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Official Journal of the Japan Wood Research Society

Synchronizations of tree-ring δ18O time series within and between tree species and provinces in Korea: a case study using dominant tree species in high elevations

Abstract

The current study was initiated to test the synchronizations of tree-ring δ18O (hereafter δ18OTR) time series within and between tree species and provinces, which are about 144 km apart from each other in Korea. For the test, a 50-year δ18OTR time series (1966–2015) was developed using four trees from each tree species which are Pinus densiflora and Quercus mongolica from Songnisan National Park and Taxus cuspidata, Pinus koraiensis, Abies koreana, and Quercus mongolica from Jirisan National Park. Their synchronizations were evaluated using t-value, Gleichläufigkeit (Glk), and Expressed Population Signal (EPS). The mean t-values and Glk scores within the tree species ranged 5.2–11.2 (p < 0.05) and 69–83%, and between the tree species ranged 6.1–13.2 (p < 0.05) and 73–81%, respectively. The mean t-value and Glk score between the regions were 4.3 (p < 0.05) and 72%, respectively. Furthermore, the EPS showed higher than 0.85, which is the generally accepted threshold value in dendrochronology, except for Q. mongolica at Songnisan National Park for which the value is 0.83 calculated by only two δ18OTR time series. Based on the statistical results, we concluded that a δ18OTR chronology established using more than four trees could serve as a promising reference for dating an undated wood without considering the tree species, as well as for research on climate in the past.

Introduction

Tree-ring dating is an accepted scientific method to determine the exact year when a ring was formed [1]. The tree-ring dating not only plays an important role in dating archaeological wooden materials [2,3,4,5], but also in investigating the climatic and environmental conditions during the dated years [6,7,8,9,10].

Dendrochronology was introduced in the Republic of Korea in the early 1990s [11, 12], whereas the first paper on dating archaeological woods using the tree-ring dating method was published in the early 2000s [13]. Due to difficulty in obtaining permission to collect tree-ring samples from archaeological woods and lack of long local tree-ring chronologies for dating, it took some time to publish research work related to dendroarchaeological dating. Although a 893-year-long (1126–2018 CE) ring-width chronology was established through many dated archaeological woods of Pinus densiflora (known as the red pine), which has been used to date as the most common archaeological woods in Korea [14,15,16], long chronologies have not yet been established using other tree species from various regions. Various local master chronologies comprising different tree species from different regions are required for successful tree-ring dating, because the annual patterns of the ring widths vary depending on the tree species and locations. To this end, archaeological woods containing various tree species need to be found in archaeological relics, buildings, and artifacts, which cover long time range without any interruption. According to past studies [17,18,19,20], tree species used for buildings, Buddhist statues, furniture and charcoals were different in some cases with respect to time and region in the Republic of Korea. Due to a lack of long local master chronologies for various tree species, most studies on dating archaeological woods rely on the radiocarbon dating method [21,22,23].

With the help of developed equipment, measured values of different cell traits, such as cell size, wall thickness and density [9, 24, 25], and stable isotopes such as carbon and oxygen [26,27,28,29] were used to establish inter-annual time series for dendrochronological research. Among them, the tree-ring δ18O time series, which has been established using the ratios between 18O and 16O for each year, is considered as a reliable reference chronology, and has been used in dating tree-ring δ18O time series without considering the tree species [30, 31]. For instance, Li et al. [32] published that tree-ring δ18O time series from pine and oak trees under similar growing conditions in Japan showed well synchronization. Furthermore, Jessica et al. [33] reported that tree-ring δ18O time series established within 1000 km in Bolivia also showed good correlations. Apart from such attractive advantage, a tree-ring δ18O chronology, established using a lesser number of trees than the other measurement parameters, can play a role as a reliable proxy representing a potential climate signal at a site [30, 34, 35]. Recently, we verified the synchronizations of tree-ring δ18O time series between different tree species, viz. Pinus densiflora, Abies koreana, Taxus cuspidata, and Quercus mongolica, from Jirisan National Park in Korea, by using four trees per tree species [36]. This study was conducted only at a single site, and therefore, it does not suffice for application of the tree-ring δ18O chronology for cross-dating and/or dating tree-ring δ18O time series for other regions.

