and Werne2017; Bao et al. Reference Bao, McNichol, McIntyre, Xu and Eglinton2018). In ramped pyroxidation mode (used in the results presented here), Helium gas (99.999% purity) flows through the top of the reactor (35 mL/min) as the sample is heated in the absence of oxygen (pyrolysis). Oxidation occurs in the lower furnace via O2 (99.999%) that flows in (3 mL/min) through the sidearm with He (10 mL/min). This reacts with the pyrolysis derived products of the upper furnace that have been carried by helium into the lower furnace. Copper oxide, nickel and platinum (Ni/Pt/CuO) wires act as catalysts, to ensure complete oxidation of carbon-bearing pyrolysis products to CO2.

Figure 1 RPO furnace arrangement featuring upper furnace for pyrolysis or combustion of the sample and lower furnace for oxidation of pyrolysis derived products and/or reduction of oxygen from combustion process.

The RPO quartz reactor insert (Figure 1) was baked at 850ºC overnight, and then baked at 1000ºC in-situ in the pyrolysis furnace until no CO2 was produced. Bulk samples were lyophilised overnight and placed in the quartz reactor insert, which was then inserted to the quartz reactor vessel in the upper furnace (Figure 1). The mass of material required is dependent on carbon content but typically in the order of 20–100 mg.

The oxidation furnace was switched on and allowed to reach 850ºC before the ramping furnace was set to continuously ramp to 1000ºC, typically over 3–4 hr, with ramp rates in the range of 2.5–6.5°C per min, depending on sample type. Ramp rates were also varied to investigate the impact on the CO2 profile and to examine the effect of contamination introduced for different collection time intervals. Any CO2 evolved over the ramp cycle was quantified using a Sable Systems CA-10 infra-red CO2 detector, and spectra were logged using LabVIEW software and National Instruments data acquisition hardware.

An automated cryogenic trap system was used to collect CO2 from targeted areas of the spectrum. For new sample types, an initial “profile” run without collection illustrated the temperature at which intervals CO2 structures of interest occurred. CO2 was cryogenically captured at these intervals for radiocarbon measurement during subsequent “collection” runs. The CO2 was transferred under vacuum to a connected (newly constructed) graphitization line, and samples were graphitized in the presence of an iron catalyst at 560ºC for 4 hr using the Bosch-Manning hydrogen reduction method (Manning and Reid Reference Manning and Reid1977; Vogel et al. Reference Vogel, Nelson and Southon1987). Samples were analyzed on a 0.5 MeV National Electrostatics compact accelerator mass spectrometer (AMS) at the 14CHRONO Centre in Queen’s University Belfast. The 14C/12C ratio of the sample relative to an international standard (F14C) and its associated uncertainty were calculated according to Reimer et al. (Reference Reimer, Brown and Reimer2004) and van der Plicht and Hogg (Reference van der Plicht and Hogg2006) and incorporated a fractionation correction (Stuiver and Polach Reference Stuiver and Polach1977) based on 13C/12C measured by AMS.

Background (Blank) Measurements

A suitable background correction for the 14CHRONO RPO system was developed based on methods used at the NOSAMS RPO Facility (Fernandez et al. Reference Fernandez, Santos, Williams, Pendergraft, Vetter and Rosenheim2014; Hemingway et al. Reference Hemingway, Galy, Gagnon, Grant, Rosengard, Soulet, Zigah and McNichol2017). Data was used from 14 separate RPO runs carried out on background materials routinely analyzed at the 14CHRONO Centre (anthracite (%C = 85–98%), sparitic calcite (%C = 12%, theoretical), and Pargas marble, all of geological age, i.e., negligible 14C content). CO2 was collected from 38 temperature intervals. Fifty AMS radiocarbon measurements were obtained from the CO2 produced (12 were duplicates). Two to six temperature fractions of CO2 were isolated for each run with the median temperature of collection ranging from 601–908°C, the duration of collection ranging from 1.2 to 8.1 min, and the sampled mass ranging from 0.25 to 2 mg C. Contamination was determined in 6 samples due to inaccurate 14C dates (having a bias consistent with air leakages). These were removed from the analysis, 2 on account of leakage into the graphitization line reactors (connector issues) and 4 due to significant leakage in the RPO setup (resolved with tightening or replacement of connectors and inspection/replacement of valve seals).

