Hostname: page-component-848d4c4894-v5vhk Total loading time: 0 Render date: 2024-06-23T05:58:38.417Z Has data issue: false hasContentIssue false
  • English
  • Français

DATING OF WOODEN HERITAGE OBJECTS IN THE GLIWICE 14C AND MASS SPECTROMETRY LABORATORY

Published online by Cambridge University Press:  31 October 2023

Natalia Piotrowska Open the ORCID record for Natalia Piotrowska [Opens in a new window] ,
Marzena Kłusek Open the ORCID record for Marzena Kłusek [Opens in a new window] ,
Piotr Boroń ,
Ewelina Imiołczyk Open the ORCID record for Ewelina Imiołczyk [Opens in a new window] ,
Mateusz Budziakowski ,
Adrian Poloczek ,
Agata Poloczek-Imielińska  and
Marian Jaksik
Natalia Piotrowska*
Affiliation:
Silesian University of Technology, Institute of Physics - CSE, Division of Geochronology and Environmental Isotopes, Gliwice, Poland
Marzena Kłusek
Affiliation:
Silesian University of Technology, Institute of Physics - CSE, Division of Geochronology and Environmental Isotopes, Gliwice, Poland
Piotr Boroń
Affiliation:
University of Silesia, Faculty of Humanities, Katowice, Poland
Ewelina Imiołczyk
Affiliation:
Upper Silesian Museum, Department of Archaeology, Bytom, Poland
Mateusz Budziakowski
Affiliation:
Tadeusz Kosciuszko Cracow University of Technology, Faculty of Architecture, Krakow, Poland
Adrian Poloczek
Affiliation:
RECO Conservation of Monuments Ltd., Katowice, Poland
Agata Poloczek-Imielińska
Affiliation:
RECO Conservation of Monuments Ltd., Katowice, Poland
Marian Jaksik
Affiliation:
RECO Conservation of Monuments Ltd., Katowice, Poland
*
*Corresponding author. Email: Natalia.Piotrowska@polsl.pl
Rights & Permissions [Opens in a new window]

Abstract

We present case studies on three objects of high importance for cultural heritage in southern Poland, dated in years 2018–2022 at the Gliwice 14C and Mass Spectrometry Laboratory with radiocarbon (14C) and dendrochronology methods. The first was a richly ornamented wooden cane, discovered during excavations on the market in Bytom city. The cane can be associated with medieval court proceedings. The archaeological context indicates the 13th century AD, and the 14C result corresponds perfectly with this time, confirming that it is the oldest object of this type in Poland. The second was a 4-m-tall oak column from St. Leonard Church in Lipnica Murowana, a UNESCO heritage site. The local story said it was previously devoted to Światowid, a pagan deity. Our analysis excluded the pre-Christian age, as the tree was felled no earlier than the late 15th century, which is in agreement with historical records. The third was a wooden Saint Lawrence Church in Bobrowniki. The presbytery was covered with up to five layers of polychromic paintings, some of high artistic value. We dated three samples from the original wooden board, and by wiggle-matching, the calibrated age interval was narrowed to 1731–1754 cal AD.

Keywords

dendrochronologyheritageradiocarbon datingwood
Type
Conference Paper
Information
Radiocarbon , First View , pp. 1 - 13
Check for updates
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, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of University of Arizona