In the current study, we aimed to test synchronizations of tree-ring δ18O (hereafter δ18OTR) time series within and between tree species and provinces in the Republic of Korea. The results are expected to offer useful tips to the dendrologists who lack the necessary resources for reliable dating of archaeological woods using ring-width data, and those who are interested in investigating the past climate of Korea.

Materials and methods

Study sites and tree species

Wood samples from living trees were collected at Songnisan (36˚ 33ʹ N, 127˚ 51ʹ E) and Jirisan (35˚ 17–20ʹ N, 127˚ 32–43ʹ E) National Parks which are located at the central and southern provinces of the Republic of Korea, respectively (Fig. 1). The highest peaks of Songnisan and Jirisan National Parks are 1029 m a.s.l. and 1915 m a.s.l., respectively. The Songnisan National Park is about 144 km away to the north from Jirisan National Park.

Fig. 1
figure 1

Locations of the sampling sites (triangles) and the meteorological stations (open circles) close to the sampling sites (SN: Songnisan National Park, JR: Jirisan National Park)

In order to establish tree-ring δ18O (hereafter δ18OTR) time series, 24 tree-ring samples were selected from archived increment cores at Tree-Ring Research Center (www.dendro.kr) at the Chungbuk National University (Table 1). All of them were already cross-dated using ring-width data for publications [36, 37]. At Songnisan National Park, two tree species, viz. Pinus densiflora and Quercus mongolica, and at Jirisan National Park, four tree species, viz. Taxus cuspidata, Pinus koraiensis, Abies koreana, and Quercus mongolica, were chosen as experimental tree species, which are also the dominant species at high altitude of Songnisan [38] and Jirisan National Parks [39, 40]. Based on the previous studies [30, 34, 37], four trees of each tree species were used to establish the δ18OTR time series for living trees.

Table 1 Details of the experimental sites and trees used to establish the δ18OTR time series

The δ18OTR time series

Only one core per tree was used to establish the δ18OTR time series. The plate method [29] was conducted to facilitate the processing of several rings simultaneously. First, an increment core was transversely cut into several 1-mm-thick wood plates using a diamond wheel saw, and then the plates were sandwiched between 1-mm-thick Teflon-punch sheets (Fig. 2a, b). A 1.0-mm gap was left between the Teflon-punch sheets to allow flow of the chemical solutions and reach all the surfaces of the wooden plate. Second, α-cellulose was extracted directly from the wood plate using a modified Jayme–Wise method [41, 42], which consists of two principal processes: (1) removal of lignin using an acidified sodium chlorite solution, followed by (2) removal of hemicellulose using sodium hydroxide solution in a water bath heated between 70 and 80 °C (Fig. 2c). Third, each annual ring (120–250 μg) of α-cellulose was partially separated from the cellulose plate under a microscope (Fig. 2d), and then loaded on a silver foil (Fig. 2e). The silver-wrapped sample was finally used to determine oxygen isotope ratio in the α-cellulose of each tree ring using an isotope ratio mass spectrometer (Delta V Advantage, Thermo Fisher Scientific) interfaced with a pyrolysis-type high-temperature conversion elemental analyzer (TC/EA, Thermo Fisher Scientific). The oxygen isotope ratio was expressed in δ notation (‰) with respect to the international oxygen isotope standard (Vienna Standard Mean Ocean Water) as follows:

$$\delta^{18} {\text{O}} \left( \permil \right) = \left( {\frac{{R_{{{\text{sam}}\left. {\text{p}} \right|{\text{e}}}} }}{{R_{\text{standard}} }} - 1} \right) \times 1000,$$
(1)

where \(R_{\text{sample}}\) and \(R_{\text{standard}}\) are the 18O/16O ratios in the sample and standard, respectively.