Standard Measurements

A series of RPO measurements have been carried out on two standards: TIRI-B pine, which has a consensus value of 4508 14C years BP, 14CHRONO mean value = 4507 ± 44 years BP (n = 542), %C = 47 ± 10% and IAEA-C6 ANU Sucrose with a consensus F14C = 1.503, 14CHRONO mean value = 1.503 ± 0.0078 (n = 1868), %C = 42% (theoretical). For each, 4 RPO runs were carried out as a part of initial tests of the system and newly constructed hydrogen graphitization line. For TIRI-B, a total of 20 CO2 fractions were successfully captured and graphitized for radiocarbon dating. For Sucrose, a total of 14 gas CO2 fractions were successfully captured, graphitized and radiocarbon dated. Usually, a series of RPO runs were carried out and dated on a wheel with other routine samples before a complete wheel of RPO samples was run on the AMS. For this reason, line leakages affected multiple runs before being identified and resolved (radiocarbon dates on standards deviated significantly from consensus dates significantly in a direction consistent with air leakages). Four TIRI-B samples (fractions from a single RPO run) were discarded due to a RPO line leak and a further three dates were removed due to graphite line reactor leakages. Three Sucrose samples were discarded due to graphite line/separation valve line leakages, and one was discarded as a measurement outlier (using Chauvenet’s criterion for outlier identification, Hughes and Hase Reference Hughes and Hase2009).

Background (Blank) Corrections

It is necessary to carry out a background correction for any non-background run in the system. From analysis of the background results, variation of F14C with RPO variables such as the ramp rate and collection temperature were not found to be statistically significant. However, there was a relationship with the quantity of CO2 collected (expressed as mg C) and the ratio of the collection time to quantity of CO2 collected (Figure 2). This latter variable reflects the fraction of CO2 contamination introduced to the system through leakages in the RPO/RC line with its relationship to F14C derived in the background correction now described.

Figure 2 Linear regression plot of F14C versus Δt/M for all RPO background runs. Black circle—anthracite; red diamond—spar calcite; blue square—Pargas marble. Dashed magenta—1δ uncertainty on regression model. Regression result: y = 0.0005 (± 0.0002) x + 0.0049 (± 0.0008), R2 = 0.25.

For an RPO measurement on background material, the measured F14CB, of mass MB, is expressed as a combination of a dead component, F14CD, of mass MD, and a contaminating component, F14Cc, of mass MC (under ideal conditions F14CD = 0, however, in the following derivation F14CD is used to reflect and incorporate any non-RPO/RC related deviation of the blank from zero, for example contaminant introduced to the blank prior to loading in the RPO/RC reactor). The measured F14CB can be expressed as:

(1) $${F^{14}}{C_B} = \;{F^{14}}{C_D}{{{M_D}} \over {{M_B}}} + \;{F^{14}}{C_C}{{{M_C}} \over {{M_B}}}$$

with

(2) $${M_B} = {\rm{\;}}{M_D} + {\rm{\;}}{M_C}$$

Using (2) we can re-express (1) as

(3) $${F^{14}}{C_B} = \;{F^{14}}{C_D} + \;{{{M_C}} \over {{M_B}}}({F^{14}}{C_C}\; - \;{F^{14}}{C_D})$$

Furthermore, we can express MC as the sum of two components: a non-time dependent MC1 that is a systematic contamination and can be expressed as a percentage of the total background mass sampled with MC1 = aMB (a = constant); a time dependent MC2 that is proportional to the collection time, Δt, and governed by a contamination rate C (expressed in mg/min and due to leakages in the RPO, reasonable to assume where vacuum fittings were used in a non-vacuum system) with MC2 = Δt C. With this, (3) can be re-arranged to:

$${F^{14}}{C_B} = \;{F^{14}}{C_D} + \;{{{M_{C1}} + {M_{C2}}} \over {{M_B}}}({F^{14}}{C_C}\; - \;{F^{14}}{C_D})$$
$${F^{14}}{C_B} = \;{F^{14}}{C_D} + \;{{a{M_B}} \over {{M_B}}}({F^{14}}{C_C}\; - \;{F^{14}}{C_D}) + \;{\Delta \over {{M_B}}}({F^{14}}{C_C}\; - \;{F^{14}}{C_D})$$
(4) $${F^{14}}{C_B} = \left( {{F^{14}}{C_D} + \;a\Delta F} \right) + \;{\Delta \over {{M_B}}}\Delta F$$

where ΔF = F14Cc – F14CD

This is equivalent to the linear expression:

$$y = c + mx$$

where $$y = {F^{14}}{C_B},\;\;c = {F^{14}}{C_D} + \;a\Delta F,\;m = C\Delta F,\;x = {{\Delta t} \over {{M_B}}}\;$$

