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Effect of Forest Composition and Dynamics of Light on Seedlings and Saplings of Korean Pine (Pinus koraiensis) in Northeastern China


Affiliations
1 College of Forestry, Beijing Forestry University, Beijing, China
2 Institute of Forestry Survey and Design of Sichuan Province, Chengdu, Sichuan, China
3 Chinese Research Academy of Environmental Science, Beijing, China
 

Natural regeneration of Korean pine (Pinus koraiensis Siebold&Zucc.) in northeastern China has often been problematic in mixed broad-leaved Korean pine forests (primary forest), but not in deciduous broadleaved forests (secondary forest). Light transmittance, soil temperature, leaf area index (LAI), height and diameter of Korean pines were estimated in order to examine the contribution of composition and the dynamics of light to Korean pine regeneration in two forests. A spatial point pattern analysis was carried out to investigate the response of seedlings and saplings to light regimes and their relationship with mature trees, graded by size. We draw the following results: (1) light conditions were better in the secondary forest than in the primary forest in late spring (June and July) before the leaf expansion and the secondary forest received more light before leaf expansion and less light penetration in the early summer (August); (2) our spatial analysis indicated that seedlings are negatively correlated with saplings and exhibit a higher degree of clumping than saplings. Relationships of seedlings with mature pines and all sizes of other mature trees appeared random, whereas saplings were negatively associated with small, medium and large mature trees. Our findings suggest that the effect of forest composition on regeneration mainly occurred before the leaf expansion in late spring.

Keywords

Korean Pine Forest, Regeneration, Seedlings and Saplings, Leaf Expansion, Spatial Point Pattern Analysis.
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  • Calvo, L., Tarrega, R. and Luis, E. 2002. Regeneration patterns in a Calluna vulgaris heathland in the Cantabrian mountains (NW Spain): effects of burning, cutting and ploughing. Acta Oecol., 23(2): 81-90.

  • Dai, X.B. 1996. Influence of light conditions in canopy gaps on forest regenerationa new gap light index and its application in a boreal forest in east-central Sweden. For. Ecol. Manag., 84(1-3): 187-197.

  • Diggle P.J. 2003. Statistical Analysis of Point Patterns. Second ed., London: Arnold, 159 pp.

  • Ding, B.Y., Zhang, S.Y. and Cheng, X.W. 1994. The theory and technique of planting artificial Korean pine forest. Haerbin: Helongjiang Science and Technology Press, pp. 56-60 (in Chinese).

  • Emborg, J. 1998. Understory light conditions and regeneration with respect to the structural dynamics of a near-natural temperate deciduous forest in Denmark. For. Ecol. Manag., 106: 83-95.

  • George, L.W.P., Miller, B.P. and Enright, N.J. 2006. A comparison of methods for the statistical analysis of spatial point patterns in plant ecology. Plant Ecol., 187(1): 59-82.

  • Hao, Z.Q., Zhang, J., Li, B.H., Ye, J., Wang, X.G. and Yao, X.L. 2008. Broad-leaved Korean pine (Pinus koraiensis) mixed forest plot in Changbaishan (CBS) of China: community composition and structure. Journal of Plant Ecology, 32(2): 238-250 (in Chinese with English abstract).

  • Hartman, J.P., Buckley, D.S. and Sharik, T.L. 2005. Differential success of oak and red maple regeneration in oak and pine stands on intermediatequality sites in northern Lower Michigan. For. Ecol. Manag., 216(1): 77-90.

  • Illian, J., Penttinen, A., Stoyan, H. and Stoyan, D. 2008. Statistical Analysis and Modeling of Spatial Point Patterns. Chichester: John Wiley & Sons, pp. 560.

  • Koehler, H.H. 2000. Natural regeneration and succession - results from a 13 years study with reference to mesofauna and vegetation, and implications for management. Landscape Urban Plan, 51: 123-130.

  • Li, J.Q., Chai, Y.X., Zhu, C.Q. and Wang, Y.Q. 1991. Seasonal pattern of photosynthesis and nutrient content of Korean pine seedlings under different light conditions. Chinese Journal of Ecology, 10(5): 1-5 (in Chinese with English Abstract).

  • Li, J.Q. and Li, J.W. 2003. Regeneration and restoration of broad-leaved Korean pine forests in Lesser Xingan mountains of northeast China.Acta Ecologica Sinica, 23(7): 1268-1277 (in Chinese with English Abstract).

  • Li, J.Q., Xu, L.Y. and Wang, Y.J. 1987. Influence of storage and distribution of nitrogen and phosphorus on seedling growth of Korean pine under virginal forest. Ecol., 6(5): 3-6.

  • Liu, C.Z. and Li, Z.Q. 1987. Habitant under birch-aspen forest and natural recruitment of Korean pine. Journal of Northeast Forestry University, 15: 22-28 (in Chinese with English Abstract).

