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Vegetation structure and distribution characteristics of Symplocos prunifolia, a rare evergreen broad-leaved tree in Korea

  • Kim, Yangji (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science) ;
  • Song, Kukman (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science) ;
  • Yim, Eunyoung (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science) ;
  • Seo, Yeonok (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science) ;
  • Choi, Hyungsoon (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science) ;
  • Choi, Byoungki (Warm Temperate and Subtropical Forest Research Center, National Institute of Forest Science)
  • 투고 : 2020.07.27
  • 심사 : 2020.11.11
  • 발행 : 2020.12.31

초록

Background: In Korea, Symplocos prunifolia Siebold. & Zucc. is only found on Jeju Island. Conservation of the species is difficult because little is known about its distribution and natural habitat. The lack of research and survey data on the characteristics of native vegetation and distribution of this species means that there is insufficient information to guide the management and conservation of this species and related vegetation. Therefore, this study aims to identify the distribution and vegetation associated with S. prunifolia. Results: As a result of field investigations, it was confirmed that the native S. prunifolia communities were distributed in 4 areas located on the southern side of Mt. Halla and within the evergreen broad-leaved forest zones. Furthermore, these evergreen broad-leaved forest zones are themselves located in the warm temperate zone which are distributed along the valley sides at elevations between 318 and 461 m. S. prunifolia was only found on the south side of Mt. Halla, and mainly on south-facing slopes; however, small communities were found to be growing on northwest-facing slopes. It has been confirmed that S. prunifolia trees are rare but an important constituent species in the evergreen broad-leaved forest of Jeju. The mean importance percentage of S. prunifolia community was 48.84 for Castanopsis sieboldii, 17.79 for Quercus acuta, and 12.12 for Pinus thunbergii; S. prunifolia was the ninth most important species (2.6). Conclusions: S. prunifolia can be found growing along the natural streams of Jeju, where there is little anthropogenic influence and where the streams have caused soil disturbance through natural processes of erosion and deposition of sediments. Currently, the native area of S. prunifolia is about 3300 ㎡, which contains a confirmed population of 180 individual plants. As a result of these low population sizes, it places it in the category of an extremely endangered plant in Korea. In some native sites, the canopy of evergreen broad-leaved forest formed, but the frequency and coverage of species were not high. Negative factors that contributed to the low distribution of this species were factors such as lacking in shade tolerance, low fruiting rates, small native areas, and special habitats as well as requiring adequate stream disturbance. Presently, due to changes in climate, it is unclear whether this species will see an increase in its population and habitat area or whether it will remain as an endangered species within Korea. What is clear, however, is that the preservation of the present native habitats and population is extremely important if the population is to be maintained and expanded. It is also meaningful in terms of the stable conservation of biodiversity in Korea. Therefore, based on the results of this study, it is judged that a systematic evaluation for the preservation and conservation of the habitat and vegetation management method of S. prunifolia should be conducted.

