Journal of Bio-Environment Control (생물환경조절학회지)

The Korean Society for Bio-Environment Control (한국생물환경조절학회)
권호 표지

Growth Performances of Seedlings of Daphniphyllum macropodum in Naejang National Park for Container Seeding Production

시설양묘에 적용을 위한 내장산 굴거리 나무 군락내 치수의 생장 특성

  • Chung, Jin-Chul (Department of Environmental Landscape Architecture, Wonkwang University) ;
  • Jeong, Ji-Young (Buan-gun Forestry Cooperative) ;
  • Choi, Jeong-Ho (Department of Environmental Landscape Architecture, Wonkwang University) ;
  • Jeon, Kyung-Soo (Department of Environmental Landscape Architecture, Wonkwang University) ;
  • Bae, Jong-Hyang (Department of Horticulture and Pet Animal-Plant Science, Wonkwang University)
  • 정진철 (원광대학교 환경조경학과) ;
  • 정지영 (부안군 산림조합) ;
  • 최정호 (원광대학교 환경조경학과) ;
  • 전경수 (원광대학교 환경조경학과) ;
  • 배종향 (원광대학교 원예애완동식물학부)
  • Received : 2011.08.25
  • Accepted : 2011.12.20
  • Published : 2011.12.31
Download PDF
⟨ Previous Next ⟩

Abstract

This study aimed to examine foundational data for container seedling production with the subject of Daphniphyllum macropodum community in Mt. Naejang National Park. To achieve the goal, it investigated the growth characteristics of young tree seedlings growing in places with different light intensity environment. Regarding the growth environment of Daphniphyllum macropodum community, it was typical heavy rain summer climate, and the soil was silt loam with the organic content as 11.42~15.61%, total nitrogen as 0.50~0.76%, cation exchangeable capacity (C.E.C) as 18.92~23.32 cmol/kg, and pH as 4.85~5.58. About light intensity environment changed by research plots, relative transmittance of solar radiation was 71~76% in plot A, 37~42% in plot B, 65~70% in plot C, and 28~33% in plot D. The seedlings tended to be intensively distributed either under the crown of their mother tree or in the slope site, and plot A and C where light intensity environment is relatively more favorable showed 1,550 tree/ha and 1,250 tree/ha. Total biomass production of Daphniphyllum macropodum seedlings was 5.37 g in plot A and 5.29 g in plot C, so they were higher than 4.42~4.51 g in plot B and D with relatively less favorable light intensity environment. The T/R ratio was 1~2, leaf area rate was $139.71{\sim}183.50cm^2{\cdot}g^{-1}$, leaf area ratio was $39.68{\sim}60.66cm^2{\cdot}g^{-1}$, and leaf dry weight ratio grew higher in the range of $0.28{\sim}0.33cm^2{\cdot}g^{-1}$ as the intensity of radiation became less. It is thought that in the generation and growth of Daphniphyllum macropodum seedlings, the intensity of light has more effects than the organic content in soil. And it is also thought that in the application of container seedlings production, light environment management over 65~70% to full sun light intensity will affect significantly the initial growth of Daphniphyllum macropodum.

본 조사는 내장산 국립공원내 굴거리나무 군락지를 대상으로 시설양묘를 위한 기초자료를 구명하고자 광환경이 다른 조건에서 자라고 있는 치수의 생장특성을 조사하였다. 굴거리나무 군락지의 생육 환경은 전형적인 하계 다우형 기후를 보였고, 토양은 미사질양토로, 유기물 함량 11.42~15.61%, 전질소 함량 0.50~0.76%, 양이온 치환용량(C.E.C) 18.92~23.32cmol/kg, pH 4.85~5.58 범위를 나타내었다. 조사구별 전광대비 광 환경의 차이는 상대 투광율이 조사구 A가 71~76%, 조사구 B는 37~42%, 조사구 C는 65~70%, 조사구 D는 28~33%로 나타났다. 굴거리나무의 치수는 모수의 수관 밑과 경사진 곳에 집중적으로 분포하는 경향을 보였고, 광환경 조건이 상대적으로 높은 조사구 A와 C가 1,550본/ha, 1,250본/ha이었으며, 총 물질 생산량도 조사구 A가 5.37g, 조사구 C가 5.29g로 광환경 조건이 낮은 조사구 B와 D의 4.42~4.51보다 높게 나타났다. T/R율은 1~2, 엽면적비는 $139.71{\sim}183.50cm^2{\cdot}g^{-1}$, 엽면적비는 $39.68{\sim}60.66cm^2{\cdot}g^{-1}$, 엽건중비는 $0.28{\sim}0.33cm^2{\cdot}g^{-1}$ 범위 내에서 광량이 적어질수록 높게 나타났다. 굴거리나무 치수의 발생과 생장은 토양내 유기물 함량보다 광량이 많은 영향을 미치는 것으로 판단되며 시설양묘 적용시 전광대비 65~70% 이상의 광환경의 관리가 굴거리나무의 초기 생장에 중요한 역할을 미칠 것으로 판단된다.