As we measure F14CB, Δt, and MB, we used the above relationship to apply a linear regression (ordinary least squares carried out with MATLAB R2020a, Figure 2) on our background dataset and established estimates of c and m that were then used to estimate an F14C value for background corrections on all samples.

The associated uncertainty in the background correction, δB, using the uncertainties in c and m, δc and δm, respectively, calculated from regression analysis, can be expressed as,

$$\delta _B^2 = \;{\left( {{{\partial y} \over {\partial c}}} \right)^2}\delta _c^2\; + \;{\left( {{{\partial y} \over {\partial m}}} \right)^2}\delta _{m\;}^2 + \;\left( {{{\partial y} \over {\partial x}}} \right)\delta _x^{{2^2}}{\rm{ }}$$
(5) $$\delta _B^2 = \;\delta _c^2\; + \;{\left( {{{\Delta t} \over {{M_B}}}} \right)^2}\delta _{m\;}^2 + {m^2}\delta _{x\;}^2$$

This also includes an expression for the uncertainty in $${\rm{x}} = {{\Delta {\rm{t}}} \over {{{\rm{M}}_{\rm{B}}}}}$$ , $${\rm{\delta }}_{{\rm{x\;}}}^2$$ . This is given by:

$${\left( {{{{\delta _x}} \over x}} \right)^2} = {\left( {{{\delta \Delta t} \over {\Delta t}}} \right)^2} + {\left( {{{\delta {M_B}} \over {{M_B}}}} \right)^2}$$
(6) $$\delta _{x\;}^2 = {\left( {{{\Delta t} \over {{M_B}}}} \right)^2}\left({\left( {{{\delta \Delta t} \over {\Delta t}}} \right)^2} + {\left( {{{\delta {M_B}} \over {{M_B}}}} \right)^2}\right)$$

with $${{\delta \Delta {\rm{t}}} \over {\Delta {\rm{t}}}}$$ the fractional uncertainty in the measurement of the duration of CO2 capture for a temperature fraction and $${{\delta {{\rm{M}}_{\rm{B}}}} \over {{{\rm{M}}_{\rm{B}}}}}$$ the fractional uncertainty in the estimated mass of gas captured. The uncertainties in the measured duration of capture, $$\delta $$ Δt, and mass of gas captured, $$\delta $$ MB, are 10 seconds and 0.02 mg, respectively.

The above methodology was applied to the RPO background dataset resulting in an estimate to be used in future background corrections. The parameters of this model will be updated regularly with 1–2 new background runs for every 6–8 sample runs.

RESULTS AND DISCUSSION

Backgrounds

The results from all backgrounds are presented in Figure 3 with the associated ages shown in Table 1. The average background value is F14C = 0.0075 ± 0.0032 (39950 ± 3132 BP, n = 44). No significant differences were observed between anthracite and calcite results. Background F14C values are consistent with contamination ranging from approximately 0.2–0.8% modern CO2. From our regression analysis the contamination not associated with leakage into the RPO line, i.e., systematic contamination, results in F14C = 0.0049 ± 0.0008, corresponding to an age of 42,700 years BP (approximately 0.25% modern carbon). Any remaining contamination is most likely derived from RPO/RC line leakages. We assume the dominant source of such leakages are connections between Swagelok Ultra-Torr vacuum fittings and the quartz glass at the entrance and exit of the furnace that are prone to low-level leakages when operating under non-vacuum conditions.

Figure 3 RPO background results (1σ) expressed in F14C. Note apparent shift to more modern values is associated with the use of smaller samples sizes, longer collection times, and an associated higher proportion of contamination. Black circle—anthracite; red diamond—spar calcite; blue square—Pargas marble. Red vertical lines used to separate individual RPO runs.

Table 1 RPO background results for anthracite, spar calcite, and Pargas marble.

