Journal of the Korean Wood Science and Technology

The Korean Society of Wood Science & Technology (한국목재공학회)
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Comparison of Cellular Anatomical, Physical and Mechanical Properties Between Dahurian Larch and Japanese Larch

잎갈나무와 일본잎갈나무의 해부학적, 물리·역학적 특성 비교

  • Han, Yeonjung (Department of Forest Products, National Institute of Forest Science) ;
  • Kim, Min-Ji (Department of Forest Products, National Institute of Forest Science) ;
  • Lee, Hyun-Mi (Department of Forest Products, National Institute of Forest Science) ;
  • Kang, Jin-Taek (Department of Forest Policy and Economics, National Institute of Forest Science) ;
  • Eom, Chang-Deuk (Department of Forest Products, National Institute of Forest Science)
  • 한연중 (국립산림과학원 임산공학부) ;
  • 김민지 (국립산림과학원 임산공학부) ;
  • 이현미 (국립산림과학원 임산공학부) ;
  • 강진택 (국립산림과학원 산림정책연구부) ;
  • 엄창득 (국립산림과학원 임산공학부)
  • Received : 2017.07.12
  • Accepted : 2017.07.31
  • Published : 2017.09.25
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Abstract

The study aims to observe the cellular anatomical properties of Dahurian larch and Japanese larch for the species identification. In addition, other factors - the ring width, tracheid length, density, and strength - were compared and analyzed to clarify their physical and mechanical properties. To the end, three Dahurian larch trees and three Japanese larch trees by each diameter class were collected as specimens from Jeongseon-eup, Jeongseon-gun, Gangwon-do, to conduct a stem analysis. It was found that the average stand age, average diameter at breast height, and average tree height of three Dahurian larch trees and Japanese larch trees were 74 years and 51 years, 442 mm and 352 mm, and 26.1 m and 20.8 m, respectively. The cellular anatomical difference between Dahurian larch and Japanese larch can be usually found by spiral thickening, considering that it doesn't occur in Dahurian larch at all, while rarely does in the ray tracheids of Japanese larch. However, in this study, spiral thickening was not observed in the radial section of Japanese larch. The average annual growth diameters measured at 1.2 m-height of Dahurian larch and Japanese larch were 5.167 mm and 5.954 mm, respectively. Meanwhile, arboreal growth of Japanese larch was observed to be higher than that of Dahurian larch. In the physical properties test, it was measured that the latewood proportion and oven-dry density of Dahurian larch with low annual diameter growth were higher than those of Japanese larch, while the mechanical properties of Dahurian larch wood were measured 2-7% higher than those of Japanese larch wood. The data obtained from this study are expected to be used as the basic reference for species identification between Dahurian larch and Japanese larch by DNA analysis.

잎갈나무와 일본잎갈나무의 종 구분을 위하여 해부학적 특성을 관찰하고, 재질의 특성을 밝히기 위하여 연륜폭, 가도관 길이, 밀도, 강도 등을 비교분석하였다. 수간해석와 시험편 채취를 위하여 강원도 정선군 정선읍 지역에서 생장한 잎갈나무와 일본잎갈나무를 경급별(대 중 소)로 1본씩 선발하여 벌채하였다. 잎갈나무와 일본잎갈나무의 평균 수령은 각각 74년, 51년, 평균 흉고지름은 각각 442 mm, 352 mm, 평균 수고는 각각 26.1 m, 20.8 m이었다. 두 수종의 수목해부학적 차이는 나선비후가 잎갈나무에 존재하지 않지만, 일본잎갈나무의 방사가도관에 드물게 존재한다는 점이다. 하지만 본 연구에서는 잎본잎갈나무의 방사단면에서 나선비후가 발견되지 않았다. 수고 1.2 m의 원판에서 측정된 잎갈나무와 일본잎갈나무의 연평균 직경생장은 각각 5.167 mm, 5.954 mm로 일본잎갈나무의 생장이 잎갈나무에 비하여 우수하였다. 강도측정을 위한 시험편의 물리적 특성에서 연평균 직경생장이 작은 잎갈나무가 일본잎갈나무에 비하여 만재율과 전건밀도가 크게 측정되었다. 역학적 특성은 잎갈나무가 일본잎갈나무에 비하여 2 - 7% 크게 측정되었다. 본 연구를 통하여 축적된 자료는 향후 수행될 DNA 분석을 통한 잎갈나무와 일본잎갈나무 종 구분의 기초자료로 활용될 것으로 기대된다.

