¹⁴C Content and δ¹³C Value of the Initial Reactants

The results of the initial reactants are given in Table 2. The carbon contents of horse manure (100.4 ± 0.3 pMC) and natural vinegar (100.8 ± 0.3 pMC) show compatible results within 2σ, indicating that these two elements are contemporary. These values are also consistent with the contemporaneous atmosphere recorded in 2020 and measured on nuts collected in France (100.8 ± 0.4 pMC). CO₂ gas, usually used as a blank, gives a mean ¹⁴C content of 0.206 ± 0.041 pMC. The industrial acetic acid ¹⁴C content is very low, close to the ¹⁴C detection limit.

Table 2 ¹⁴C content in pMC and AMS δ¹³C of the reactants. For comparison, the contemporaneous ¹⁴C content of the atmospheric CO₂ is indicated. It was estimated by measuring the ¹⁴C content of nuts collected in France in 2020.

The δ¹³C values of horse manure and vinegar, –29‰ and –18‰, are in the range of organic matter, whereas the δ¹³C values of CO₂ gas and acetic acid, –35‰ and –43.6‰ respectively, are characteristic of materials derived from fossil fuels.

Chemical Structure of the Final Products

A white powder was obtained for all the setups due to the corrosion of the metallic lead foil (Figure 2). Two main products were determined by XRD after 2 months of exposure: lead acetate trihydrate, Pb(CH₃COO)₂.3(H₂O) (Figure 3a) for setups 1, 2, and 5 and cerussite, PbCO₃ (Figure 3b) for setups 3, 4, and 6 (Table 3).

Table 3 Composition, ¹⁴C content in pMC, IRMS and AMS δ¹³C of the reaction products after 53 to 120 days of exposure (120 days for setups 1 and 2; 73 days for setups 3 and 4; 53 for setups 5 and 6). Composition was determined by XRD after 64 days for setup 1; 53 days for setups 2, 5, 6; 10 and 73 days for setups 3 and 4.

Figure 3 X-ray diffractograms of the white powder collected from: (a) setup 2 showing the production of lead acetate trihydrate (setups 1 and 5 show the same pattern), (b) setup 4 showing the production of cerussite (setups 3 and 6 show the same pattern).

Lead acetates were detected for setups 1 and 2 where lead was submitted to the vapors of vinegar or acetic acid (CH₃COOH), as also observed by Gonçalves et al. (Reference Gonçalves, Pires, Carvalho, Mendonca, Cruz and Urbano Alfonso2010). The formation of the trihydrate form was promoted when water vapor condensed (Gonzalez et al. Reference Gonzalez, Wallez, Calligaro, Gourier and Menu2019) following the reaction:

(1) $${\rm{Pb + 2 C}}{{\rm{H}}_{\rm{3}}}{\rm{COOH + 1/2 }}{{\rm{O}}_{\rm{2}}}{\rm{\ +\ 2}}{{\rm{H}}_{\rm{2}}}{\rm{O}} \to {\rm{Pb}}{\left( {{\rm{C}}{{\rm{H}}_{\rm{3}}}{\rm{COO}}} \right)_{\rm{2}}}{\rm{.3}}\left( {{{\rm{H}}_{\rm{2}}}{\rm{O}}} \right)$$

In presence of horse manure and vinegar or acetic acid (setups 3, 4), pure cerussite (PbCO₃) was formed from the second day of exposure. The formation of lead carbonate indicates that the supply in CO₂, produced here by fermentation of the manure, was enough for the reaction

(2) $${\rm{Pb + C}}{{\rm{O}}_{\rm{2}}}{\rm{\ +\ 1/2 }}{{\rm{O}}_{\rm{2}}} \to {\rm{PbC}}{{\rm{O}}_{\rm{3}}}$$

to be complete. No other intermediate compounds described by Gonzalez et al. (Reference Gonzalez, Wallez, Calligaro, Gourier and Menu2019), such as plumbonacrite (Pb₅(CO₃)₃O(OH)₂) and hydrocerussite (2PbCO₃.Pb(OH)₂) were observed, even in the early stages of the reaction.