Figure 4 shows CO2 profiles of CO2 captured fractions and associated ages of anthracite (4a) and calcite (4b) RPO runs. These demonstrate the statistical agreement observed between the ages obtained from different temperature fractions. The profiles are as expected; a broad shoulder of thermal decomposition (approximately 550–950°C) is evident on the anthracite profile and a well-defined peak (approximately 650–850°C) of thermal decomposition (795°C) is seen on the calcite profile. Both profiles indicate that the RPO/RC system is efficient at the upper limit of its temperature range (< 1000°C). The yields obtained on complete runs (i.e., RPO runs to high enough temperatures to allow complete thermal decomposition) were also in in good agreement with expected values: for anthracite two complete runs each resulted in a yield of % C = 93%; for spar calcite seven complete runs resulted in yields of %C = 12.9 ± 1.5%. Yields in agreement with expected values, particularly for high carbon content anthracite, support that the RPO system is completely oxidizing and capable of capturing all the pyrolysis products produced in the process.

Figure 4 Example background RPO run for anthracite sample (a) and spar calcite sample (b). Fuzzy grey line—raw data (spiked structures associated with valve sequence switch-over have been removed). Black solid line—spline smoothed data. Red and yellow boundaries mark temperature intervals of CO2 capture with resultant radiocarbon results (F14C) presented on secondary axis (y axis error bars to 1σ, x axis error bars mark temperature interval). Duplicates of the CO2 fraction captured were dated for most fractions (for anthracite, the duplicates of the last sample are almost identical and difficult to distinguish).

Secondary Standards

The results of secondary standards TIRI-B and ANU Sucrose are presented in Tables 2 and 3 and the associated radiocarbon age and F14C results are plotted in Figure 5. An example RPO run for each is presented in Figure 6. The results are within range of consensus values. The mean age of TIRI-B samples was 4482 ± 47 years BP (N = 13, consensus = 4508 years BP). The mean age of IAEA-C6 ANU Sucrose was F14C= 1.5036 ± 0.0034 (N = 10, consensus F14C = 1.503). The yield from two complete runs was %C = 48.4 ± 3.0%, supporting complete oxidation of the pyrolysis products.

Table 2 RPO results from TIRI-B Pine.

Table 3 RPO results for IAEA-C6 ANU-Sucrose.

Figure 5 RPO results from analysis of TIRI – B pine (a) and IAEA-C6 ANU Sucrose (b). Red dashed line—consensus value, 14C age = 4508 years BP (pine) and F14C = 1.503 (sucrose). Error bars to 1σ.

Figure 6 Example RPO run for TIRI-B pine sample (a) and IAEA C-6 ANU Sucrose (b). Fuzzy gray line—raw data (spiked structures associated with valve sequence switch-over removed). Black solid line—spline smoothed data. Red and yellow boundaries mark temperature intervals of CO2 capture with resultant radiocarbon results presented on secondary axis (y axis error bars to 1σ, x axis error bars mark temperature interval). Dashed red line—consensus value of (age = 4508 years BP and F14C = 1.504, respectively). Black solid region—run paused to resolve ice trap blockage.

During the pyrolysis of organic material, there is preferential loss of hydrogen, nitrogen, sulphur and oxygen (Li et al. Reference Li, Shen, Zhang, Mei, Ran, Xu and Yu2013; Williams et al. Reference Williams, Rosenheim, McNichol and Masiello2014). This leads to the increased formation of aromatic hydrocarbons, which are more resistant to thermal decomposition. This process is known as charring (Currie et al. Reference Currie and Kessler2005; Fernandez et al. Reference Fernandez, Santos, Williams, Pendergraft, Vetter and Rosenheim2014; Williams et al. Reference Williams, Rosenheim, McNichol and Masiello2014). Charred products decompose at a higher temperature and can leading to double peaks similar to those observed in both the ANU sucrose and TIRI-B pine cellulose CO2 profiles. Alternatively organic material also comprises multiple carbon pools and the multiple peaks in profiles from this study may indicate the presence of carbon products from different thermal decomposition processes (Hemingway et al. Reference Hemingway, Galy, Gagnon, Grant, Rosengard, Soulet, Zigah and McNichol2017), e.g., sucrose comprises fructose, glucose, which can break down at different temperatures.