키워드

참고문헌

  1. Brower JE, Zar JH, Ende CN. Field and laboratory method for general ecology. 4th ed. Boston: WCB McGraw-Hill; 1998.
  2. Chinzei K, Fujioka K, Kitazato H, Koizumi I, Oba T, Oda M, et al. Postglacial environmental change of the Pacific Ocean off the coastal of Central Japan. Mar Micropaleo. 1987;11:273-91. https://doi.org/10.1016/0377-8398(87)90002-8
  3. Choi BK, Syntaxonomy and syngeography of warm-temperate evergreen broadleaved forests in Korea. Daegu: Keimyung Univ. PhD Thesis; 2013.
  4. Choi BK, Lee CB. A study on the synecological values of the Torreya nucifera forest (natural monument no. 374) at Pyeongdae-ri in Jeju Island. J Korean Inst Trad Land Arch. 2015;33(4):87-98. https://doi.org/10.14700/KITLA.2015.33.4.087
  5. Chung CH. Vegetation response to climate change on Jeju Island, South Korea, during the last deglaciation based on pollen record. Geosci J. 2007;11:147-55. https://doi.org/10.1007/BF02913928
  6. Corlett RT. Seed dispersal distances and plant migration potential in tropical East Asia. Biotro. 2009;41:592-8. https://doi.org/10.1111/j.1744-7429.2009.00503.x
  7. Curtis JT, McIntosh RP. An upland forest continuum in the prairie-forest border region of Wisconsin. Ecology. 1951;32:476-96. https://doi.org/10.2307/1931725
  8. Eom BC, Climatically potential natural vegetation and phytoclimatic map of Korea. Daegu. Keimyung Univ. PhD Thesis; 2019.
  9. GBIF (2020) Global biodiversity information facility. URL: https://www.gbif.org/.
  10. Harrison SP, Yu G, Takahara H, Prentice IC. Diversity of temperate plants in East Asia. Nature. 2001;413:129-30. https://doi.org/10.1038/35093166
  11. Hattori T, Minamiyama N, Kuroda A. Phytosociological system of the natural lucidophyllous forests in Japan. Human Nat. 2012;23:1-29. https://doi.org/10.1007/s12110-012-9133-0
  12. Hong YS, Kim EJ, Lee EP, Lee SY, Cho KT, Lee YK, et al. Characteristics of vegetation succession on the Pinus thunbergii forests in warm temperate regions, Jeju Island. South Korea J Ecol Environ. 2019;43(4):438-53.
  13. Ito HK. A comparison of seedling emergence and survival between Quercus glauca and Symplocos prunifolia. J For Res. 2009;14:245-50. https://doi.org/10.1007/s10310-009-0124-x
  14. Kang MS, Lee YJ, Park CY, Yoo CS. A new classification rule of hydrological soil groups of Jeju Island: application to representative basins and evaluation of previous studies. J Kor Wat Res Ass. 2018;51:1261-71.
  15. Kawahata H, Ohshima H. Vegetation and environmental record in the northern East China Sea during the late Pleistocene. Glob Planet. 2004;41:251-73. https://doi.org/10.1016/j.gloplacha.2004.01.011
  16. KBIS. Korea Biodiversity Information System. URL: https://www.nature.go.kr/. 2020.
  17. KIGAM. Korea Institute of Geoscience and Mineral Resources. URL: https://www.kigam.re.kr/. 2020.
  18. Kim CS, Koh JG, Moon MO, Song GP, Kim SY, Kim J, et al. Rare plants of Jeju Island. Kor For Res Ins: Seoul; 2008.
  19. Kim JW. Vegetation of Northeast Asia: on the syntaxonomy and syngeography of the oak and beech forests. Vienna: University of Vienna. PhD Thesis; 1992.
  20. Kim MH. Phytosociological study on the vegetation of Cheju Island, Korea. Jeju: Jeju Univ. PhD Thesis; 2000.
  21. Kim MH, Itow S. Distribution of evergreen broad-leaved plants in satellite islands of Korea and Western Kyushu, Japan (1) distribution of tree species and factors of distribution. J Bas Sci Cheju Univ. 1996;9:107-20.
  22. KNA (Korea National Arboretum). Rare Plants Data Book in Korea. Pocheon: Kor Nat Arb; 2009.
  23. Lee CB. Coloured flora of Korea I volumes. Hyangmunsa: Seoul; 2003a.
  24. Lee CB. Coloured flora of Korea II volumes. Hyangmunsa: Seoul; 2003b.
  25. Lee WT. Lineamenta Flora Koreae. Seoul: Academy Press; 1996.
  26. Manabe T, Nishimura N, Miura M, Yamamoto S. Population structure and spatial patterns for trees in a temperate old-growth evergreen broad-leaved forest in Japan. Plant Ecol. 2000;151:181-97. https://doi.org/10.1023/a:1026512404110
  27. Miura M, Manabe T, Nishimura N, Yamamoto S. Forest canopy and community dynamics in a temperate old-growth evergreen broad-leaved forest, SouthWestern Japan: a 7-year study of a 4-ha plot. J Ecol. 2001;89:841-9. https://doi.org/10.1046/j.0022-0477.2001.00603.x
  28. Miyawaki A, Okuda S, Fujiwara R. Handbook of Japanese vegetation. Shibundo Pub.: Tokyo; 1994.