Fig. 2
figure 2

Preparation process to measure δ18O of α-cellulose in each tree ring: a cutting an increment core of 1 mm thickness (C: cross plane, R: radial plane, T: tangential plane); b vial with a thin wood plate fixed between Teflon-punch sheets; c chemical treatment to extract lignin and hemicellulose in solutions of NaClO2 and NaOH in a water bath at temperature 70 and 80 °C, respectively; d separating α-cellulose from each tree ring of same width from early- to latewood at 120–250 μg, and e wrapped α-cellulose in a thin silver foil

Owing to contamination in the process of cellulose extraction, two individual tree cores collected from Q. mongolica were not used for further analysis.

Synchronization tests

To verify synchronization within and between the tree species and provinces, the t-value and Glk (Gleichläufigkeit) scores were used for cross-dating [43]. The t-value and Glk scores are well-known parameters which represent the matching strength between time series at a certain overlapping position in dendrochronology [44]. The t-values were calculated using the correlation coefficients between time series and the number of their overlapping years (Eq. 2), whereas the Glk scores were calculated based on the matching ratios of the time series compared in the overlapping years (Eq. 3).

$$t = \frac{{r \times \sqrt {n - 2} }}{{\sqrt {\left( {1 - r^{2} } \right)} }},$$
(2)

where \(r\) is the correlation coefficient and \(n\) is the number of overlapped tree rings between time series.

$$G_{{\left( {x,y} \right)}} = \frac{1}{n - 1}\mathop \sum \limits_{i = 1}^{n - 1} \left[ {G_{ix} + G_{iy} } \right]$$
(3)

If (\(x_{i + 1} - x_{i}\)) > 0, \(G_{ix}\) = + 1/2,(\(x_{i + 1} - x_{i}\)) = 0, \(G_{ix}\) = 0,(\(x_{i + 1} - x_{i}\)) < 0, \(G_{ix}\) = − 1/2, where \(G_{{\left( {x,y} \right)}}\) is the Glk value and \(x_{i}\) is the measurement value at \(i\)-year tree ring.

The TSAPWin program (RINNTECH, Germany) was applied to calculate the t-values and Glk scores which were further used to test the synchronizations between the δ18OTR time series. Fifty-year δ18OTR time series (1966–2015) from living trees were used for analyzing the strength of common variations between the different trees.

We also used the expressed population signal (EPS) to evaluate the chronology signal strength [27, 45]. The EPS can be described as shown in Eq. 4:

$${\text{EPS}} = n*R_{\text{bar}} /\left( {n*R_{\text{bar}} + \left( {1 - R_{\text{bar}} } \right)} \right),$$
(4)

where n is the number of trees at the site and Rbar is the mean correlation coefficient of all the time series. With increase in n and/or Rbar, the EPS was found to increase and reach 1. The suggested threshold value was higher than 0.85 over the entire period.

Results and discussion

Oxygen isotope measurement of α-cellulose from each tree ring was done so that we could establish δ18OTR time series for individual sample trees. Due to operating error of the equipment, however, two Q. mongolica at Songnisan National Park could not be measured. Therefore, only two oak δ18OTR time series were used for further analysis (Table 2).

Table 2 The t-values and Glk scores of δ18OTR time series within tree species

Synchronization tests within and between tree species

From the synchronization test of δ18OTR time series within tree species, the mean t-values (min.–max.) for P. densiflora and Q. mongolica at Songnisan National Park were 5.2 (4.2–6.4) and 6.9 (none), respectively, while their Glk scores were 74% (66–83%) and 79% (none), respectively (Table 2). In addition, the mean t-values (min.–max.) for T. cuspidata, P. koraiensis, A. koreana, and Q. mongolica at Jirisan National Park were 9.5 (5.9–15.6), 11.2 (7.5–14.0), 7.3 (4.9–11.3) and 6.4 (4.0–11.0), respectively, and their Glk scores were 78% (68–87%), 83% (78–86%), 76% (65–84%), and 69% (62–86%), respectively (Table 2). In all the above cases, the conifer tree species at Jirisan National Park showed higher t-values and Glk scores than that at Songnisan National Park; however, Q. mongolica showed lower values in reverse. Although the statistical values showed some differences, the inter-annual δ18OTR time series within the tree species showed similar patterns (Fig. 3).