However, this highlights a potential issue with RPO of organic samples, as low temperature pyrolysis products may char and become resistance to thermal decay leading to decomposition at higher temperatures. Organic samples may contain a mixture of carbon sources. Labile carbon can form char and evolve at the equivalent temperatures to older recalcitrant carbon. As such, this may lead to incorporation of this labile material into the high temperature fraction; the high temperature fraction 14C age will consequently be offset and appear younger. Either a charring correction (Williams et al. Reference Williams, Rosenheim, McNichol and Masiello2014) or utilization of ramped combustion may be more appropriate for some organic samples (the RPO/RC system at the 14CHRONO Centre is equipped to perform both procedures), especially where higher temperature fractions are of interest.

CONCLUSION

Backgrounds and secondary standard CO2 profiles and radiocarbon values presented here demonstrate the ability of the 14CHRONO Ramped Pyroxidation line to measure varying sample types with an acceptable process background value. Future testing will include the operation of the ramped combustion mode and collection of CO2 for δ13C stable isotope analysis. The efficacy of this RPO/RC facility has been tested using a range of sample types including mortar, lake and marine sediment, and a preserved archaeological wooden bowl from the National Museum, Dublin (Ireland). Publication of these results is forthcoming. The results of background and standard results here give us confidence that our analyses are robust and replicable.

ACKNOWLEDGMENTS

We would like to thank our colleagues at NOSAMS and the University of South Florida, in particular Brad Rosenheim, Prosper Zigah, Ann McNichol, and Mary Lardie, for all their generous advice and guidance. We also would like to express our gratitude to George Burton and Ben Healey (Queen’s University Belfast) for glassware manufacture and their assistance with glassware design. For electronics advice, we also wish to thank Barry Finnegan for his assistance. We also want to thank Jordon Hemingway and an anonymous reviewer for constructive comments. Finally, a thanks to the broader 14CHRONO team and the School of Natural and Built Environment for their on-going assistance and support.

References

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Figure 0

Figure 1 RPO furnace arrangement featuring upper furnace for pyrolysis or combustion of the sample and lower furnace for oxidation of pyrolysis derived products and/or reduction of oxygen from combustion process.

Figure 1

Figure 2 Linear regression plot of F14C versus Δt/M for all RPO background runs. Black circle—anthracite; red diamond—spar calcite; blue square—Pargas marble. Dashed magenta—1δ uncertainty on regression model. Regression result: y = 0.0005 (± 0.0002) x + 0.0049 (± 0.0008), R2 = 0.25.

Figure 2

Figure 3 RPO background results (1σ) expressed in F14C. Note apparent shift to more modern values is associated with the use of smaller samples sizes, longer collection times, and an associated higher proportion of contamination. Black circle—anthracite; red diamond—spar calcite; blue square—Pargas marble. Red vertical lines used to separate individual RPO runs.

Figure 3

Table 1 RPO background results for anthracite, spar calcite, and Pargas marble.

Figure 4

Figure 4 Example background RPO run for anthracite sample (a) and spar calcite sample (b). Fuzzy grey line—raw data (spiked structures associated with valve sequence switch-over have been removed). Black solid line—spline smoothed data. Red and yellow boundaries mark temperature intervals of CO2 capture with resultant radiocarbon results (F14C) presented on secondary axis (y axis error bars to 1σ, x axis error bars mark temperature interval). Duplicates of the CO2 fraction captured were dated for most fractions (for anthracite, the duplicates of the last sample are almost identical and difficult to distinguish).

Figure 5

Table 2 RPO results from TIRI-B Pine.

Figure 6

Table 3 RPO results for IAEA-C6 ANU-Sucrose.

Figure 7

Figure 5 RPO results from analysis of TIRI – B pine (a) and IAEA-C6 ANU Sucrose (b). Red dashed line—consensus value, 14C age = 4508 years BP (pine) and F14C = 1.503 (sucrose). Error bars to 1σ.

Figure 8

Figure 6 Example RPO run for TIRI-B pine sample (a) and IAEA C-6 ANU Sucrose (b). Fuzzy gray line—raw data (spiked structures associated with valve sequence switch-over removed). Black solid line—spline smoothed data. Red and yellow boundaries mark temperature intervals of CO2 capture with resultant radiocarbon results presented on secondary axis (y axis error bars to 1σ, x axis error bars mark temperature interval). Dashed red line—consensus value of (age = 4508 years BP and F14C = 1.504, respectively). Black solid region—run paused to resolve ice trap blockage.