Structure changes and succession dynamic of the natural secondary forest after severe fire interference

Bin-fan Liu; Guang-ju Liu; Zhi-cheng Wang

doi:10.1007/s11676-009-0022-2

Journal of Forestry Research ›› 2009, Vol. 20 ›› Issue (2) : 123 -130. DOI: 10.1007/s11676-009-0022-2

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Structure changes and succession dynamic of the natural secondary forest after severe fire interference

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Abstract

The structure and dynamic succession law of natural secondary forest after severe fire interference in recent 20 years were studied by adopting the method of deducing time series from the spatial sequence of vegetation in Heihe region, Heilongjiang, China. Two typical and widely distributed forest types in the study area, namely forest type A and forest type B, were selected as study subjects. Forest type A is pure broadleaf forest or broadleaf mixed forest mainly composing of superior Betula platyphylla and Populus davidiana in the area with gradient <25°, while forest type B is pure forest or mixed forest composing of superior Quercus mongolica and Betula davurica in the area with gradient >25°. Species richness, vegetation coverage, important value, and similarity index of community in different layers (Herb, shrub, small tree, and arbor layers) were investigated and analyzed for the two typical forests. The results show that after fire interference, the species richness and coverage in each layer in forest type A were higher than that in forest type B. Both for forest type A and B, with elapse of post-fire years, the species richness and coverage of herbs and shrubs showed a decline tendency, while those of arbor layer present a rising tendency. Through comparison of the important values of species in each layer and analysis of community structure changes, the dynamic process of post-fire vegetation succession for forest type A and B was separately determined. Post-fire 80 years’ succession tendency of forest type A is B. platyphylla and Larix gmelinii mixed forest. Its shrub layer is mainly composed of Corylus heterophylla and Vaccinium uliginosum, and herb layer is dominated by Carex tristachya, Athyrium multidentatum, and Pyrola incarnate; whereas, the post-fire 80 years’ succession of forest type B is Q. mongolica and B. davurica mixed forest. Its shrub layer is mainly composed of lespedeza bicolar and corylus heterophylla and herb layer is dominated by Carex tristachya, Asparagus densiflorus, and Hemerocallis minor.

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Bin-fan Liu, Guang-ju Liu, Zhi-cheng Wang. Structure changes and succession dynamic of the natural secondary forest after severe fire interference. Journal of Forestry Research, 2009, 20(2): 123-130 DOI:10.1007/s11676-009-0022-2

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References

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[1]	Attiwill P.M.. The disturbance of forest ecosystems: The ecological basis for conservative management. For Ecol Manage, 1994, 63(2–3): 247-300.

[2]	Borchert M., Johnson M., Schreiner D., et al. Early postfire seed dispersal, seed establishment and seed mortality of Pinuscoulteri (D.Don) in central coastal California, USA. Plant Ecol, 2003, 168: 207-220.

[3]	Cao C., Jiang D., Alamusa. Ecological process of vegetation restoration in Caragana mirophylla sand-fixing area. Chinese Journal of Applied Ecology, 2000, 11(3): 349-354.

[4]	Cwynar L.C.. Fire and the forest history of the North Cascade Range. Ecology, 1987, 68: 791-802.

[5]	Fastie C.L.. Causes and ecosystem consequences of multiple pathways of primary succession at Glacier Bay, Alaska. Ecology, 1995, 76: 1899-1916.

[6]	Gill A. M.. Fire and the Australian flora: a review. Aust For, 1975, 38: 1-25.

[7]	Grogan P., Bruns T.D., Chapin F.S. III. Fire effects on ecosystem nitrogen cycling in a Californian bishop pine forest. Oecologia, 2000, 122(4): 537-544.

[8]	Guo Z., Ma Y., Zheng J., Liu W., Jin Z.. Biodiversity of tree species, their populations’ spatial distribution pattern and interspecific association in mixed deciduous broadleaved forest in Changbai Mountains. Chinese Journal of Applied Ecology, 2004, 15(11): 2013-2018.

[9]	Hanes T.L., Jones H.. Post-fire chaparral succession in southern California. Ecology, 1967, 48: 257-264.

[10]	He H.S., Mladenoff D.J.. Spatially explicit and stochastic simulation of forest-landscape fire disturbance and succession. Ecology, 1999, 80(1): 81-99.

