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水分含量对秸秆还田土壤碳矿化和微生物特性的影响
引用本文:CHEN Lin,ZHANG Jia-Bao,ZHAO Bing-Zi,XIN Xiu-Li,ZHOU Gui-Xiang,TAN Jin-Fang,ZHAO Jin-Hua. 水分含量对秸秆还田土壤碳矿化和微生物特性的影响[J]. 土壤圈, 2014, 24(2): 167-177. DOI: 10.1016/S1002-0160(14)60003-5
作者姓名:CHEN Lin  ZHANG Jia-Bao  ZHAO Bing-Zi  XIN Xiu-Li  ZHOU Gui-Xiang  TAN Jin-Fang  ZHAO Jin-Hua
作者单位:[1]State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, Nanjing 210008(China) [2]University of Chinese Academy of Sciences, Beijing 100049 (China) [3]Collaborative Innovation Center of Food Crops in Henan, Henan Agriculture University, Zhengzhou 450002 (China)
基金项目:Supported by the National Basic Research Program (973 Program) of China (No. 2011CB100506), the Knowledge Innovation Pro- gram of Chinese Academy of Sciences (No. CXJQ120111), and China Agriculture Research System--Wheat.
摘    要:An 80-d incubation experiment was conducted to investigate straw decomposition,the priming effect and microbial characteristics in a non-fertilized soil(soil 1) and a long-term organic manure-fertilized soil(soil 2) with and without13 C-labeled maize straw amendment under different moisture levels. The soil 2 showed a markedly higher priming effect,microbial biomass C(Cmic),and β-glucosidase activity,and more abundant populations of bacteria and fungi than the soil 1. Also,soil CO2 emission,Cmic,β-glucosidase activity,and bacterial and fungal population sizes were substantially enhanced by straw amendment. In the presence of straw,the amount of straw mineralization and assimilation by microbes in the soil at 55% of water holding capacity(WHC) were significantly higher by 31% and 17%,respectively,compared to those at 25% of WHC. In contrast,β-glucosidase activity and fungal population size were both enhanced as the moisture content decreased. Cmicdecreased as straw availability decreased,which was mainly attributed to the reduction of straw-derived Cmic. Amended soils,except the amended soil 2 at 25% of WHC,had a more abundant fungal population as straw availability decreased,indicating that fungal decomposability of added straw was independent of straw availability. Non-metric multidimensional scaling analysis based on fungal denatured gradient gel electrophoresis band patterns showed that shifts in the fungal community structure occurred as water and straw availability varied. The results indirectly suggest that soil fungi are able to adjust their degradation activity to water and straw availability by regulating their community structure.

关 键 词:土壤CO2排放  秸秆分解  水分含量  碳矿化  修订  生物属性  微生物生物量C  变性梯度凝胶电泳
收稿时间:2013-09-28

Carbon mineralization and microbial attributes in straw-amended soils as affected by moisture levels
CHEN Lin,ZHANG Jia-Bao,ZHAO Bing-Zi,XIN Xiu-Li,ZHOU Gui-Xiang,TAN Jin-Fang and ZHAO Jin-Hua. Carbon mineralization and microbial attributes in straw-amended soils as affected by moisture levels[J]. Pedosphere, 2014, 24(2): 167-177. DOI: 10.1016/S1002-0160(14)60003-5
Authors:CHEN Lin  ZHANG Jia-Bao  ZHAO Bing-Zi  XIN Xiu-Li  ZHOU Gui-Xiang  TAN Jin-Fang  ZHAO Jin-Hua
Affiliation:1State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, Nanjing 210008 (China)2Graduate University of Chinese Academy of Sciences, Beijing 100049 (China)3Collaborative Innovation Center of Food Crops in Henan, Henan Agriculture University, Zhengzhou 450002 (China)
Abstract:An 80-d incubation experiment was conducted to investigate straw decomposition, the priming effect and microbial characteristics in a non-fertilized soil (soil 1) and a long-term organic manure-fertilized soil (soil 2) with and without 13C-labeled maize straw amendment under different moisture levels. The soil 2 showed a markedly higher priming effect, microbial biomass C (Cmic), and β-glucosidase activity, and more abundant populations of bacteria and fungi than the soil 1. Also, soil CO2 emission, Cmic, β-glucosidase activity, and bacterial and fungal population sizes were substantially enhanced by straw amendment. In the presence of straw, the amount of straw mineralization and assimilation by microbes in the soil at 55% of water holding capacity (WHC) were significantly higher by 31% and 17%, respectively, compared to those at 25% of WHC. In contrast, β-glucosidase activity and fungal population size were both enhanced as the moisture content decreased. Cmic decreased as straw availability decreased, which was mainly attributed to the reduction of straw-derived Cmic. Amended soils, except the amended soil 2 at 25% of WHC, had a more abundant fungal population as straw availability decreased, indicating that fungal decomposability of added straw was independent of straw availability. Non-metric multidimensional scaling analysis based on fungal denatured gradient gel electrophoresis band patterns showed that shifts in the fungal community structure occurred as water and straw availability varied. The results indirectly suggest that soil fungi are able to adjust their degradation activity to water and straw availability by regulating their community structure.
Keywords:bacteria   decomposition   fungi   maize straw   organic manure
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