  29. Miyoshi N, Fujiki T, Morita Y. Palynology of a 250-m core from Lake Biwa: a 430,000-year record of glacial-interglacial vegetation change in Japan. R Palaeo and Paly. 1999;104:267-83. https://doi.org/10.1016/S0034-6667(98)00058-X
  30. Moon DC, Yang SK, Koh GW, Park WB. Estimation of baseflow discharge through several streams in Jeju Island. Korea J Envir Sci. 2005;14:405-12.
  31. Naka K, Yoneda T. Community dynamics of evergreen broadleaf forests in southwestern Japan. III. Revegetation in gaps in an evergreen oak forest. Bot Mag Tok. 1984;97:275-86. https://doi.org/10.1007/BF02488661
  32. NIBR. National Institute of Biological Resources. URL: https://www.nibr.go.kr/; 2020.
  33. Oh JG. Comparative studies on evergreen broad-leaved forests of Dadohae National Marine Park in Korea and Nagasakigen in Japan. Mokpo: Mokpo Univ. PhD Thesis; 1995.
  34. Oh KK, Choi SH. Vegetation structure and successional sere of warm temperate evergreen forest region. Korea Kor J Ecol. 1993;16(4):459-76.
  35. Pielou EC. Ecological diversity. New York: John Wiley and Sons; 1975.
  36. Podani J. SYNTAX 2000: computer program for data analysis in ecology and systematics. Budapest: Scientia Pub; 2001.
  37. Shannon CE, Weaver W. The mathematical theory of communication. Urbana & Illinois: Univ. Illinois press; 1963.
  38. Shin HT, Yi MH. The relationship between soil seed bank and ground layer of actual vegetation in Korea. J Environ Sci. 2011;20:127-35.
  39. Song KM. An analysis of a 100-years-old map of the heritage trees in Jeju Island. J Korean Inst Trad Land Arch. 2019.37(2):20-29. https://doi.org/10.14700/KITLA.2019.37.2.020
  40. Song YC. The essential characteristics and main types of the broad-leaved evergreen forest in China. Phytoco. 1988;16:105-23. https://doi.org/10.1127/phyto/16/1988/105
  41. Song YC, Wang XR. Vegetation and flora of Tiantong National Forest Park, Zheijiang Province China. Shanghai: Shang Sci Tech Liter Press; 1995.
  42. Sung JW, Yi MH, Yoon JW, Kim GS, Shin HT, Kim YS. Growth environment and vegetation structure of native habitat of Corydalis cornupetala. Kor J Environ Eco. 2013;27:271-9.
  43. Tang CQ. The subtropical vegetation of southwestern China. Heidelberg: Springer; 2015.
  44. Tang CQ, Ohsawa M. Ecology of subtropical evergreen broad-leaved forests of Yunnan, southwestern China as compared to those of southwestern Japan. J Plant Res. 2009;122:335-50. https://doi.org/10.1007/s10265-009-0221-0
  45. Tsukada M. Map of vegetation during the last glacial maximum in Japan. Quat Res. 1985;23:369-81. https://doi.org/10.1016/0033-5894(85)90041-9
  46. Wang XH, Kent M, Fang XF. Evergreen broad-leaved forest in eastern China: its ecology and conservation and the importance of resprouting in forest restoration. For Ecol Manag. 2007;245:76-87. https://doi.org/10.1016/j.foreco.2007.03.043
  47. Weber HE, Moravec J, Theurillat JP. International code of phytosociological nomenclature. 3rd edition. J Veg Sci. 2000;11:739-68. https://doi.org/10.2307/3236580
  48. Westhoff V, Maarel EV. The Braun-Blanquet approach, in RH Whittaker (Eds.) ordination and classification of communities. The Hague: Dr. Junk, W. Pub; 1973.
  49. Whittaker RH. Vegetation of the Great Smoky Mountains. Ecol Monogr. 1956;26:1-80. https://doi.org/10.2307/1943577
  50. Yi MH, Kim YS, Kim DG, Park SG, Shin HT. The relationship between soil seed bank and actual vegetation. Kor J Environ Ecol. 2010;24:638-47.
  51. Yim YJ, Kira T. Distribution of forest vegetation and climate in the Korean peninsula: I. distribution of some indices of thermal climate. Ecol Soc Jap. 1975;25(2):77-88.
  52. Yoon JH, Hukusima T, Kim MH, Yoshikawa M. The comparative studies on the distribution and species composition of forest community in Korea and Japan around the East Sea. Kor J Environ Ecol. 2011;25:327-57.
  53. Yoon JW, Yi MH, Kim YS. Growth environment and vegetation structure of native habitats of Wikstroemia ganpi (Sieb. Et Zucc.) maxim. Kor J Environ Ecol. 2014;28:331-41. https://doi.org/10.13047/KJEE.2014.28.3.331
  54. Zheng Z, Wei JH, Huang KY, Xu CH, Lu HY, Tarasov P, et al. East Asian pollen database: modern pollen distribution and its quantitative relationship with vegetation and climate. J Biogeogr. 2014;41:1819-32. https://doi.org/10.1111/jbi.12361