Fig. 3
figure 3

Synchronization tests of the δ18OTR time series within tree species (gray lines) and their mean inter-annual variations (solid bold lines)

In the synchronization test of δ18OTR chronologies between tree species, the mean t-value and Glk score between P. densiflora and Q. mongolica at Songnisan National Park were 6.6 and 73%, respectively, while the mean t-values and Glk scores among T. cuspidata, P. koraiensis, A. koreana, and Q. mongolica at Jirisan National Park ranged from 6.1 (P. koraiensis: Q. mongolica) to 13.2 (T. cuspidata: A. koreana) and 73% (P. koraiensis: Q. mongolica) to 81% (T. cuspidata: A. koreana and P. koraiensis: A. koreana), respectively (Table 3, gray background). Except the t-value between P. koraiensis and Q. mongolica in Jirisan National Park, all other statistical values in Jirisan National Park were higher than those in the Songnisan National Park. In these comparisons, we could identify distinct similar patterns among inter-annual δ18OTR chronologies of individual tree species (Fig. 4).

Table 3 The t-values and Glk scores of δ18OTR time series between tree species in the same national parks (gray backgrounds) and both national parks (white background)
Fig. 4
figure 4

Synchronization tests of the δ18OTR chronologies between the tree species

In all the synchronization tests of δ18OTR time series within and between tree species, we verified reliable homogenous patterns as well as meaningful t-values and Glk scores. The oxygen isotope ratios of the tree-ring cellulose were primarily determined by evaporative enrichment of leaf water 18O, which was modulated by relative humidity at the site [26, 27]. Non-climatic factors such as ecological competition did not alter annual variations in δ18OTR values of individual trees significantly. In fact, the δ18OTR time series established from different tree species under the same and/or similar growing conditions were shown to be well correlated with one another [30, 32, 36, 46]. Unlike Q. mongolica, the conifer trees at Jirisan National Park showed higher t-values and Glk scores than the conifer trees (P. densiflora) at Songnisan National Park, and the statistical results between the conifer species tended to be higher than between conifer species and Q. mongolica. According to previous publication [31], such results might occur from differences in the fraction of carbohydrate oxygen that undergoes exchange with oxygen of xylem water, the net fractionation factor between them, differences in root depth and growing seasons of the tree species.

The mean correlation coefficients within trees (Rbar) and expressed population signal (EPS)

Rbar and EPS of δ18OTR time series for the Songnisan National Park were higher than 0.61 and 0.83, respectively (Table 4). By contrast, for the Jirisan National Park, the former was higher than 0.70 and the latter higher than 0.90. Except Q. mongolica at Songnisan National Park, the EPS from the four trees showed higher than the threshold value 0.85 [27, 45]. The δ18OTR chronologies from the four trees therefore were verified as a promising chronology for dating of the undated archaeological woods, as well as for capturing past climate condition.

Table 4 Mean correlation coefficients (Rbar) and expressed population signal (EPS) of δ18OTR time series within tree species

Through previous publications on dendroclimatic researches [47, 48], it was verified that δ18OTR chronologies established using more than four trees could serve as a promising chronology in dendroclimatic reaches based on EPS. In this result, the Rbar from each group, consisting of the same tree species showed high values, so that EPS higher than the threshold value (0.85) could be obtained (Table 4). Only EPS from Q. mongolica at Songnisan National Park, which was calculated using Rbar from two trees, was lower than the threshold due to insufficient sample size.

Synchronization tests between the study regions

Comparing the δ18OTR chronologies originating from Songnisan National Park and Jirisan National Park, the mean t-values and Glk scores (min.–max.) were 4.5 (3.6–5.4) and 72% (68–78%), respectively (Table 3, white background). To verify the synchronization strength between the two regions regardless of tree species, we compared the local δ18OTR chronologies between Songnisan and Jirisan National Parks. It turned out that the mean t-value and Glk score were 3.5, and 65%, respectively. In addition, the local chronologies showed a significant correlation of 0.60 (p < 0.01) (Fig. 5).

