Abstract
The Taihang Mountain Range is located at E112° 50’ – 114° 30’, N35° 20’ – 39° 30’ in North China. This study aimed to reveal relationships between plant communities, soil variables and topographic variables. Floristic data and environmental data from sixty-eight quadrats of 10 m x 20 m along an elevation gradient from 1050 to 2180 m were analysed by TWINSPAN, DCA and CCA. Eight vegetation formations were recognized, all secondary successional stages following the original broad-leaved deciduous forests’ distraction by human activities. The results showed that the community patterns are related to both soil variables and topographic variables. Among the soil variables, soil N, P, K and organic matter were found to be the most important factors forcing the spatial patterns of plant communities. The vegetation patterns were also significantly correlated with the topographic variables, elevation, slope and aspect. Interactions between the environmental variables were significant. It is concluded that further measures for the conservation of vegetation and protection of soils in the Taihang Mountains must be undertaken.
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Abbreviations
- CCA:
-
Canonical Correspondence Analysis
- DCA:
-
Detrended Correspondence Analysis
- IV:
-
Importance Value
- TWINSPAN:
-
Two Way INdicator SPecies ANalysis
References
Anderson, J. P. E. 1982. Soil respiration. In: A. L. Page (ed.), Methods of Soil Analysis, Chemical and Microbiological Properties, Part 2. American Society of Agronomy, Madison. pp. 831–871.
Bergmeier, E. 2002. The vegetation of the high mountains of Crete: A revision and multivariate analysis. Phytocoenologia 32: 205–249
Brunner, I., Rigling, D., Egli, S. and P. Blaser. 1999. Response of Norway spruce seedlings in relation to chemical properties of forest soils. Forest Ecology and Management 116: 71–81
Cannell, M, G, R, and M. D. Hooper. 1990. The greenhouse effect and terrestrial ecosystems of the UK. Research Publication 4, Institute of Terrestrial Ecology, London.
Chen, X., Li, B-L., Scott, T. A., Tennant, T. and M. F. Allen. 2005. Spatial structure of multispecies distributions in southern California, USA. Biological Conservation 124: 169–175
Cheng, Z. H. and J.-T. Zhang. 2003. Difference between tourism vegetation landscapes of different distance. Journal of Mountain Science 21: 647–652
Dirnbock, T., Dullinger, S. and G. Grabherr. 2003. A regional impact assessment of climate and land-use change on alpine vegetation. Journal of Biogeography 30: 303–322.
Ertli, T., Marton, A. and R. Foldenyi. 2004. Effect of pH and the role of organic matter in the adsorption of isoproturon on soils. Chemosphere 57: 771–779
Fosaa, A. M. 2004. Biodiversity patterns of vascular plant species in mountain vegetation in the Faroe Islands. Diversity and Distributions 10: 217–223
Gao, Q. and H.Y. Zheng. 1991. The application of fuzzy ISODATA clustering to quantitative analysis of grassland communities. Acta Phytoecologica et Geobotanica Sinica 15(4): 312–318.
Gerald, P. 2004. The high mountain vegetation of Turkey - A state of the art report, including a first annotated conspectus of the major syntaxa. Turkish Journal of Botany 28: 39–63
Glaser, B., Turrion, M-B., Solomon, D., Ni, A. and W. Zech. 2000. Soil organic matter quantity and quality in mountain soils of the Alay Range, Kyrgyzia, affected by land use change. Biology and Fertility of Soils 31: 407–413
Higashi,, T., Sohtome, R., Hayashi, H., Ohse, K., Sugimoto, T., Ohkawa, Y., Tamura, K. and M. Miyazaki, 2003. Influences of forest decline on various properties of soils on Mt. Hirugatake, Tanzawa Mountains, Kanto district, Japan. I. Changes in vegetation, soil profile morphology, and some chemical properties of soils. Soil Science and Plant Nutrition 49: 161–169
Hill, M. O. 1979. TWINSPAN – A Fortran program for arranging multivariate data in an ordered two-way table by classification of the individuals and atributes. Cornell University, Ithaca.
Hill, M. O. and H. G. Gauch. 1980. Detrended correspondence analysis£¬an improved ordination technique. Vegetatio 42:47–58
Holdridge, L. R. 1967. Life Zone Ecology. Tropical Science Centre, San Jose, Costa Rica.
Holten, J. I., Paulsen, G. and W. C. Oechel. 1993. Impacts of Climatic Change on Natural Ecosystems. NINA, Trondheim.
Leathwick, J. R. 1995. Climatic relationships of some New Zealand forest tree species. Journal of Vegetation Science 6:237–248
Liu, L. 1984. Plant resources and their utilization directions in Taihang Mountains. Scientia Geographica 4(3): 10–15
Liu, L. 1996. Vegetation in Hebei Province. Science Press, Beijing.
Liu, Z. Y. (ed ) 1992. Soils in Shanxi Province. Science Press, Beijing.
Liu, T.W. and Yue, J. Y. 2004. Flora Shanxiensis. China Science and Technology Press, Beijing.
Ma, Z. Q. 2001. Vegetation of Shanxi Province. China Science and Technology Press, Beijing.
Martins, D., Odd, E., Eli, F., Jonas, E. L. and A. Erik. 1999. Beech forest communities in the Nordic countries – a multivariate analysis. Plant Ecology 140: 203–220.