  • Lu, Z.Y. and Jiang, J.D. 1980. Annual growth cycle of Korean pine seedling. Scientia Silvae Sinicae, (1): 66-69 (in Chinese with English Abstract).

  • Martinez, I., González, T.F., Wiegand, T. and Obeso, J.R. 2013. Spatial patterns of seedling-adult associations in a temperate forest community. For. Ecol. Manag., 296: 74-80.

  • McIntyre, E.J.B. and Fajardo, A. 2009. Beyond description: the active and effective way to infer processes from spatial patterns. Ecology, 90(1): 46-56.

  • Smith, E.A., O Loughlin, D., Buck, J.R. and St Clair, S.B. 2011. The influences of conifer succession, physiographic conditions and herbivory on quaking aspen regeneration after fire. For. Ecol. Manag., 262(3): 325-330.

  • Schurr, F.M., Bossdorf, O., Milton, S.J. and Schumacher, J. 2004. Spatial pattern formation in semi-arid shrubland: a priori predicted versus observed pattern characteristics. Plant Ecol., 173(2): 271-282.

  • Szwagrzyk, J. and Bodziarczyk, J. 2001. Dynamics of seedling banks in beech forest: results of a 10 year study on germination, growth and survival. For. Ecol. Manag., 141(3): 237-250.

  • Tang, C.Q., He, L.Y., Su, W.H., Zhang, G.F., Wang, H.C., Peng, M.C., Wu, Z.L. and Wang, C.Y. 2013. Regeneration, recovery and succession of a Pinus yunnanensis community five years after a mega-fire in central Yunnan, China. For. Ecol. Manag., 294: 188-196.

  • Wang. S.L. and Ge, J.P. 1993. Study of the natural regeneration pattern and process of Korean pine population under natural poplar-birch forest in the Xiaoxingan Mountains. Journal of Northeast Forestry University, 21: 7-13 (in Chinese with English Abstract).

  • Wiegand, T., Gunatilleke, S. and Gunatilleke, N. 2007. Species associations in a heterogeneous Sri Lankan dipterocarp forest. Am. Nat., 170(4): 67-95.

  • Wiegand, T., Huth, A. and Martlnez, I. 2009. Recruitment in tropical tree species: revealing complex spatial patterns. Am. Nat., 174(4): 106-140.

  • Wiegand, T. and Moloney, K.A. 2004. Rings, circles and null-models for point pattern analysis in ecology. Oikos., 104(2): 209-229.

  • Yang, H.X. 1985. Distribution patterns of dominant tree species on northern slope of Changbai Mountain. Forest Ecosystem Research, 5: 1-14 (in Chinese with English Abstract).

  • Yuan, F. H. Guan, D. X. Wu, J. B. Wang, A. Z., Shi, T. T. and Zhang, X. J. 2008. Spatiotemporal characteristics of photosynthetically active radiation in understory of Korean pine and broadleaved mixed forest in Changbai Mountains. Chinese Journal of Applied Ecology, 19(2): 231-237 (in Chinese with English Abstract).

  • Zhao, F., Yang, J., He, H.S. and Dai, L. 2013. Effects of natural and humanassisted regeneration on landscape dynamics in a Korean pine forest in Northeast China. PLoS One, 8(12): e82414.


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  • Effect of Forest Composition and Dynamics of Light on Seedlings and Saplings of Korean Pine (Pinus koraiensis) in Northeastern China

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Authors

Junlong Yang
College of Forestry, Beijing Forestry University, Beijing, China
Guochun Zhang
Institute of Forestry Survey and Design of Sichuan Province, Chengdu, Sichuan, China
Wenhui Liu
Chinese Research Academy of Environmental Science, Beijing, China
Qijing Liu
College of Forestry, Beijing Forestry University, Beijing, China

Abstract


Natural regeneration of Korean pine (Pinus koraiensis Siebold&Zucc.) in northeastern China has often been problematic in mixed broad-leaved Korean pine forests (primary forest), but not in deciduous broadleaved forests (secondary forest). Light transmittance, soil temperature, leaf area index (LAI), height and diameter of Korean pines were estimated in order to examine the contribution of composition and the dynamics of light to Korean pine regeneration in two forests. A spatial point pattern analysis was carried out to investigate the response of seedlings and saplings to light regimes and their relationship with mature trees, graded by size. We draw the following results: (1) light conditions were better in the secondary forest than in the primary forest in late spring (June and July) before the leaf expansion and the secondary forest received more light before leaf expansion and less light penetration in the early summer (August); (2) our spatial analysis indicated that seedlings are negatively correlated with saplings and exhibit a higher degree of clumping than saplings. Relationships of seedlings with mature pines and all sizes of other mature trees appeared random, whereas saplings were negatively associated with small, medium and large mature trees. Our findings suggest that the effect of forest composition on regeneration mainly occurred before the leaf expansion in late spring.

Keywords


Korean Pine Forest, Regeneration, Seedlings and Saplings, Leaf Expansion, Spatial Point Pattern Analysis.

References