Keywords

References

  1. Bao, F.C., Jiang, Z.H., Jiang, X.M., Lu, X.X., Luo, X.Q., Zhang, S.Y. 2001. Differences in wood properties between juvenile wood and mature wood in 10 species grown in China. Wood Science and Technology 35(4): 363-375. https://doi.org/10.1007/s002260100099
  2. Boone, R.S., Kozlik, C.J., Bios, P.J., Wengert, E.M. 1988. Dry Kiln Schedules for Commercial Woods-Temperate and Tropical (Gen Tech Rep FPL-STR-57). Forest Products Laboratory, Madison, USA.
  3. Choi, Y.-S., Oh, S.-M., Kim, G.-H. 2011. Evaluation of pretreatment moisture content and fixation characteristics of treated wood for pressure treatment of Japanese red pine and Japanese larch skin timber with ACQ, CUAZ and CuHDO. Journal of The Korean Wood Science and Technology 39(6): 481-489. https://doi.org/10.5658/WOOD.2011.39.6.481
  4. Chong, S.-H., Won, K.-R., Hong, N.-E., Park, B.-S., Lee, K.-J., Byeon, H.-S. 2014. Bending and compressive strength properties of Larix kaempferi according to thinning intensity. Journal of The Korean Wood Science and Technology 42(4): 385-392. https://doi.org/10.5658/WOOD.2014.42.4.385
  5. Eom, Y.G. 2015. Wood Anatomy of Korean Species. Media Wood., Ltd., Seoul, Korea.
  6. Fujimoto, T., Koga, S. 2010. An application of mixed-effects model to evaluate the effects of initial spacing on radial variation in wood density in Japanese larch (Larix kaempferi). Journal of Wood Science 56(1): 7-14. https://doi.org/10.1007/s10086-009-1045-1
  7. Han, Y., Lee, H.M., Eom, C.D. 2016. Physical and mechanical properties of Korean red pine wood from different growth sites and correlations between them. Journal of The Korean Wood Science and Technology 44(5): 695-704. https://doi.org/10.5658/WOOD.2016.44.5.695
  8. Hwang, K., Park, B.-S. 2007. Strength properties of old Korean larch pile. Journal of The Korean Wood Science and Technology 35(6): 23-30.
  9. Ishikura, Y., Matsumoto, K., Ohashi, Y. 2012. Radial variation in partial compression properties perpendicular to the grain of Japanese larch (Larix kaempferi). Journal of Wood Science 58(5): 399-407. https://doi.org/10.1007/s10086-012-1273-7
  10. Jo, J.M., Kang, S.K., Huh, N.J., Park, S.J. 1988. Illustrated World Wood. Seonjinmunhwa Press, Seoul, Korea.
  11. Jung, H.S. 2005. Terminology of Wood. Seoul National University Press, Seoul, Korea.
  12. Jyske, T., Makinen, H., Saranpaa, P. 2008. Wood density within Norway spruce stems. Silva Fennica 42(3): 439-455.
  13. Kang, J.T., Son, Y.M., Yim, J.S., Jeon, J.H. 2016. Estimation of carbon stock and uptake for Larix kaempferi Lamb.. Journal of Climate Change Research 7(4): 499-506. https://doi.org/10.15531/ksccr.2016.7.4.499
  14. Kim, G.-H., Kim, H.-J., Kim, J.-J. 2001. Fixation characteristics of CCA and CCFZ in Japanese red pine, Japanese larch, and ezo spruce sapwood. Journal of The Korean Wood Science and Technology 29(1): 52-59.
  15. Kim, K.-H., Hong, S.-I. 2008. Bearing properties of domestic larix glulam. Journal of The Korean Wood Science and Technology 36(4): 93-101.
  16. Kim, S.-H., Yang, I., Han, G.-S. 2015. Effect of sawdust moisture content and particle size on the fuel characteristics of wood pellet fabricated with Quercus mongolica, Pinus densiflora, and Larix kaempferi sawdust. Journal of The Korean Wood Science and Technology 43(6): 757-767. https://doi.org/10.5658/WOOD.2015.43.6.757
