employee
Minsk, Belarus
UDK 630 Лесное хозяйство. Лесоводство
The paper presents new experimental data and reveals the regular variability of the formation of density fluctuations, frost and fallen annual rings in mossy (Pinetum pleurozium) and ledum (Pinetum ledosum) pine forests. The main statistical characteristics of generalized tree-ring chronologies are analyzed, statistically significant differences (p < 0.05) in the average, maximum and minimum width of annual rings depending on the type of forest are established. It has been experimentally established that in ledum pine forests the number of anomalies is 3.34 times greater than in mossy pine forests. There were 229 density fluctuations in mossy pine, 530 in ledum, frost damage – 28 and 159, fallen tree rings – 10 and 202, in compliance. The most unfavorable years, which were reflected in the radial growth of mossy pine forests, were 1979 and 1980; the maximum number of detected anomalies (91,4%) occurred in 1907, 1928, 1958, 1971, 1985, 1990, 1992, 1994, 1999, 2010 and 2017. The most unfavorable years, which were reflected in the radial growth of ledum pine forests, were 1906 and 1940 ; the maximum number of detected anomalies (89.7%) occurred in 1928, 1937, 1944, 1946, 1963, 1965, 1974, 1977, 1981, 1982, 1991, 2000 and 2016. There are no coincidences of the formation of anomalies and minima of growth in mossy and ledum pine forests, as far as the degree of responses to changes in external conditions in these types of forests is different. The conducted studies have shown that the structure of annual rings of common pine can be considered as a reflection of the features of seasonal growth of trees, while the formation of anomalies of the structure is largely determined by soil-hydrological conditions of growth.
mossy pine forests, ledum pine forests, growing conditions, fallen tree rings, anomalies in the structure of tree rings, soil-hydrological regime
1. Peltier D. M., Ogle K. Tree growth sensitivity to climate is temporally variable. Ecology Letters. 2020;23(11):1561-1572. DOI: https://doi.org/10.1111/ele.13575.
2. Fuchs S., Schuldt B., Leuschner C. Identification of drought-tolerant tree species through climate sensitivity analysis of radial growth in Central European mixed broadleaf forests. Forest Ecology and Management. 2021;494:119287. DOI: https://doi.org/10.1016/j.foreco.2021.119287.
3. Schweingruber F. H. Wood structure and environment. Springer Science & Business Media, 2007. 279 p. URL: https://www.coursehero.com/file/83370489/Fritz-H-Schweingruber-Wood-Stru....
4. Braeuning A., De Ridder M., Zafirov N., García-González I., Dimitrov D. P., Gärtner, H. Tree-ring features: indicators of extreme event impacts. Iawa Journal. 2016;37(2): 206-231. URL: https://brill.com/view/journals/iawa/37/2/article-p206_7.xml.
5. Gao J., Rossi S., Yang B. Origin of intra-annual density fluctuations in a semi-arid area of Northwestern China. Frontiers in Plant Science. 2021;12:777753. DOI: https://doi.org/10.3389/fpls.2021.777753.
6. De Micco V., Campelo F., De Luis M., Bräuning A., Grabner M., Battipaglia G., Cherubini P. Intra-annual density fluctuations in tree rings: how, when, where, and why? IAWA Journal. 2016;37(2):232-259. URL: https://brill.com/view/journals/iawa/37/2/article-p232_8.xml.
7. Campelo F., Nabais C., Freitas H., Gutierrez E. Climatic significance of tree-ring width and intra-annual density fluctuations in Pinus pinea from a dry Mediterranean area in Portugal. Ann. For. Sci. 2007;64:229-238. DOIhttps://doi.org/10.1051/forest:2006107.
8. Rita A., Camarero J. J., Colangelo M., de Andrés E. G., Pompa-García M. Wood Anatomical Traits Respond to Climate but More Individualistically as Compared to Radial Growth: Analyze Trees, Not Means. Forests. 2022;13(6):956. DOI: https://doi.org/10.3390/f13060956.
9. Hetzer T., Brauning A., Leuschner H-H. High-resolution climatic analysis of wood anatomical features in Corsican pine from Corsica (France) using latewood tracheid profiles. Trees 2014;28:1279-1288. DOI: https://doi.org/10.1007/s00468-014-1045-7.
10. Hoh A. N., Voskanyan P. S., Petrosyan A. A. Individual'nye priznaki v stroenii godichnyh sloev i ispol'zovanie ih dlya ustanovleniya mesta proizrastaniya. Sudebnaya ekspertiza Belarusi. 2022;1:76-82. URL: https://elibrary.ru/item.asp?id=48367040.
11. Voronin V. I., Zhavoronkov Yu. M., Unzhakova S. V., Cvetkov V. A. Aktual'nye problemy naznacheniya i proizvodstva sudebno-botanicheskoy ekspertizy s primeneniem metodov dendrohronologii, ekologicheskoy ekspertizy i puti ih resheniya. Kriminalistika: vchera, segodnya, zavtra. 2022;3:44-62. DOI:https://doi.org/10.55001/2587-9820.2022.44.51.00512.