INTRODUCTION

The trees as annually resolved archives form an inexhaustible resource of datasets for many branches of Earth and environmental science. Dendrochronology, derived from wood biology, is the science whose primary task is the dating of wood (Ważny Reference Ważny2001). Radiocarbon (14C) dating and dendrochronology have been linked since the first steps of the 14C method, and the history of this symbiosis was recently reviewed by Pearson et al. (Reference Pearson, Leavitt, Kromer, Solanki and Usoskin2022). From the radiocarbon perspective, tree rings investigations enabled the reconstruction of past 14C content necessary for calibration of radiocarbon dates (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Ramsey, Butzin, Cheng, Edwards and Friedrich2020; van der Plicht et al. Reference van der Plicht, Bronk Ramsey, Heaton, Scott and Talamo2020; Hua et al. Reference Hua, Turnbull, Santos, Rakowski, Ancapichún, De Pol-Holz, Hammer, Lehman, Levin, Miller, Palmer and Turney2022), provided the insight into the carbon cycle on the Earth (e.g., Levin and Hesshaimer Reference Levin and Hesshaimer2000) and delivered data on changing astronomical variables such as cosmic ray intensity (Miyake et al. Reference Miyake, Nagaya, Masuda and Nakamura2012). 14C concentration in growth-rings were explored as records of environmental and climatic conditions (e.g., Pazdur et al. Reference Pazdur, Nakamura, Pawełczyk, Pawlyta, Piotrowska, Rakowski, Sensuła and Szczepanek2007) as well as anthropogenic influence on the environment (e.g., Ežerinskis et al. Reference Ežerinskis, Šapolaitė, Pabedinskas, Juodis, Garbaras, Maceika, Druteikienė, Lukauskas and Remeikis2018; Sensuła et al. Reference Sensuła, Michczyński, Piotrowska and Wilczyński2018; Kontuľ et al. Reference Kontuľ, Povinec, Richtáriková, Svetlik and Šivo2022).

The age determination of wooden objects of heritage was one of the first reported applications of the radiocarbon method, forming the famous “curve of knowns” by Libby (Reference Libby1961). Radiocarbon dating of wooden archaeological samples was also performed in the 14C and Mass Spectrometry Laboratory in Gliwice since its early days (Mościcki and Zastawny Reference Moscicki and Zastawny1976). Many studies have demonstrated a successful approach in obtaining accurate ages of wooden objects, however, the results need to be treated with caution. The 14C method provides the age of tree felling, and not the age of any work performed like sculpting, forming or using for construction. The development of accelerator mass spectrometry technique (AMS), which allowed the loss of material necessary for this destructive analysis to be minimized, significantly enhanced 14C dating on precious cultural heritage objects. In particular, when 14C supported by dendrochronology allowed application of wiggle-matching procedures, performed with use of the Bayesian analysis (Bronk Ramsey et al. Reference Bronk Ramsey, van der Plicht and Weninger2001), the high precision and reliability was reached (e.g., Quarta et al. Reference Quarta, Pezzo, Marconi, Tecchiati, D’Elia and Calcagnile2010; Fukuyo et al. Reference Fukuyo, Yokoyama, Miyairi and Igarashi2019; Matskovsky et al. Reference Matskovsky, Gadiev, Dolgikh, Cherkinsky, Polumieva, Panov, Kudikov, Lomakin and Dolgova2019). However, ethical issues arise with respect to the authentication of such objects, particularly those in private possession or destined for the market (Huysecom et al. Reference Huysecom, Hajdas, Renold, Synal and Mayor2017). Following UNESCO conventions on heritage objects, the 14C and Mass Spectrometry Laboratory in Gliwice follows the recommendations for diligence protocol formulated by Hajdas et al. (Reference Hajdas, Jull, Huysecom, Mayor, Renold, Synal, Hatté, Hong, Chivall, Beck, Liccioli, Fedi, Friedrich, Maspero and Sava2019). In all cases, the samples were collected following proper allowances and in the presence of persons representing interested parties: architects, historians, conservators, museum curators and representatives of the Catholic Church, whichever was applicable. They provided knowledge of the historical context and expertise in interpretation of results, and most of them coauthor this manuscript. Presented case study describes radiocarbon and dendrochronological dating of three wooden objects of significant cultural heritage. These objects are from the area of southern Poland and their analyses were conducted between AD 2018 and 2022 at the Gliwice 14C and Mass Spectrometry Laboratory.

CONTEXT OF THE SAMPLES

Cane from Bytom Market

The richly ornamented wooden cane was discovered in AD 1998 during archaeological excavations on the main market in Bytom city (Upper Silesia, 50°20′54″N 18°54′56″E), founded in AD 1254 under German law. The cane was found in a Trench No. 1, measuring 9.5 by 38 m, in Layer No. XIII, Bedding No. IV, with a large accumulation of antiquities, including numerous wooden objects. The Bedding No. IV was placed on a clay floor and covered with a thin insulating layer made up of small twigs and wood chips. This layer was overlaid with chopped wood branches, forming a compact surface of the medieval market place. Three alternating layers of clay, sand, gravels, and paving stones were located above Bedding No. IV, up to the latest cobblestone surface. The archaeological context implies that Layer No. XIII corresponds to the 13th century AD, when small wooden stalls were in use. Accurate dating of these objects was possible due to previous dendrochronological studies of structural elements and analysis of collected movable relics, as summarized by Andrzejewska (Reference Andrzejewska and Antiqua2000).