When CO₂ gas was injected, two different results were obtained. For setup 5 with acetic acid, corrosion took place very slowly and only a thin layer of lead acetate was detected. In contrast, in presence of vinegar (setup 6), lead carbonate (cerussite) was obtained. Several hypotheses can be put forward to explain this difference: experimental failure (lack of CO₂ in setup 5) and/or a possible role played by the microorganisms contained in vinegar (setup 6) as an additional source of CO₂ as suggested by Sanchez-Navas et al. (Reference Sanchez-Navas, Lopez-Cruz, Velilla and Vidal2013) and Photos-Jones et al. (Reference Photos-Jones, Bots, Oikonomou and Hamilton2020).

¹⁴C Content and δ¹³C Value of the Final Products

The results obtained for the final products are presented in Table 3. For setups 1 and 2, the samples were taken after 4 months of exposure. Lead acetate formed from lead and vinegar has a ¹⁴C content of 103.394 ± 0.205 pMC and a δ¹³C value of –17.4‰. Lead acetate formed from lead and acetic acid has a ¹⁴C content of 10.42 ± 0.05 pMC and a δ¹³C value of –39.6‰. The δ¹³C values are of the same order of magnitude as those of the initial ingredients (vinegar δ¹³C value = –18.8‰; acetic acid δ¹³C value = –35±3‰), but the ¹⁴C contents are slightly higher (vinegar ¹⁴C content = 100.8 ± 0.3 pMC; acetic acid ¹⁴C content = 0.206 ± 0.041 pMC). These results are probably due to external contamination by environmental CO₂ or by the other setups nearby, occurring during the long time of exposure. For setup 1, measurement after one week of exposure only seems to confirm this interpretation with a ¹⁴C content of 1.558 ± 0.125 pMC and a δ¹³C value of –36 ± 4‰ (SacA61010, not reported in Table 3) very close to those of acetic acid. For setup 2, the result is above the current atmospheric level, but no other source of ¹⁴C has been identified so far. For setups 1 and 2, it can be inferred that Pb(CH₃COO)₂.3(H₂O) has a similar carbon isotope signature to that of the corrosive liquid. No significant δ¹³C fractionation was observed. These results confirm that lead acetate was produced by the reaction of the acid vapors on lead according to reaction (1).

Lead actetate was also obtained in the case of setup 5 when acetic acid and fossil CO₂ gas were used. The ¹⁴C content is 0.359 ± 0.033 pMC and the δ¹³C value –36.43‰. These values are similar to those of the initial ingredients, but as both acetic acid and fossil CO₂ gas have a very similar carbon isotope signature, it is not possible to estimate the contribution of each component to the formation of lead acetate in that case.

For setups 3, 4, and 6, the samples were taken after ∼2 months of exposure. The cerussite produced in setup 3 from lead, acetic acid and horse manure has a ¹⁴C content of 94.4 ± 0.2 pMC and a δ¹³C value of –50.3‰. In setup 4 where vinegar is present, the ¹⁴C content is 101.1 ± 0.3 pMC and the δ¹³C value is –49.9‰. In setup 6, the cerussite produced from lead, vinegar and fossil CO₂ gas has a ¹⁴C content of 4.59 ± 0.06 pMC and a δ¹³C value of –46.8‰. The ¹⁴C content of the cerussite produced shows values around 100 pMC when horse manure was involved whatever the corrosive reagent used (vinegar or acetic acid), and a low value when fossil CO₂ gas was used with vinegar (Table 3). These results clearly indicate the predominant influence of CO₂ when lead carbonate is produced according to reaction (2).