Fig. 5
figure 5

Synchronization tests of local δ18OTR chronologies between Songnisan and Jirisan National Parks

According to the correlation analysis between individual δ18OTR chronologies and monthly temperature and precipitation from meteorological stations close to Songnisan and Jirisan National Parks (Fig. 1) for the last 43 years (1973–2015), all chronologies at both the national parks showed relatively high positive correlation coefficients with April and July temperatures of the current year (Fig. 6). These results signify that these monthly temperatures at both the research areas play an important role in modulating δ18O of the source water and local humidity [27, 32]. It should also be noted that there are significant linear relationships between April temperatures of Songnisan and Jirisan National Parks, and between the July temperatures of them as well (Fig. 7). Although Songnisan and Jirisan National Parks are about 144 km apart from each other, our results indicate that the δ18OTR was controlled by large-scale variations in the growing season temperature as well as variations in the April and July temperatures (Fig. 6). Significant correlations of δ18OTR chronologies were also found between different provinces in Bolivia which are about 1000 km far from each other [33].

Fig. 6
figure 6

Correlation coefficients between individual δ18O chronologies and monthly temperature and precipitation from October in the previous year to September in the current year from Boeun meteorological station close to Songnisan National Park and Sancheong and Namwon meteorological stations close to Jirisan National Park for the last 43 years (19732015)

Fig. 7
figure 7

Linear relationships between April temperatures and between July temperatures of Songnisan and Jirisan National Parks

Application to dendroarchaeology and dendroclimatology

In order to date wooden materials using tree-ring chronology, establishing a long chronology using the same tree species growing under similar environmental condition is a fundamental requirement [49]. Dendrologists in Korea have a limitation in making such a long chronology. This is due to the chance of finding a living tree older than 300 years being rare, as well as, it is difficult to find archaeological woods to extend the chronology from the living trees. Based on the current results, it was verified that a δ18OTR chronology established using four trees could play a promising reference in dating archaeological woods excavated from a region between Songnisan and Jirisan National Parks, and in research on reconstructing the past climate of the region.

Conclusions

Based on a 50-year δ18OTR time series, we tested synchronization between and within-tree species in the Songnisan and Jirisan National Parks, which are about 144 km apart. The δ18OTR time series was established using increment cores from Pinus densiflora and Quercus mongolica in the Songnisan National Park, and Taxus cuspidata, Pinus koraiensis, Abies koreana and Quercus mongolica in the Jirisan National Park. All the δ18OTR chronologies showed significant correlations with one another irrespective of species and locations. In addition, the EPS from the four δ18OTR time series were higher than 0.85, which is the threshold value in research on climate in the past. Based on the statistical results, we conclude that a δ18OTR chronology established using more than four trees could play a promising reference for dating an undated wood without considering the tree species, as well as for research on climate in the past, where the regions are from Songnisan to Jirisan National Parks.

Availability of data and materials

Not applicable.

Abbreviations

δ18OTR chronology:

Tree-ring δ18O time series

Glk:

Gleichläufigkeit

EPS:

Expressed population signal

SN:

Songnisan National Park

JR:

Jirisan National Park

DBH:

Diameter at breast height

References

  1. Schweingruber FH (1988) Tree rings. Kluwer, Dordrecht, p 276

    Google Scholar 

  2. Nash SE (2002) Archaeological tree-ring dating at the millennium. J Archaeol Res 10:243–275

    Google Scholar 

  3. Ohyama M, Ohwada M, Suzuki M (2007) Chronology development of Hiba arbor-vitae (Thujopsis dolabrata var. hondae) and dating of timbers from an old building. J Wood Sci 53:367–373

    Google Scholar 

  4. Park W-K, Kim Y, Seo J-W, Lee J-H, Wazny T (2007) Tree-ring dating of Sinmumun, the north gate of Kyungbok Palace in Seoul. Tree-Ring Res 63(2):105–109

    Google Scholar 

  5. Jeong H-M, Kim Y, Kim J-Y, Seo J-W (2016) Tree-ring dating of the Palsangjeon wooden pagoda at the Beopjusa temple in Boeun, South Korea. J Korean Wood Sci Technol 44(4):515–525

