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Volume 35 Issue 1
Feb.  2016
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Article Navigation >  CARSOLOGICA SINICA  > 2016  >  35(1): 11-18
ZHANG Ying, LIU Chang, SONG Ang, JIN Zhen-jiang, LI Qiang. Relationship between soil physicochemical properties and soil enzyme activities in Huixian karst wetland system based on Canonical Correspondence Analysis[J]. CARSOLOGICA SINICA, 2016, 35(1): 11-18. doi: 10.11932/karst20160103
Citation: ZHANG Ying, LIU Chang, SONG Ang, JIN Zhen-jiang, LI Qiang. Relationship between soil physicochemical properties and soil enzyme activities in Huixian karst wetland system based on Canonical Correspondence Analysis[J]. CARSOLOGICA SINICA, 2016, 35(1): 11-18. doi: 10.11932/karst20160103
shu

Relationship between soil physicochemical properties and soil enzyme activities in Huixian karst wetland system based on Canonical Correspondence Analysis

doi: 10.11932/karst20160103
  • 1.

    Environmental Science and Engineering College, Guilin University of Technology/Institute of Karst Geology,CAGS/Key Laboratory of Karst Dynamics, MLR & GZAR

  • 2.

    Institute of Karst Geology,CAGS/Key Laboratory of Karst Dynamics, MLR & GZAR

  • 3.

    Environmental Science and Engineering College, Guilin University of Technology

  • Publish Date: 2016-02-25
    Abstract
  • Wetland as an important ecological system plays an important role in regulating water and climate change, which was affected by human activities. Therefore, wetland degradation becomes a global phenomenon and the focus of many scientists. Huixian karst wetland system has the research base for comprehensive control of karst ecology and rocky desertification, belonging to original semi-disturbed wetland where in the past 20 years fertilizers have been applied to paddy field and dry land. In order to reveal the relationship between soil physicochemical properties and soil enzyme activities in Huixian karst wetland system, soil samples from three kinds of lands (wetland, paddy field and dry land) were collected. To gain a better understanding of the impact from the human and agricultural activities on the karst wetland system, a suitable evaluation method based on descriptive analysis, correlation analysis and canonical correspondence analysis (CCA) was employed. The highest content of soil organic carbon, total nitrogen, alkali-hydrolyzable nitrogen, cation exchange capacity, exchangeable calcium and exchangeable magnesium appears in the wetland, followed by the paddy field and dry land, respectively; the lowest content of available phosphorus and potassium occurs in the wetland. Therefore, the karst wetland system has an important function in the maintenance of soil carbon sink and nutrition cycle. The content of available phosphorus and potassium in wetland was lower than those in the paddy field and dry land,which was affected by human and agricultural activities. The concentrations of urease, invertase, alkaline phosphatase and cellulose are also quite high in the wetland and show a strong spatial heterogeneity. By analyzing soil factors and soil enzymes confined to wetland and paddy field of the study area, the CCA biplot shows a trend of land degradation in this area, from which it can be seen that the wetland is influenced by human activities. Wetland was first cultivated as paddy field, later it was eventually reclaimed into dry land with the decline of soil natural fertility. Therefore, among these three types of lands, the wetland has a high carbon storage function, while the paddy field has the similar one. If the ecological succession is irreversible, the best way to maintain the ecological environment of wetland system is to protect paddy field as constructed wetland. It is also important to regulate and promote carbon sequestration in karst area.

     

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    米彩红,刘增文,李茜.黄土丘陵区3种典型人工阔叶纯林枯落物分解对土壤性质极化的影响[J].西北农林科技大学学报(自然科学版),2012,40(7):120-126.
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    [75]
    杨宁,杨满元,雷玉兰,等.衡阳紫色土丘陵坡地土壤酶活性对植被恢复的响应[J].生态环境学报,2014,23(4):575-580.
    [76]
    曹彤,江源,宋阳,等.陕北种植业土地利用与农业投入关系的典范对应分析[J].资源科学,2005,27(4):56-62.
    [77]
    岳跃民,王克林,张伟,等.基于典范对应分析的喀斯特峰丛洼地土壤-环境关系研究[J].环境科学,2008,29(5):1400-1405.
    [78]
    Ter Braak C J F.Canonical correspondence analysis:A new eigenvector technique for multivariate direct gradient analysis[J].Ecology,1986,67(5):1167-1179.
    [79]
    Mench M,Bes C.Assessment of ecotoxicity of topsoils from a wood treatment site[J].Pedosphere,2009,19(2):143-155.
    [80]
    汪良奇,张强,萧良坚,等.基于湖积物硅藻与地球化学记录的古环境变迁反演:以桂林会仙岩溶湿地为例[J].中国岩溶,2014,33(2):129-135.
    [81]
    丁长欢,慈恩,邵景安,等.近30年黔西喀斯特区典型县域农田土壤有机碳动态研究:以贵州普定县为例[J].中国岩溶,2015,34(3):281-291.
    [82]
    方芳,靳振江,李强,等.岩溶区与非岩溶区土壤有机碳、养分及特征元素对比研究[J].桂林理工大学学报,2015,已接收.
    [83]
    徐琪.湿地农田生态系统的特点及其调节[J].生态学杂志,1989, 8(3):8-13,23.
    [84]
    邱峰.百万亩水稻田纳入湿地保护[EB/OL].[2011-10-28] http://www.nb.suzhou.gov.cn/newsview.asp? id=1359.
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