Mi, X-C. and J.-T. Zhang. 1995. Classification and ordination of Form. Quercus variabilis in Menghe Reservation, Shanxi Province. Bulletin of Botany 15: 397–402
Molles, M. C. 2002. Ecology: Concepts and Applications. 2nd ed. The McGraw-Hill Co., Singapore.
Paschke, M. W., Redente, E. F. and Brown, S. L. 2003. Biology and establishment of mountain shrubs on mining disturbances in the Rocky Mountains, USA. Land Degradation and Development 14: 459–480
Podani, J. 2000. Introduction to the Exploration of Multivariate Biological Data. Backhuys Publishers, Leiden.
Saarsalmi, A., Malkonen, E. and S. Piirainen, 2001. Effects of wood ash fertilization on forest soil chemical properties. Silva Fennica 35:355–368
Sanz-Elorza, M., Dana, E. D., Gonzalez, A. and E. Sobrino. 2003. Changes in the high-mountain vegetation of the central Iberian Peninsula as a probable sign of global warming. Annals of Botany 92: 273–280.
Sparks R.E. 1995. Need for ecosystem management of large rivers and their floodplains. BioScience 45: 168–182.
Steffen, W. L., Walker, B. H., Ingram, J. S. I. and G. H. Koch, (eds) 1992. Global Change and Terrestrial Ecosystems: The Operational Plan. Report No.21. IGBP, Stockholm.
Tasser, E. and U. Tappeiner, 2002. Impact of land use changes on mountain vegetation. Applied Vegetation Science 5: 173–184
ter Braak, C. J. F. and P. Šmilauer, 2001. CANOCO Reference Manual and User’s Guide to Canoco for Windows. Software for Canonical Community Ordination (version 4.5). Centre for Biometry Wageningen (NL) and Microcomputer Power (Ithaca NY, USA).
Ter Braak, C. J. F. 1986. Canonical correspondence analysis: a new eigenvector method for multivariate direct gradient analysis,. Ecology 67: 1167–1179.
Walter, H. 1979. Vegetation of the Earth and Ecological Systems of the Geo-biosphere. 2nd ed. Springer, New York.
Wang, Y. F. 1991. Vegetation Resources and their Utilization and Protection in Loess Plateau. Science and Technology Press, Beijing.
Wilson, S. M., Pyatt, D. G., Malcolm, D. C. and T. Connolly. 2001. The use of ground vegetation and humus type as indicators of soil nutrient regime for an ecological site classification of British forests. Forest Ecology and Management 140: 101–116
Woodward, F. I. (ed.) 1992. Global Climate Change: The Ecological Consequences. Academic Press, London.
Wu, Z.Y. 1980. Vegetation of China. Science Press, Beijing.
Yang, Y. H., Watanabe, M., Wang, Z., Sakura, Y. and C. Tang. 2003. Prediction of changes in soil moisture associated with climatic changes and their implications for vegetation changes: WAVES model simulation on Taihang Mountain, China. Climatic Change 57 (1-2): 163–183
Ye, Z. H., Shu, W. S., Zhang, Z. Q., Lan, C. Y. and Wong, M. H. 2002. Evaluation of major constraints to revegetation of lead/zinc mine tailings using bioassay techniques. Chemosphere 47: 1103–1111
Zhang, J-S., Meng, P., Yin, C. J. and Feng, W. D. 2002. Spatial and temporal distribution characteristics of wheat roots in apple-wheat intercropping. Forest Research 15: 537–541
Zhang, J-T. 1987. The main vegetation types and their rational utilization in Northwest Shanxi. J. Wuhan. Botanical Research 5:373–382.
Zhang, J-T. 1995. Quantitative Methods in Vegetation Ecology. China Sci. and Tech. Press, Beijing.
Zhang, J-T. 2002. A Study on Relations of Vegetation, Climate and Soils in Shanxi Province, China. Plant Ecology 162: 23–31.
Zhang, J-T. 2003. Applied Ecology. Science Press, Beijing.
Zhang, J-T. 2004. Quantitative Ecology. Science Press, Beijing.
Zhang, J-T. 2005. Succession analysis of plant communities in abandoned croplands in the Eastern Loess Plateau of China. Journal of Arid Environments 63: 458–474.
Zhang, J-T. and T.G. Chen. 2004. Variation of plant communities along an elevation gradient in the Guandi Mountains, North China. Community Ecology 5:227–233
Zhang, J-T. and J. H. 2001. The analysis of economic loss of ecological destruction in Shanxi, North China. China Softscience 16(5), 89–94.
Zhang, J,-T. and R. E. B. Oxley, 1994. A comparison of three methods of multivariate analysis of upland grasslands in North Wales. J. Veg. Sci. 5:71–76.
Zhang, J-T., Ru, W. M. and B.Li. 2006. Relationships between vegetation and climate on the Loess Plateau in China. Folia Geobotanica 41: 151–163.
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Zhang, J.T., Xi, Y. & Li, J. The relationships between environment and plant communities in the middle part of Taihang Mountain Range, North China. COMMUNITY ECOLOGY 7, 155–163 (2006). https://doi.org/10.1556/ComEc.7.2006.2.3
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DOI: https://doi.org/10.1556/ComEc.7.2006.2.3