    Google Scholar 

  6. Sano Y, Matono T, Ujihara A (1977) Growth of Pinus pumila and climate fluctuation in Japan. Nature 266:159–161

    Google Scholar 

  7. Park W-K, Yadav R (1998) Reconstruction of May precipitation (A.D. 1731–1995) in west-central Korea from tree rings of Korean red pine. J Korean Meteor Soc 34(3):459–465

    Google Scholar 

  8. Abrams MD, Copenheaver CA, Terazawa K, Umeki K, Takiya M, Akashi N (1999) A 370-year dendroecological history of an old-growth Abies-Acer-Quercus forest in Hokkaido, northern Japan. Can J For Res 29(12):1891–1899

    Google Scholar 

  9. Grudd H (2008) Torneträsk tree-ring width and density AD 500–2004: a test of climatic sensitivity and a new 1500-year reconstruction of north Fennoscandian summer. Clim Dyn 31:843–857

    Google Scholar 

  10. Seo J-W, Park W-K (2002) Reconstruction of may precipitation (317 years: A.D. 1682–1998) using tree rings of Pinus densiflora S. et. Z. in Western Sorak Mt. Korean J Quat Res 16(1):29–36 (in Korean with English Abstract)

    Google Scholar 

  11. Choi JN, Yu KB, Park W-K (1992) Paleoclimate reconstruction for Chungbu mountainous region using tree-ring chronology. Korean J Quat Res 6:21–32 (in Korean with English Abstract)

    Google Scholar 

  12. Park W-K (1993) Increasing atmospheric carbon dioxide and growth trends of Korean subalpine conifers. J Korean For Soc 82(1):17–25

    Google Scholar 

  13. Park W-K, Kim Y-J, Lee J-H, Seo J-W (2001) Development of tree-ring chronology of Pinus densiflora from Mt. Sorak and dating the year of construction of the Kyunghoe-ru Pavilion in Seoul. J Korean Phys Soc 39:790–795

    Google Scholar 

  14. Park W-K, Kim Y-J (2005) Tree-ring dating of korean traditional furniture: a case study on cabinet and chest. J Korean Wood Sci Technol 33(3):1–10 (in Korean with English Abstract)

    Google Scholar 

  15. Park W-K, Kim SK, Kim Y-J (2007) Tree-ring dating for Korean wood furniture: a case study on medicine cabinets. J Korean Wood Sci Technol 35(6):57–64 (in Korean with English Abstract)

    Google Scholar 

  16. Lee K-H, Kim S-K, Park W-K (2008) Tree-ring dating of wood elements used for the Jeongjagak and Bigak buildings of Kangrung (King Myoungjong’s Tomb). J Korean Furnit Soc 19(3):219–228 (in Korean with English Abstract)

    Google Scholar 

  17. Park W-K, Yoon S-J, Lee Y-J (1999) Species identification of peat woods from Hyunwhari, Pyungtack. Mokchae Konghak 27(2):1–6 (in Korean with English Abstract)

    Google Scholar 

  18. Park W-K, Lee K-H (2007) Changes in the species of woods of used for Korean ancient and historic architectures. AURC 16(1):9–28 (in Korean with English abstract)

    Google Scholar 

  19. Park W-K, Oh J-A, Kim Y, Kim S-K, Park S-Y, Son B-H, Choi S (2010) Species of wooden Buddhist statues of the late Joseon Dynasty in Jeollado, South Korea. J Korean Furnit Soc 21(1):72–82 (in Korean with English abstract)

    Google Scholar 

  20. Son J-A, Park W-K (2010) Species of Korean furniture in the late Choseon Dynasty (I). KFS J 21(6):486–498

    Google Scholar 

  21. Lee K-H, Seo J-W, Han G-S (2018) Dating wooden artifacts excavated at Imdang-dong site, Gyeongsan, Korea and interpreting the paleoenvironment according to the wood identification. J Korean Wood Sci Technol 46(3):241–252 (in Korean with English Abstract)

    Google Scholar 

  22. Nam T-G, Hong G-H, Lee J-H (2017) Radiocarbon dating of a wooden board from Mado shipwreck No. 4 using wiggle matching. J Conserv Sci 33(4):275–281 (in Korean with English Abstract)