The cane is 57.7 cm long and has a diameter of 2.9 cm by the ornament. Two distinct incisions, most probably intentionally made, caused a cavity in ca. 1/3 of the length (see Figure 1A). The cane is supposed to have been used in court proceedings in the Germanic law circle, and the cuts were aimed at weakening the cane for easier breakage. Historical sources document the judge’s practice to break the cane (named Rechtsstab, Gerchichtsstab) over the head of the accused at the time of the sentence.

Figure 1 Sampling details with sample position indicated by dotted ellipses and laboratory numbers; (A) wooden cane from Bytom; complete cane and sampling area; (B) oak column from Lipnica Murowana: sketch of the column, drilling point and increment core with indicated tree rings boundaries; (C) wooden board from Bobrowniki: front view with paint, fragment of back and view on the polished side (marked in light green) and previous LSC 14C date.

The cane is currently displayed for the public at the Museum of Upper Silesia, Department of Archaeology, Bytom. For sampling, it was brought to 14C Laboratory, examined visually, photographed, and a piece of wood (1.68 g; GdA-6743) was cut with a knife from the area near the incisions (Figure 1A). Further interference in cane, for example, cutting, polishing, or drilling, was omitted to protect the object; thus the number of tree rings sampled remains unknown.

Column from Church of St. Leonard in Lipnica Murowana

Lipnica Murowana town (Lesser Poland region, 49°51′28″N 20°31′45″E) was founded in AD 1326 by king Władysław Łokietek. However, an ecclesiastical organization have been functioning in the area for much longer, and some sources suggest even half of the 12th century. Several precious cultural heritage sites located in Lipnica Murowana have survived to our time, including the timber Church of St. Leonard, which is a UNESCO World Heritage Site since AD 2003. The thorough renovation of the church was carried out in the 1950s and currently it is in an excellent state of preservation.

The detailed description and 3-D scans of the church are provided by Budziakowski et al. (Reference Budziakowski, Piotrowska and Kłusek2020). In brief, the church was constructed as a timber building with wooden log walls placed on a stone base, and a steep roof. The interior space was covered with a flat, timber decks with coffers to its sides. The decks were painted and feature rich ornamentation. The main altar originates from the beginning of the 16th century and was furnished with a triptych painting depicting the church’s patron, St. Leonard of Limoges, along with St. Lawrence of Rome and St. Florian, and side panels illustrating scenes from the saint’s life. The back side of the altar is supported by 4-m-tall oak trunk with a rounded top (Figure 1B). At the base the altar and column are affixed with metal braces. Several cuts on the column can be observed: a wedge-shaped cut near the top, carvings depicting rosettes. A socket in the upper part may be supposed to be used to affix a horizontal beam, which indicates the object had been a cross or an element of a larger structure previously. The column lacks other symbols or ornaments, particularly any that could be linked with a pre-Christian culture. Nevertheless, the local story associated with the church states that a column was reportedly an element from an older Slavic shrine and was to depict or symbolize the figure of a Slavic deity called Światowid.

The column was sampled on site with an increment borer in AD 2018, and the 5-mm-diameter core was extracted, measuring ca. 12 cm in length. The dendrological analyzes indicated that the core comprised 16 tree rings. In order to avoid potential contamination of the external layer, 14C dating was performed using a fragment of the internal part of the core, which encompassed two incomplete rings (Figure 1B; GdA-5702). Unfortunately, for such a short sequence, the dendrochronological matching with a reference chronology was not possible. The results formed part of the Budziakowski et al. (Reference Budziakowski, Piotrowska and Kłusek2020) publication aimed at the architecture scientist, and we aim here to present this interesting case study to a wider radiocarbon community.