Keywords

References

  1. Ashton, P.M.S. and G.P. Berlyn. 1994. A comparison of leaf physiology and anatomy of Quercus (section erythrobalanus-fagaceae) species in different light environments. American Journal of Botany. 81(5):589-597. https://doi.org/10.2307/2445734
  2. Cho, J.H., S.G. Hong, and J.J. Kim. 1998. Growth and critical light intensity at cotyledon stage of Cornus controversa hemal. Seedling. Journal of Korean Forestry Society 87(3):493-500 (in Korean).
  3. Cho, M.S., K.W. Kwon, and J.H. Choi. 2007. Photosynthetic responses and growth performances in the three deciduous hardwood species under different shade treatments. Journal of Korean Forestry Society 96(4):462-469 (in Korean).
  4. Choi, J.H. 2001. Effects of artificial shade treatment on the growth performances, water relations, and photosynthesis of several tree species. Chungnam national university Doctor's dissertation p. 152 (in Korean).
  5. Dai Xiaobing. 1996. Influence of light conditions in canopy gaps on forest regeneration : a new gap light index and its application in a boreal forest in east-central Sweden. Forest Ecology and Management 84:187-197. https://doi.org/10.1016/0378-1127(96)03734-6
  6. Jeong, J.H., K.S. Koo, C.H. Lee, and C.S. Kim. 2002. Physico-chemical Properties of Korean Forest Soils by Regions. Journal of Korean Forestry Society 91(6):694-700 (in Korean).
  7. Kim, J.J. 2000. Studies on optimum shading for seedling cultivation of Cornus controversa and C. walteri. Journal of Korean Forestry Society 89(5):591-597 (in Korean).
  8. Kim, P.G., K.Y. Lee, S.S. Hur, S.H. Kim, and E.J. Lee. 2003. Effects of shading treatment on photosynthetic activity of Acanthopanax senticosus. Journal of Ecology and Field Biology 26(6):321-326 (in Korean). https://doi.org/10.5141/JEFB.2003.26.6.321
  9. Kim, P.G., Y.S. Yi, D.J. Chung, S.Y. Woo, J.H. Sung, and E.J. Lee. 2001. Effects of light intensity on photosynthetic activity of shade tolerant and intolerant tree species. Journal of Korean Forestry Society 90(4):476-487 (in Korean).
  10. Kim, Y.C. 1987. Effect of inorganic environmental factors on the growth on Pinus koraiensis seedlings (II) - The influence of root cuttings on the growth of seedlings grown on the transplanting bed -. Journal of Korean Forestry Society 76(3):218-229 (in Korean).
  11. Kim, Y.H. and D.K. Lee. 2000. Growth characteristics and physiological adaptation of Pinus densiflora seedling in the canopy gap. Journal of Korean Forestry Society 89(3):452-460 (in Korean).
  12. Korea Meteorological Administration (1998-2007). Monthly weather report (in Korean).
  13. Kwon, H.J. and H.K. Song. 2008. Vegettaion structures and ecological properties of sterwartia koreana community. Journal of Korean Forestry Society 97(3):296-304 (in Korean).
  14. Kwon, K.W., J.H. Choi, and J.C. Chung. 2000. Studies on the shade tolerance, light requirement and water relations of economic tree species (II). Journal of Korean Forestry Society 89(2):198-207 (in Korean).
  15. Kwon, K.W., M.S. Cho, G.N. Kim, S.W. Lee, and K.H. Jang. 2009. Photosynthetic characteristics and growth performances of containerized seedling and bare root seedling of Quercus acutissima growing at different fertilizing schemes. Journal of Korean Forestry Society 98(3):331-33 (in Korean)8.
  16. Lee, K.J. 2008. Tree Physiology. Seoul National University Press. p. 514 (in Korean).
  17. Lee, S.W., J.H. Choi, S.K. Yoo, S.K. Kim, J.H. Bae, and S.K. Han. 2006. Effect of raw material properties on growth characteristics of broad-leaved container seedlings. Journal of Bio-Environment Control. 15(3):244-249 (in Korean).
  18. Poorter, L. 1999. Growth responses of 15 rainforest tree species to a light gradient : the relative importance of morphological and physiological traits. Functional Ecology 13:396-410. https://doi.org/10.1046/j.1365-2435.1999.00332.x
  19. Reich, P.B., M.G. Tjoelker, M.N. Walters, D.W. Vanderklein, and C. Buschena. 1998. Close association of RGR, leaf and root morphology, seed mass and shade tolerance in seedlings of nine boreal tree species grown in high and low light. Functional Ecology 12:327-338. https://doi.org/10.1046/j.1365-2435.1998.00208.x
  20. Rural Development Administration. 2000. Analysis of soil and plant. Rural Development Administration. p. 202 (in Korean).
  21. SAS institute Inc. 2000. SAS/STAT TM Guide for Peronal Computer. Version 8 Edition. SAS Institute Inc., N. C. p. 1026.
  22. Schupp, E.W., H.F. Howe, C.K. Audspurger, and D.J. Levey. 1989. Arrival and survival in tropical tree fall gaps. Ecology 70:562-564. https://doi.org/10.2307/1940206
  23. Whitmore, T.C. 1989. Canopy gaps and the two major groups of forest trees. Ecology 70:536-538. https://doi.org/10.2307/1940195
  24. Yanai, R.D., M.J. Twery, and S.L. Stout. 1998. Woody understory response to changes in overstory density : thinning in Allegheny hardwoods. Forest Ecology and Management 102:45-60. https://doi.org/10.1016/S0378-1127(97)00117-5