  17. Kim, S.T., Lee, J.-J., Park, D.-H., Yang, I., Han, G.-S., Ahn, B.J. 2015. Effect of torrefaction condition on the chemical composition and fuel characteristics of larch wood. Journal of The Korean Wood Science and Technology 43(1): 122-134. https://doi.org/10.5658/WOOD.2015.43.1.122
  18. Koga, S., Zhang, S.Y. 2004. Inter-tree and intra-tree variations in ring width and wood density components in balsam fir (Abies balsamea). Wood Science and Technology 38(2): 149-162. https://doi.org/10.1007/s00226-004-0222-z
  19. Kong, W.S. 2006. Natural Ecosystem of North Korea. Jipmoondang, Seoul, Korea.
  20. Korea Forest Service. 2016. Statistical yearbook of forestry. Korea Forest Service, Daejeon, Korea.
  21. Korea Standard Association. 2004. Method of compression test for wood. KS F 2206.
  22. Korea Standard Association. 2004. Method of bending test for wood. KS F 2208.
  23. Korea Standard Association. 2004. Method of shear test for wood. KS F 2209.
  24. Kretschmann, D.E. 2010. Mechanical Properties of Wood. In: (Centennial Eds) Wood Handbook: Wood as an Engineering Material. Forest Products Laboratory, Madison, USA.
  25. Lee, J.J., Kim, G.C., Kim, K.M., Oh, J.K. 2003. Distribution characteristic of bending properties for visual graded lumber of Japanese larch. Journal of The Korean Wood Science and Technology 31(5): 72-79.
  26. Seo, J.-W., Eom, C.-D., Park, S.-Y. 2014. Study on the variation of inter-annual tracheid length for Korean red pine from Sokwang-ri in Uljin. Journal of The Korean Wood Science and Technology 42(6): 646-652. https://doi.org/10.5658/WOOD.2014.42.6.646
  27. Smith, D.M. 1955. A comparison of two methods for determining the specific gravity of small samples of second growth Douglas-fir (Rep No. 2033). Forest Products Laboratory, Madison, USA.
  28. Takahashi, M., Hosoda, K., Nishizono, T., Takao, G., Saito, H., Ishibashi, S., Furuya, N., Kodani, E., 2015. Resources and growth Japanese Larch (Larix kaempferi) in Japan. Chiayi city, Taiwan, Proc. of The 2015 International Symposium of Sustainable Forest Ecosystem Management in Rapidly Changing World (SFEM 2015).
  29. Takeda, T., Hashizume, T. 2000. Effective sampling method for estimating bending strength distribution of Japanese larch square-sawn timber. Journal of Wood Science 46(5): 350-356. https://doi.org/10.1007/BF00776395
  30. Wimmer, R., Downes, G.M. 2003. Temporal variation of the ring width-wood density relationship in Norway spruce grown under two levels of anthropogenic disturbance. IAWA Journal 24(1): 53-61. https://doi.org/10.1163/22941932-90000320
  31. Yim, K.B. 1985. Silviculture theory. Hyangmun Press, Seoul, Korea.
  32. Zhang, S.Y. 1998. Effect of age on the variation, correlations and inheritance of selected wood charicteristics in black spruce (Picea mariana). Wood Science and Technology 32(3): 197-204. https://doi.org/10.1007/BF00704842
  33. Zhu, J., Nakano, T., Hirakawa, Y. 1998. Effect of growth on wood properties for Japanese larch (Larix kaempferi): Differences of annual ring structure between corewood and outerwood. Journal of Wood Science 44(5): 392-396. https://doi.org/10.1007/BF01130453