Board from Saint Lawrence Church in Bobrowniki

Bobrowniki village was founded in AD 1273 in the Upper Silesia (50°22′48″N 18°59′41″E). Saint Lawrence Church located there is a unique wooden church with two towers. The earliest notes about its existence come from AD 1619, and the inscription on the ceiling beam states, “Built in 1669, restored in 1857.” The church has a complicated renovation history, part of which remains undiscovered, with most pronounce reconstructions made in 19th century, when the wood coming from 16th century was reused for wall building (Konieczny Reference Konieczny and Klajmon2010), and the two towers were erected. The presbytery of the church is constructed by wooden boards covered by five layers of polychromic paintings, which are an object of ongoing conservation works (Poloczek-Imielińska 2021). The boards do not show any features indicating on being reused material—they are well fitted, the junctions are precise without any shifts or damage, and the first polychromic layer shows stylistic continuity, as far as it was discovered. The following second layer is poorly preserved and also shows some figures, which was covered by third painting. This one was made in AD 1923 by Otto Kowalewski, a renowned Silesian painter, as documented by the signature and date placed by one of the paintings and also was present on a photograph taken in AD 1930 (Poloczek-Imielińska 2021). This layer is also in a poor state of preservation and was covered in 20th century by two further paint layers without figures, and of relatively low artistic value.

This oldest layer is in the best state of preservation, and of the highest artistic value. The exposed fragments show baroque polychrome paintings, which may come from ca. 17th century, or else be baroque-styled 19th century works. The analyzes of pigments from the first layer were inconclusive, reported as “non-dating,” meaning used from the antiquity. The first attempt to radiocarbon dating a fragment of wooden board in AD 2011 with LSC technique yielded a wide range of possible calibrated ages (see Table 1 and Figure 4), and the present study was aimed at narrowing this range.

Table 1 Results of radiocarbon dating and calibrated age ranges for independent and modeled dates.

An original wooden board from the presbytery was removed and brought to the 14C Laboratory for subsampling. The cross section surface of the wood of the board was polished, revealing a tree-ring structure which allowed to the determination of their number and width. Three samples were taken for 14C dating (Figure 1 C): Board 1 (GdA-6744) comprised 3 rings followed by a gap of 9 rings, Board 2 (GdA-6745) comprised 4 rings, followed by a gap of 15 rings, and Board 3 (GdA-6746) comprised 3 rings. The weights of the samples were respectively: 630.62 mg, 807.52 mg, 619.42 mg.

METHODS

The wood samples were subjected to chemical preparation to obtain pure cellulose, taking into account the individual sample conditions and in general following the procedures described by Michczyńska et al. (Reference Michczyńska, Krąpiec, Michczyński, Pawlyta, Goslar, Nawrocka, Piotrowska, Szychowska-Krąpiec, Waliszewska and Zborowska2018). Overall, the preservation state of all samples examined was very good, in particular, for the oak wood of the Lipnica column (GdA-5702).

All samples have been shredded with a scalpel to small pieces (1–2 mm in size). Contamination with preservatives and/or paint could not be excluded for cane (GdA-6743) and board (GdA-6744, 6745, 6746) samples, so Soxhlet extraction was applied using a sequence of toluene-ethanol (equal in volume), ethanol, and demineralized water washes. In case of oak from Lipnica column (GdA-5702), the Soxhlet treatment was omitted, as the danger of contamination was very low for a sample taken at a distance of 11 cm from the surface of this solid and hard trunk. Subsequently, NaOH mercerization (4%, 12 hr, 75ºC) was applied, followed by a regular ABA protocol (4% HCl, 1 hr, 75ºC; 4% NaOH, 1 hr, 75ºC; 4% HCl, 1 hr, 75°C) with demineralized water washes between steps. Bleaching was carried out in two steps: first with NaClO2 + HCl at pH = 2 (2 hr, 75ºC) and the second in the same solution and time, but including 15 min in an ultrasonic bath. In this way, fine homogeneous holo-cellulose fibers were obtained, which were dried in an oven (75°C). In the case of Lipnica sample (GdA-5702) the preparation was extended by two additional NaOH treatments (10% NaOH, 45 min, 70ºC; 17% NaOH 45 min, room temperature, ultrasonic bath) to obtain alpha-cellulose.