    Google Scholar 

  23. Nam T-G, Yoon Y-H, Kim E-H (2018) Species identification and Radiocarbon dating for the wooden board from Daebudo shipwreck No. 2 using wiggle matching. J Conserv Sci 34(5):359–368 (in Korean with English Abstract)

    Google Scholar 

  24. Garćia-González I, Eckstein D (2003) Climatic signal of earlywood vessels of oak on a maritime site. Tree Physiol 23(7):497–504

    Google Scholar 

  25. Seo JW, Eckstein D, Jalkanin R (2012) Screening various variables of cellular anatomy of Scots pines in subarctic Finland for climatic signals. IAWA J 33(4):417–429

    Google Scholar 

  26. Roden JS, Lin G, Ehleringer JR (2000) A mechanistic model for interpretation of hydrogen and oxygen isotope ratios in tree-ring cellulose—evidence and implications for the use of isotope signals transduced by plants. Geochim Cosmochim Acta 64(1):21–35

    CAS  Google Scholar 

  27. McCarroll D, Loader NJ (2004) Stable isotopes in tree rings. Quat Sci Rev 23(7–8):771–801

    Google Scholar 

  28. Esper J, Frank DC, Battipaglia G, Büntgen U, Holert C, Treydte K, Siegwolf R, Saurer M (2010) Low-frequency noise in δ13C and δ18O tree ring data: a case study of Pinus uncinata in the Spanish Pyrenees. Global Biogeochem Cycles 24(4):1–11

    Google Scholar 

  29. Kagawa A, Sano M, Nakatsuka T, Ikeda T, Kubo S (2015) An optimized method for stable isotope analysis of tree rings by extracting cellulose directly from cross-sectional laths. Chem Geol 393–394:16–25

    Google Scholar 

  30. Sano M, Tshering P, Komori J, Fujita K, Xu C, Nakatsuka T (2013) May-September precipitation in the Bhutan Himalaya since 1743 as reconstructed from tree ring cellulose δ18O. J Geophys Res Atmos 118(15):8399–8410

    Google Scholar 

  31. Hartl-Meier C, Zang C, Büntgen U, Esper J, Rothe A, Göttlein A, Dirnböck T, Treydte K (2015) Uniform climate sensitivity in tree-ring stable isotopes across species and sites in a mid-latitude temperate forest. Tree Physiol 35(1):4–15

    CAS  PubMed  Google Scholar 

  32. Li Z, Nakatsuka T, Sano M (2015) Tree-ring cellulose δ18O variability in pine and oak and its potential to reconstruct precipitation and relative humidity in central Japan. Geochem J 49(2):125–137

    Google Scholar 

  33. Jessica B, Sarah H, Santiago C, Robert N, Simnon B, Melanie L, Timnothy H, Gerhard H, Jaime A, Manuel G, Roel B (2015) Oxygen isotopes in tree rings show good coherence between species and sites in Bolivia. Glob Planet Change 133:298–308

    Google Scholar 

  34. Xu C, Masaki S, Nakatsuka T (2011) Tree ring cellulose δ18O of Fokieneia hodginsii in northern Laos: a promising proxy to reconstruct ENSO? J Geophys Res 116:D24109

    Google Scholar 

  35. Seo J-W, Sano M, Jeong H-M, Lee K-H, Park H-C, Nakatsuka T, Shin C-S (2019) Oxygen isotope ratios of subalpine in Jirisan National Park, Korea and their dendroclimatological potential. Dendrochronologia 57:1–7

    Google Scholar 

  36. Seo J-W, Jeong H-M, Sano M, Choi E-B, Park J-H, Lee G-H, Kim Y-J, Park H-C (2017) Establishing tree ring δ18O chronologies for principal tree species (T. cuspidata, P. koraiensis, A. koreana, Q. mongolica) at subalpine zone in Mt. Jiri National Park and their correlations with the corresponding climate. J Korean Wood Sci Technol 45(5):661–670 (in Korean with English abstract)