12. Dylis N.V. Programma i metodika biogeocenologicheskih issledovaniy. M.: Nauka. 1974: 404. URL: https://www.studmed.ru/dylis-nv-programma-i-metodika-biogeocenologichesk....
13. Hoh A. N., Zvyagincev V.B. Anomalii struktury godichnyh sloev sosny obyknovennoy v zavisimosti ot tipa lesa. Izvestiya Gomel'skogo gosudarstvennogo universiteta imeni F. Skoriny. 2023;3(138):49-55. URL: http://elib.gsu.by/jspui/handle/123456789/61605.
14. Barinov V. V., Myglan V. S., Nazarov A. N., Vaganov E. A., Agatova A. R., Nepop R. K. Ekstremal'nye klimaticheskie sobytiya v Respublike Altay po dendrohronologicheskim dannym. Izvestiya Rossiyskoy akademii nauk. Seriya biologicheskaya. 2016;(2):188. DOI:https://doi.org/10.7868/S0002332916020028.
15. Brewer P. W., Murphy D., Jansma E. TRiCYCLE: a universal conversion tool for digital tree-ring data. Tree-Ring Research. 2011;67(2):135-144. DOI: https://doi.org/10.3959/2010-12.1.
16. Holmes R.L. Computer-assisted quality control in tree-ring dating and measurement. Tree-Ring Bulletin. 1983;43:69–78. URL: http://hdl.handle.net/10150/261223.
17. Holmes R. L., Adams R. K., Fritts H. C. User's manual for program ARSTAN. Tree-Ring Chronologies of Western North America: California, Eastern Oregon and Northern Great Basin. University of Arizona, Tucson.1986: 50–56. URI: http://hdl.handle.net/10150/304672.
18. Tishin D. V., Chizhikova N. A. Dendrohronologiya. Kazan': Kazanskiy universitet, 2018. 34 s. URI: https://kpfu.ru/staff_files/F_662784908/Dendrochronology_09final.pdf.
19. Rigling A., Waldner P. O., Forster T., Bräker O. U., Pouttu A. Ecological interpretation of tree-ring width and intraannual density fluctuations in Pinus sylvestris on dry sites in the central Alps and Siberia. Canadian Journal of Forest Research. 2001;31(1):18-31. DOI: https://doi.org/10.1139/x00-126.
20. Sharma A., Jaloree S., Thakur R. S. Review of clustering methods: toward phylogenetic tree. Proceedings of International Conference on Recent Advancement on Computer and Communication. Springer, Singapore. 2018:475–480. DOI: https://doi.org/10.1007/978-981-10-8198-9_50.
21. Novakovskiy A. B., Novakovskaya I. V. Exstatr–rasshirenie Excel dlya statisticheskoy obrabotki dannyh v ekologii. Cianoprokarioty / cianobakterii: sistematika, ekologiya, rasprostranenie. 2019:41–44. URL: https://elibrary.ru/item.asp?id=41186453.
22. Briffa K. R., Jones P. D., Schweingruber F. H. Summer temperature patterns over Europe: a reconstruction from 1750 AD based on maximum latewood density indices of conifers. Quaternary Research. 1988;30(1):36-52. DOI: https://doi.org/10.1016/0033-5894(88)90086-5.
23. Matveev S. M., Timaschuk D. A. Dendroklimaticheskiy analiz 200-letnego drevostostoya sosny obyknovennoy v Voronezhskom biosfernom zapovednike. Lesovedenie. 2019;2: 93-104. DOI:https://doi.org/10.1134/S0024114819020074.
24. Loginov V. F., Volchek A. A., Valuev V. E., Germenchuk M. G., Komarovskaya E. V., Kurchevskiy S. M., Shpoka I. N. Atlas opasnyh meteorologicheskih yavleniy na territorii Belarusi : ucheb. posobie. M. : Mescher. F-l VNIIGiM im. A.N. Kostyakova. 2016:58. URL:https://rep.bstu.by/handle/data/3833.
25. Postanovlenie Gosudarstvennogo komiteta sudebnyh ekspertiz Respubliki Belarus' ot 9 noyabrya 2020 g. № 11 «Ob osuschestvlenii deyatel'nosti po provedeniyu sudebnyh ekspertiz» – 18 s.
26. Rozanov, M. I. Dendrohronologicheskie metody ekspertizy drevesiny. VNIISE ekspertnaya tehnika. 1971; 34:45–65.
27. Rozanov, M. I. Ustanovlenie istochnika proishozhdeniya dereva. Kriminalisticheskoe issledovanie veschestvennyh dokazatel'stv fizicheskimi, himicheskimi i biologicheskimi metodami. CNIISED. 1969;2: 34–36.
28. Dormontt, E. E., Boner, M., Braun, B., Breulmann, G., Degen, B., Espinoza, E., Lowe, A. J. Forensic timber identification: It's time to integrate disciplines to combat illegal logging . Biological Conservation. 2015;191:790-798. URL: https://doi.org/10.1016/j.biocon.2015.06.038