For combustion, ca. 3.5 mg of each cellulose was weighted, packed in a tin boat, and introduced to the VarioMicro elemental analyzer (Elementar TM) coupled to the AGE-3 graphitization system (Wacker et al. Reference Wacker, Němec and Bourquin2010). Reference materials: Oxalic Acid II and background samples (coal and old wood beyond the 14C range) were prepared in the same way, analyzed in the same batch, and used for calculations. All samples yielded amount of material sufficient to prepare standard cathodes with 1 mg of carbon. Radiocarbon concentration measurements were performed at the Poznań Radiocarbon Laboratory using the NEC 0.5MV Compact Carbon AMS (Goslar et al. Reference Goslar, Czernik and Goslar2004). Radiocarbon results were calibrated with use of OxCal v4 software (Bronk Ramsey Reference Bronk Ramsey2009) and IntCal20 calibration curve (Reimer et al. Reference Reimer, Austin, Bard, Bayliss, Blackwell, Ramsey, Butzin, Cheng, Edwards and Friedrich2020).

The samples were observed under the Zeiss Stemi 305 trino microscope (coupled with the Axiocam 208 color) to determine the taxonomic affiliation of the wood. For the wooden board from the Bobrowniki church, dendrochronological examinations were performed using LinTabTM equipment and TSAP-WinTM software (Rinn Reference Rinn2003). The obtained measurement sequences of growth-ring width were compared with available master chronologies.

RESULTS AND DISCUSSION

The result obtained for all samples are summarized in Table 1 and presented in Figures 24.

Figure 2 Calibration of 14C date obtained for yew cane from Bytom.

Figure 3 Calibration results for GdA-5702 Lipnica 1: probability distribution of the original date, date shifted by 26 ± 7 calendar years and the age of the altar construction, assumed as AD 1510 ± 10.

Figure 4 Probability distribution of calibrated ages for 14C-dated samples from Bobrowniki before modeling with D_Sequence (light gray) and after (dark gray). (A) Plotted on the background of calibration curve. (B) Details and results of D_Sequence analyzes compared with calendar ages determined by dendrochronology.

The Cane from Bytom

Dendrological analysis allowed identification of the species as yew wood (Taxus baccata L.), which is strong and flexible, yet durable and resistant to moisture. The use of this species was common, and the choice may have been intentional with a symbolic meaning.

Radiocarbon dating result for GdA-6743 was 720 ± 30 BP, and the calibrated age range at 1σ level was 1271–1296 cal AD (Figure 2). Previous dendrochronological analysis of 12 fir trunks was performed by M. Krąpiec (as reported by Andrzejewska Reference Andrzejewska and Antiqua2000). These trunks were used in construction of the medieval drainage ditch and years the trees were felled were determined from AD 1272 to AD 1294. Therefore, the age 1271–1296 cal AD is in a perfect agreement with archeological context of the Layer No. XIII.

The Column from Lipnica Murowana

The radiocarbon date of 370 ± 25 BP was determined for the GdA-5702 sample. However, the dated material was collected from the internal part of the trunk, and the age obtained did not correspond to the age the tree was felled, which was at least 14 years later than indicated by the measurement results. Furthermore, the external part of the trunk was cut during carpentry work. The unknown number of rings that were removed must have included a sapwood layer, which in the case of oak trees from Lesser Poland covers 12 +7/–6 rings (Zielski and Krąpiec Reference Zielski and Krąpiec2004). In summary, the age of the tree felling must have been later by at least 26 ± 7 years relative to the date result. This correction was added during calibration as a normal distribution, and the results are presented in Figure 3.

For comparison, the date of the altar’s construction is plotted, assumed to be AD 1510 with an uncertainty of 10 years. Due to the wiggle in the calibration curve, the probability distribution of the calendar age of the date of the tree fall has two distinct ranges, the first indicating the late 15th to half of the 16th century AD and the second the first half of the 17th century AD. The earlier age range is more probable in light of historical records. As such, the analysis excluded the legendary pre-Christian provenience of the column and its relation to the Światowid deity—if this were to be true, the oak must have been a few hundred years older.

The Saint Lawrence Church in Bobrowniki

The dendrochronological analysis of the board confirmed that it was made of pine wood. The whole sequence covered 71 tree rings (see Figure 1 C). The sequence was matched to three different pine master chronologies, and all attempts gave the same results, i.e., AD 1746–1816 for the whole sequence with acceptable correlation coefficient (TV=5.4, TVBP = 4.1, TVH = 3.6). The sample Board 1 (GdA-6744) composed of 3 rings was dated to AD 1749–1751, Board 2 (GdA-6745) composed of 4 rings dated to AD 1760–1763, and Board 3 (GdA-6746) composed of 3 rings dated to AD 1778–1780.