[11]	Keeley S.C., Keeley J.E., Hutchinson S.M., Johnson A.W.. Postfire succession of herbaceous flora in Southern California chaparral. Ecology, 1981, 62(6): 1608-1621.

[12]	Kercher J.R., Axelrod M.C.. A process model of fire ecology and succession in a mixed-conifer forest. Ecology, 1984, 65: 1725-1742.

[13]	Liu G., Hu H., Zhang H.. Reconstruction Method for Fire History of Natural Secondary Forests. Journal of Northeast Forestry University, 2008, 36(5): 75-77.

[14]	Lloret F., Calvo E., Pons X., et al. Wildfire and landscape dynamics in the Eastern Iberian Peninsula. Landscape Ecol, 2002, 17: 745-759.

[15]	Luo Dekun. Discussing the method of regeneration in postfire area in Daxinganling. Forestry Science and Technology, 1987, 53: 10-12. (in Chinese)

[16]	Phillips D.L., Shure D.J.. Patch-size effects on early succession in Southern Appalachian forests. Ecology, 1990, 71: 204-212.

[17]	Preston C.A., Baldwin I.T.. Positive and negative signals regulate germination in the post-fire annual, Nicotiana attenuata. Ecology, 1999, 80: 481-494.

[18]	Romme W.H.. Fire and landscape diversity in subalpine forests of Yellowstone national park. Ecol Monogr, 1982, 52(2): 199-221.

[19]	Schroeder D., Ajith H.P.. A comparison of large-scale spatial vegetation patterns following clearcuts and fires in Ontario’s boreal forests. For Ecol Manage, 2002, 159: 217-230.

[20]	Shafi M.I., Yarranton G.A.. Diversity, floristic richness, and species evenness during a secondary (post-fire) succession. Ecology, 1973, 54(4): 897-902.

[21]	Shu Lifu, Zuo Jichun, Tian Wentao. 1996. Discussion on natural regeneration in burned areas of Daxing’anling Mountains. Management of Forestry Resource, (6): 43–45 (in Chinese)

[22]	Shugart H.H., West D.C.. Forest succession models. Bio-Science, 1980, 30: 308-319.

[23]	Turner M. G., Romme W.H., Reed R.A., Tuskan G.A.. Postfire aspen seedling recruitment across the Yellowstone (USA) landscape. Landscape Ecology, 2003, 18: 127-140.

[24]	Wang X., Li X., He H., Leng W., Wen Q.. Postfire succession of larch forest in the northern slope of Daxing’anling. Chinese Journal of Ecology, 2004, 23(5): 35-41.

[25]	Wang X., Li X., He H., Xie F.. Long-term effects of different planting proportion on forest landscape in Daxing’anling Mountains after the catastrophic fire in 1987. Chinese Journal of Applied Ecology, 2006, 17(5): 855-861.

[26]	Wang X., Li X., He H.. Spatial simulation of forest succession under different fire disturbances and planting strategies in northern slopes of Daxing’anling Mountains. Journal of Beijing Forestry University, 2006, 28(1): 14-22.

[27]	White P.S.. Process and natural disturbance in vegetation. Bot Rev, 1979, 45: 229-299.

[28]	Xu H., Li Z., Qiu Y.. Fire disturbance history in virgin forest in northern region of Daxing’anling Mountains. Acta Ecol Sin, 1997, 17(4): 337-343.

[29]	Yang Y., Li Z.. The summary about fires having impact on nitrogen cycle in forest ecosystems. Journal of Fujian Forestry College, 1992, 12(1): 1052-1111.

[30]	Zhang J., Zhao H., Zhang T.. Dynamics of species diversity of communities in restoration processes in Horqin sandy land. Journal of Plant Ecology, 2004, 28(1): 86-92.

[31]	Zhang W., Xu X., Zhou J.. Study on population dynamics of Abies chensiensis, an endangered species. Chinese Journal of Applied Ecology, 2005, 16(10): 1799-1804.

[32]	Zhang Y., Cao T., Pan B.. Species diversity of floor bryophyte communities in Bogda Mountains, Xinjiang. Chinese Journal of Applied Ecology, 2003, 14(6): 887-891.