In these three setups, carbonatation was achieved and pure cerussite was obtained, mostly carriyng the ¹⁴C signature of the initial CO₂. However, the influence of the corrosive reagent can be seen when looking in detail at the pMC values for setups 3 and 4. The ¹⁴C content of cerussite from setup 4 was 101.1 ± 0.3 when horse manure was used with natural vinegar, whereas the ¹⁴C content of cerussite from setup 3 was 94.4 ± 0.2 when horse manure was used with acetic acid (<0.25 pMC). The latter value reflects the presence of traces of acetic acid between the flakes of lead white or minor phases (<5%) not seen by XRD, carrying the ¹⁴C signature of acetic acid. The same observation can be made in the reverse situation (setup 6) where the cerussite produced by fossil CO₂ gas (0.21 ± 0.04 pMC) with natural vinegar (100.8 ± 0.3) has a ¹⁴C content of 4.6 ± 0.1 pMC.

About the δ¹³C results, contrary to lead acetate, cerussite produced using horse manure shows a strong fractionation: very depleted δ¹³C values of –50.3‰ and –49.9‰ were obtained although the initial ingredients had δ¹³C values of –18.8‰ (vinegar) or –43.6‰ (acetic acid) and –28.9‰ (horse manure). The δ¹³C signature is lower than expected for the organic matter from an animal’s diet, which is generally between –32‰ and –10‰ (Amelung et al. Reference Amelung, Bol and Friedrich1999; Sponheimer et al. Reference Sponheimer, Robinson, Ayliffe, Passey, Roeder, Shipley, Lopez, Cerling, Dearing and Ehleringer2003; Inacio et al. Reference Inácio2013). Hendriks et al. (Reference Hendriks, Caseri, Ferreira, Scherrer, Zumbuhl, Kuffner, Hajdas, Wacker, Synal and Guntet2020) and Messager et al. (Reference Messager, Beck, Blamart, Richard, Germain, Batur, Gonzalez and Foy2022) obtained similar results, with δ¹³C values between –45 and –40‰ for lead whites prepared with the same process but provided by other suppliers.

Low δ¹³C values are not well documented for carbon dioxide. Botz et al. (Reference Botz, Pokojski, Schmitt and Thomm1996) reported δ¹³C values up to –49.7‰ for CO₂ emitted during biologic methane formation and Whiticar (1999) indicated values up to –46‰ for CO₂ produced by methane oxidation. As gas generated by the degradation of organic matter in manure contains both methane and carbon dioxide (Wartell et al. Reference Wartell, Krumins, Alt, Kang, Schwab and Fennell2012), the low δ¹³C values obtained for cerussite probably reflect the fermentation process. A direct analysis of the δ¹³C of gas would be necessary to confirm this hypothesis.

¹⁴C Dates for Lead White (Cerussite)

When cerussites were produced from acetic acid and/or fossil CO₂ (setups 3, 5, 6), apparent old ages were found due to the presence of dead carbon in the initial ingredients. The calculation of absolute dates is therefore not relevant in these cases.

For cerussite produced according to the process described in the ancient recipes using natural vinegar and horse manure (setup 4), the ¹⁴C content was converted into calendar dates using the post-bomb atmospheric NH1 21 calibration curve (recorded up to 2019 only). Two dates were obtained due to the shape of the bomb peak: 1955 and 2017-… Despite the limited expansion of the calibration curve, the second interval can be considered to be in agreement with the manufacturing date in 2020. This result is consistent with the level of ¹⁴C recorded in the atmosphere for this given year.

Together with the pioneering works of Hendriks et al. (Reference Hendriks, Hajdas, Ferreira, Scherrer, Zumbuhl and Kuffner2019) and Beck et al. (Reference Beck, Messager, Coelho, Caffy, Delqué-Količ, Perron, Mussard, Dumoulin, Moreau and Gonzalez2019) on other lead white reproductions, this result demonstrates that the radiocarbon dates for these pigments produced following the historical corrosion process are accurate and meaningful.