As expected from the previous dating and the historical context, all the 14C ages fell into a period of pronounced wiggles in the calibration curve, resulting in multiple calibrated age ranges, extending in total to over 200 years (Table 1; Figure 4A). The additional information from dendrochronological data on the number of tree rings between dated samples was added using D_Sequence function in OxCal (Bronk Ramsey et al. Reference Bronk Ramsey, van der Plicht and Weninger2001). Statistical indicators confirm that the model assumptions are fulfilled by the analysis results to an acceptable degree, as all individual agreement indices exceed the threshold of 60% and the combination agreement index A comb = 68.1% exceeds the acceptance threshold of 40.8% (Table 1; Figure 4B).

At the same time, the results reveal two relatively narrow but clearly separated calendar age ranges, which for 68.3% probability are: 1731–1754 cal AD (36.1%), and 1925–1952 cal AD (32.2%). For 95.4% probability the ranges are wider but cover roughly the same periods: second half of 18th century or first half of 20th century. In addition, with a minor probability (2.7%) the age may be from 1854–1878 cal AD. However, the third layer of polychrome painting was undoubtedly documented to have been created by Otto Kowalewski in AD 1923, which implies the 20th century age range should be excluded.

CONCLUSIONS

In all presented cases, the radiocarbon and dendrochronological analyses showed a synergy leading to enhanced knowledge about the dated objects. For the cane from Bytom, the dendrochronological analysis was not possible; however, the species identification as a yew tree provided useful historical information, which will be further explored. In case of the column from Lipnica Murowana, the scientific results excluded a legendary story of its provenance, although it cannot be expected to erase already existing regional beliefs. The most spectacular success was achieved for 14C wiggle-matching procedure applied to the board from Bobrowniki church, where by adding the information about dendrochronological sequence and historical records the calibrated age interval was spectacularly narrowed from 1650–1950 cal AD to 1731–1754 cal AD. While the range borders are provided with single-year precision, it should not be overestimated, being a result of Bayesian modeling. Moreover, this interval is shaped by the calibration curve, which may be adjusted in the future. Even though, the middle 18th century should remain the most accurate age of the wooden board.

ACKNOWLEDGMENTS

The research was supported by the SUT subsidy for the maintenance and development of research potential for years 2018-2022. Publication was supported under the Rector’s pro-quality grants to NP: Silesian University of Technology, no 14/020/RGJ22/0019 and 14/020/SDU/10-05-01. Publication supported under the Rector's Professorship Grant to N.Piotrowska, Silesian University of Technology no 14/020/RGP21/0015.

Footnotes

Selected Papers from the 24th Radiocarbon and 10th Radiocarbon & Archaeology International Conferences, Zurich, Switzerland, 11–16 Sept. 2022

