北京市延庆采砂迹地型湿地植被群落分类与演替分析

Abstract
Figure/Table
References
Related Citation (15)

Download: PDF (856 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract

In this paper,we analyzed and ordered the 51 plant species in 40 sampling locations in trail wetlands in Yanqing County, Beijing City by using TWISPAN analysis,and divided the vegetation communities into seven types,which were type Artemisia capillaris-Setaria viridis-Artemisia annua,type Artemisia lavandulaefolia-Artemisia capillaris-Lespedeza caraganae-Setaria viridis, type Artemisia lavandulaefolia-Artemisia capillaris-Setaria viridis-Glycine soja-Sonchus arvensis,type Setaria viridis-Xanthium sibiricum-Melilotus officinalis-Chloris virgate,type Bidens tripartita-Artemisia lavandulaefolia-Inula japonica-Artemisia sieversiana-Phragmites australis,type Typha orientalis-Phragmites australis-Zizania latifolia-Glycine soja-Bidens bipinnata,and type Juncus effusus-Cyperus fuscus-Echinochloa crusgalli.We also sorted and analyzed the 51 plant species by double variables principal coordinates analysis(DPCoA).The results showed that there were two succession rules for plant communities in this area,which were the succession from typical stand wetland plant species to ordinary wetland plant species,and the succession from hygrophilous plants to terraneous plants.The vegetation restoration in sand-mining wetland should not only restore soil nutrient,but also regulate water condition.The findings can provide a scientific support for mining trail wetlands restoration.

Key words： plant community double variables principal coordinates analysis(DPCoA) community succession wetland

Received: 25 October 2011

:	Q941.2
	Q948.11

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	ZHAO Xin-sheng
	CUI Li-juan
	LI Wei
	ZHANG Man-yin
	WANG Yi-fei
	LI Sheng-nan

Cite this article:

ZHAO Xin-sheng,CUI Li-juan,LI Wei, et al. Study on vegetation community classification and succession of sand-mining wetland in Yanqing County,Beijing[J]. , 2011, 30(5): 518-524.

URL:

http://www.ecolsci.com/EN/ OR http://www.ecolsci.com/EN/Y2011/V30/I5/518

[1] Carlo R.Additive partitioning of Rao's quadratic diversity:a hierarchical approach[J].Ecological Modelling,2005,183:365-371.
[2] Carlo R,Laszlo S.Towards a unifying approach to diversity measures:Bridging the gap between the Shannon entropy and Rao's quadratic index[J].Theoretical Population Biology,2006:70,237-243.
[3] Ihaka R,Gentleman R R.A language for data analysis and graphics[J].Journal of Computational and Graphical Statistics,1996,5:299-314.
[4] Izsák J,Papp L.Application of the quadratic entropy index for diversity studies on drosophilid species assemblages[J].Environmental and Ecological Statistics,1995,2:213-224.
[5] Marie-Louise S.Community and edaphic analysis of upland northern hardwood communities,central Vermont,USA[J].Forest Ecology and Management,1995,72:235-249.
[6] Rao C R.Diversity and dissimilarity coefficients:a unified approach[J].Theoretical Population Biology,1982,21:24-43.
[7] Rao C R.Rao's axiomatization of diversity measures.In:Kotz S,Johnson NL(Eds.),Encyclopedia of Statistical Sciences[M].Wiley,New York.1986.614-617.
[8] Sandrine P,Anne-Beatrice D,Daniel C.From dissimilarities among species to dissimilarities among communities:a double principal coordinate analysis[J].Journal of Theoretical Biology,2004,228:523-537.
[9] Sobolev L N,Ntehin V D.Russian(Ramensky) approaches to community systematization[M].In:Whittaker R.H.ed.Ordination and Classfication of Communities.Junk:The Hague,1973:75-103.
[10] Pavoine S,Ollier S,Pontier D.Measuring diversity from dissimilarities with Rao's quadratic entropy:Are any dissimilarities suitable[J].Theoretical Population Biology,2005,67:231-239.
[11] Swain M D,Greig-Sminth P.An application of principle component analysis to vegetation change in permanent plots[J].Journal of Ecology,1980,68:33-41.
[12] Warwick R M,Clarke K R.New ‘biodiversity' measures reveal a decrease in taxonomic distinctness with increasing stress[J].Marine Ecology-Progress Series,1995,129:301-305.
[13] Watve M G,Gangal R M.Problems in measuring bacterial diversity and a possible solution[J].Applications of Environmental Microbiology,1996,62:4299-4301.
[14] Hill M.O.TWINSPAN-A FORTRAN Program for Arranging Multivariate Data in an Ordered Two-way Table by Classification of the Individuals and Attributes Ithaca[M].New York:Comell University.1979.
[15] 贺强,崔保山,赵欣胜,等.水盐梯度下黄河三角洲湿地植被空间分异规律的定量分析[J].湿地科学.2007,5(3):208-214.
[16] 李伟,崔丽娟,赵欣胜,等.采砂迹地型湿地恢复过程中植物群落分布与土壤环境因子的关系[J].生态环境学报,2010,19(10):2325-2331.
[17] 张金屯.群落演替的数量分析方法[J].山西大学学报(自然科学版),1994,17(4):457-463.
[18] 上官铁梁,张金屯.植物群落永久样方演替数据分析方法-类中心排序法[J].生态学报,2000,增刊:45-48.
[19] Gauch H.G.Multivariate Analysis in Community Ecology[M].Cambridge University Press,Cambridge,England.1982,298 pages.Chinese edition,1989.
[20] Jafaria M,Zare C M A,Tavilib A.Effective environmental factors in the distribution of vegetation types in Poshtkouh rangelands of Yazd Province(Iran)[J].Journal of Arid Environments,2004,56:627 641.
[21] Helge B,Pit U.Correspondence of the fine-scale spatial variation in soil chemistry and the herb layer vegetation in beech forests[J].Forest Ecology and Management,2005,210:205-223.
[22] Zhao X S.Cui B S,Yang Z F.The Key Environmental Factors of Vegetation Degraded in the Yellow River Delta[A], Proceeding of the 3rd international Yellow River Forum on sustainable water resourcesmanagement and delta ecosystem maintenance[C], 2007,Vol Ⅱ:121-130.