    Google Scholar 

  37. Jeong H-M, Kim Y-J, Seo J-W (2017) Relationships between vessel-lumen-area time series of Quercus spp. Mt. Songni and corresponding climatic factors. J Korean Wood Sci Technol 45(1):72–84 (in Korean with English abstract)

    Google Scholar 

  38. Yu J-E, Lee J-H, Kwon K-W (2003) An analysis of forest community and dynamics according to elevation in Mt. Sokri and Odae. Korean J Agric For Meteorol 5(4):238–246

    Google Scholar 

  39. Gwon J-H, Sin M-K, Kwon HJ, Song H-K (2013) A study on the forest vegetation of Jirisan National Park. J Korean Env Tech 16(5):93–118 (in Korean with English abstract)

    Google Scholar 

  40. Cho M-G, Chung J-M, Im H-I, Il Noh, Kim T-W, Kim C-Y, Moon H-S (2016) Ecological characteristics of sub-alpine coniferous forest on Banyabong in Mt. Jiri. J Clim Change Res 7(4):465–476

    Google Scholar 

  41. Loader NJ, Robertson I, Barker AC, Switsur VR, Waterhouse JS (1997) An improved technique for the batch processing of small wholewood samples to α-cellulose. Chem Geol 136(3–4):313–317

    CAS  Google Scholar 

  42. Brendel O, Iannetta P, Stewart D (2000) A rapid and simple method to isolate pure alpha-cellulose. Phytochem Anal 11(1):7–10

    CAS  Google Scholar 

  43. Eckstein D, Bauch J (1969) Beitrag zur Rationalisierung eines dendrochronologishen Verfahrens und zur Analyze seiner Aussagesicherheit. Forstw Cbl 88:230–250

    Google Scholar 

  44. Nasswettrová A, Krvankov S, Smira P (2017) Comparison of the results of dendrochronological measuring based on different images of a historical wood sample of silver fir (Abies alba) from the Czech Republic. Wood Res 62(1):113–124

    Google Scholar 

  45. Wigley TML, Briffa KR, Jones PD (1984) On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. J Climate Appl Meteror. 23:201–213

    Google Scholar 

  46. Hartl-Meier C, Zang C, Büntgen U, Esper J, Rothe A, Göttlein A, Dirnböck T, Treydte K (2014) Uniform climate sensitivity in tree-ring stable isotopes across species and sites in a mid-latitude temperate forest. Tree Physiol 35(1):4–15

    PubMed  Google Scholar 

  47. Xu C, Zhu H, Nakatsuka T, Sano M, Li Z, Shi F, Liang E, Guo Z (2017) Sampling strategy and climatic implication of tree-ring cellulose oxygen isotopes of Hippophae tibetana and Abies georgei on the southeastern Tibetan Plateau. Int J Biometeorol 63:679–686

    PubMed  Google Scholar 

  48. Li Q, Liu Y, Nakatsuka T, Zhan Q-B, Ohnishi K, Sakai A, Kobayashi O, Pan Y, Song H, Liu R, Sun C, Fang C (2020) Oxygen stable isotopes of a network of shrubs and trees as high-resolution paleoclimatic proxies in Northwestern China. Agric For Meteorol 285–286:107929

    Google Scholar 

  49. Fritts HC (1976) Tree rings and climate. Academic Press, New York

    Google Scholar 

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Acknowledgements

This study was supported by the Ministry of Environment (MOE), the Republic of Korea, through the Korea National Park Research Institute as the “The monitoring Project of Ecosystem in National Park according to climate change”, by Research Institute for Humanity and Nature (RIHN: a constituent member of NIHU) Project No. 14200077 (Historical Climate Adaptation Project), and Grant-in-Aid for Scientific Research from the Japan Society for the Promotion of Science (23242047, 26244049, 17H02020 and 17H06118).

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Choi, EB., Sano, M., Park, JH. et al. Synchronizations of tree-ring δ18O time series within and between tree species and provinces in Korea: a case study using dominant tree species in high elevations. J Wood Sci 66, 53 (2020). https://doi.org/10.1186/s10086-020-01901-3

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