References

REFERENCES

Andrzejewska, A. 2000. Spatial layout of the medieval and modern Bytom market in the light of the latest archaeological research. In: Antiqua, Wratislavia, vol. 2, Medieval Silesia and Czechia. The center of the medieval city. Wroclaw and Central Europe. p. 279288. In Polish.Google Scholar
Bronk Ramsey, C. 2009. Bayesian analysis of radiocarbon dates. Radiocarbon 51(1):337360. doi: 10.1017/S0033822200033865 CrossRefGoogle Scholar
Bronk Ramsey, C, van der Plicht, J, Weninger, B. 2001. “Wiggle matching” radiocarbon dates. Radiocarbon 43(2A):381389. doi: 10.1017/S0033822200038248 CrossRefGoogle Scholar
Budziakowski, M, Piotrowska, N, Kłusek, M. 2020. Church of St. Leonard in Lipnica Murowana—analysis of historic substance—selected issues. Wiadomości Konserwatorskie – Journal of Heritage Conservation 62:136147.Google Scholar
Ežerinskis, Ž, Šapolaitė, J, Pabedinskas, A, Juodis, L, Garbaras, A, Maceika, E, Druteikienė, R, Lukauskas, D, Remeikis, V. 2018. Annual variations of 14C concentration in the tree rings in the vicinity of Ignalina nuclear power plant. Radiocarbon 60(4):12271236. doi: 10.1017/RDC.2018.44 CrossRefGoogle Scholar
Fukuyo, N, Yokoyama, Y, Miyairi, Y, Igarashi, Y. 2019. AMS dating of potentially the oldest wooden sculptures in Japan from a Shinto Shrine in Akita. Radiocarbon 61(5):12211228. doi: 10.1017/RDC.2019.31 CrossRefGoogle Scholar
Goslar, T, Czernik, J, Goslar, E. 2004. Low-energy 14C AMS in Poznań Radiocarbon Laboratory, Poland. Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms 223–224:511. doi.org/10.1016/j.nimb.2004.04.005 CrossRefGoogle Scholar
Hajdas, I, Jull, AJT, Huysecom, E, Mayor, A, Renold, M-A, Synal, H-A, Hatté, C, Hong, W, Chivall, D, Beck, L, Liccioli, L, Fedi, M, Friedrich, R, Maspero, F, Sava, T. 2019. Radiocarbon dating and the protection of cultural heritage. Radiocarbon 61(5):11331134. doi: 10.1017/RDC.2019.100 CrossRefGoogle Scholar
Hua, Q, Turnbull, JC, Santos, GM, Rakowski, AZ, Ancapichún, S, De Pol-Holz, R, Hammer, S, Lehman, SJ, Levin, I, Miller, JB, Palmer, JG, Turney, CSM. 2022. Atmospheric radiocarbon for the period 1950–2019. Radiocarbon 64(4):723745. doi: 10.1017/RDC.2021.95 CrossRefGoogle Scholar
Huysecom, E, Hajdas, I, Renold, M-A, Synal, H-A, Mayor, A. 2017. The “enhancement” of cultural heritage by AMS dating: ethical questions and practical proposals. Radiocarbon 59(2):559563. doi: 10.1017/RDC.2016.79 CrossRefGoogle Scholar
Konieczny, A. 2010. Dendrochronological studies of historic wooden churches in the Silesian Voivodship in 2009. In: Klajmon, B. Conservation News of the Silesian Voivodeship vol.2: Castles and Palaces, 185210. In Polish.Google Scholar
Kontuľ, I, Povinec, PP, Richtáriková, M, Svetlik, I, Šivo, A. 2022. Tree rings as archives of atmospheric pollution by fossil carbon dioxide in Bratislava. Radiocarbon 64(6):15771585. doi: 10.1017/RDC.2022.95 CrossRefGoogle Scholar
Levin, I, Hesshaimer, V. 2000. Radiocarbon—a unique tracer of global carbon cycle dynamics. Radiocarbon 42(1):6980. doi: 10.1017/S0033822200053066 CrossRefGoogle Scholar
Libby, WF. 1961. Radiocarbon dating. Science 133:621629.CrossRefGoogle ScholarPubMed
Matskovsky, V, Gadiev, U, Dolgikh, A, Cherkinsky, A, Polumieva, P, Panov, V, Kudikov, A, Lomakin, N, Dolgova, E. 2019. Radiocarbon dating of medieval buildings in the mountainous part of Ingushetia (Northern Caucasus, Russia). Radiocarbon 61(3):777797. doi: 10.1017/RDC.2019.33 CrossRefGoogle Scholar
Michczyńska, DJ, Krąpiec, M, Michczyński, A, Pawlyta, J, Goslar, T, Nawrocka, N, Piotrowska, N, Szychowska-Krąpiec, E, Waliszewska, B, Zborowska, M. 2018. Different pretreatment methods for 14C dating of Younger Dryas and Allerød pine wood (Pinus sylvestris L.). Quaternary Geochronology 48:3844. doi.org/10.1016/j.quageo.2018.07.013 CrossRefGoogle Scholar
Miyake, F, Nagaya, K, Masuda, K, Nakamura, T. 2012. A signature of cosmic-ray increases in AD 774–775 from tree rings in Japan. Nature 486(7402):240242. dx.doi.org/10.1038/nature11123 CrossRefGoogle ScholarPubMed
Moscicki, W, Zastawny, A. 1976. Gliwice (Gdansk) Radiocarbon Dates III. Radiocarbon 18(1):5059. doi: 10.1017/S0033822200002368 CrossRefGoogle Scholar
Pazdur, A, Nakamura, T, Pawełczyk, S, Pawlyta, J, Piotrowska, N, Rakowski, A, Sensuła, B, Szczepanek, M. 2007. Carbon isotopes in tree rings: climate and the Suess effect interferences in the last 400 years. Radiocarbon 49(2):775788. doi: 10.1017/S003382220004265X CrossRefGoogle Scholar
Pearson, CL, Leavitt, SW, Kromer, B, Solanki, SK, Usoskin, I. 2022. Dendrochronology and radiocarbon dating. Radiocarbon 64(3):569588. doi: 10.1017/RDC.2021.97 CrossRefGoogle Scholar
Poloczek-Imielińska A. 2021. Research and uncovering of paintings in the interior of the wooden church of St. Lawrence in Bobrowniki (Będzin district). Conservation News of the Silesian Voivodeship 13:340348. In Polish.Google Scholar
Quarta, G, Pezzo, MI, Marconi, S, Tecchiati, U, D’Elia, M, Calcagnile, L. 2010. Wiggle-match dating of wooden samples from Iron Age sites in Northern Italy. Radiocarbon 52(3):915923. doi: 10.1017/S0033822200046014 CrossRefGoogle Scholar
Reimer, PJ, Austin, WEN, Bard, E, Bayliss, A, Blackwell, PG, Ramsey, CB, Butzin, M, Cheng, H, Edwards, RL, Friedrich, M, et al. 2020. 2020. The IntCal20 Northern Hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon 62(4):725757. doi: 10.1017/RDC.2020.41 CrossRefGoogle Scholar
Rinn, F. 2003. TSAP-Win Professional timeseries analysis and presentation for dendrochronology and related applications, Version 0.3. User reference. http://www.rinntech.com. Heidelberg, Germany.Google Scholar
Sensuła, B, Michczyński, A, Piotrowska, N, Wilczyński, S. 2018. Anthropogenic CO2 emission records in scots pine growing in the most industrialized region of Poland from 1975 to 2014. Radiocarbon 60(4):10411053. doi: 10.1017/RDC.2018.59 CrossRefGoogle Scholar
van der Plicht, J, Bronk Ramsey, C, Heaton, TJ, Scott, EM, Talamo, S. 2020. Recent developments in calibration for archaeological and environmental samples. Radiocarbon 62(4):10951117. doi: 10.1017/RDC.2020.22 CrossRefGoogle Scholar
Wacker, L, Němec, M, Bourquin, J. 2010. A revolutionary graphitisation system: fully automated, compact and simple. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 268(7–8):931934. doi: 10.1016/J.NIMB.2009.10.067 CrossRefGoogle Scholar
Ważny, T. 2001. Dendrochronology of historical objects in Poland. Archaeological Museum in Gdansk. 137 p. In Polish.Google Scholar
Zielski, A, Krąpiec, M. 2004. Dendrochronology. Warsaw: Wydawnictwo Naukowe PWN. In Polish.Google Scholar
Figure 0

Figure 1 Sampling details with sample position indicated by dotted ellipses and laboratory numbers; (A) wooden cane from Bytom; complete cane and sampling area; (B) oak column from Lipnica Murowana: sketch of the column, drilling point and increment core with indicated tree rings boundaries; (C) wooden board from Bobrowniki: front view with paint, fragment of back and view on the polished side (marked in light green) and previous LSC 14C date.

Figure 1

Table 1 Results of radiocarbon dating and calibrated age ranges for independent and modeled dates.

Figure 2

Figure 2 Calibration of 14C date obtained for yew cane from Bytom.

Figure 3

Figure 3 Calibration results for GdA-5702 Lipnica 1: probability distribution of the original date, date shifted by 26 ± 7 calendar years and the age of the altar construction, assumed as AD 1510 ± 10.

Figure 4

Figure 4 Probability distribution of calibrated ages for 14C-dated samples from Bobrowniki before modeling with D_Sequence (light gray) and after (dark gray). (A) Plotted on the background of calibration curve. (B) Details and results of D_Sequence analyzes compared with calendar ages determined by dendrochronology.