[1]Andreetta A, Huertas A D, Lotti M, et al. Land use changes affecting soil organic carbon storage along a mangrove swamp rice chronosequence in the Cacheu and Oio regions (northern Guinea-Bissau)[J]. Agriculture,Ecosystems Environment,2016,216:314-321. [2]Mcleod E, Chmura G L, Bouillon S, et al. A blueprint for blue carbon: toward an improved understanding of the role of vegetated coastal habitats in sequestering CO2[J]. Frontiers in Ecology and the Environment,2011,9(10):552-560. [3]Theriota JM, Conkleb JL, Pezeshkic SR, et al. Will hydrologic restoration of Mississippi River riparian wetlands improve their critical biogeochemical functions[J]. Ecological Engineering,2013,60:192-198. [4]Fenner N, Freeman C, Reynolds B. Observations of a seasonally shifting thermal optimum in peatland carbon-cycling processes; implications for the global carbon cycle and soil enzyme methodologies[J]. Soil Biology and Biochemistry,2005,37(10):1814-1821. [5]Bergstrom D W, Monreal C M, King D J. Sensitivity of soil enzyme activities to conservation practices[J]. Soil Science Society of America Journal,1998,62(5):1286-1295. [6]Wang B, Xue S, Liu G B, et al. Changes in soil nutrient and enzyme activities under different vegetations in the Loess Plateau area, Northwest China[J]. Catena,2012,92:186-195. [7]Freeman C, Liska G, Ostle N J, et al. Enzymes and biogeochemical cycling in wetlands during a simulated drought[J]. Biogeochemistry,1997,39(2):177-187. [8]Kang H, Kim S Y, Fenner N, et al. Shifts of soil enzyme activities in wetlands exposed to elevated CO2[J]. Science of the Total Environment,2005,337(1-3):207-212. [9]曾竞,卜兆君,王猛,等.氮沉降对泥炭地影响的研究进展[J].生态学杂志,2013,32(02):473-481. [10]Li Y T, Rouland C, Benedetti M, et al. Microbial biomass, enzyme and mineralization activity in relation to soil organic C, N and P turnover influenced by acid metal stress[J]. Soil Biology and Biochemistry,2009,41(5):969-977. [11]刘亚军,吴娟,邹锋,等.鄱阳湖湿地灰化薹草洲滩土壤微生物和酶特性对水分梯度的响应[J].湿地科学,2017,15(02):269-275. [12]Chen R R, Blagodatskaya E, Senbayram M, et al. Decomposition of biogas residues in soil and their effects on microbial growth kinetics and enzyme activities [J]. Biomass and Bioenergy,2012,45(7):221-229. [13]陆梅,田昆,陈玉惠,常凤来,莫剑锋.高原湿地纳帕海退化土壤养分与酶活性研究[J].西南林学院学报,2004(01):34-37. [14]Caravaca F, Alguacil M M, Torres P, et al. Plant type mediates rhizospheric microbial activities and soil aggregation in a semiarid Mediterranean salt marsh[J]. Geoderma,2005,124(3-4):375-382. [15]万忠梅,宋长春.小叶章湿地土壤酶活性分布特征及其与活性有机碳表征指标的关系[J].湿地科学,2008(02):249-257. [16]牛世全,李君锋,杨婷婷,等.甘南玛曲沼泽湿地土壤微生物量、理化因子与土壤酶活的关系[J].冰川冻土,2010,32(05):1022-1029. [17]孙英杰,徐广平,沈育伊,蒲高忠,李艳琼,周翠鸣,莫凌,李衍青.桂林会仙喀斯特湿地芦苇群落区土壤酶活性[J].湿地科学,2018,16(02):196-203. [18]马宁,齐继薇,刘长发,刘远,魏海峰,蔡恒江,李冰,李晋.辽河口潮滩湿地不同植被土壤4种碳代谢酶活性及其与有机碳含量、pH值关系[J].中国农学通报,2018,34(01):90-97. [19]朱海强,李艳红,李发东.艾比湖湿地典型植物群落土壤酶活性季节变化特征[J].应用生态学报,2017,28(04):1145-1154. [20]万忠梅,宋长春.三江平原小叶章湿地土壤酶活性的季节动态[J].生态环境学报,2010,19(05):1215-1220. [21]Kang H, Freeman C, Chun J. N-Acetylglucosaminidase activities in wetlands: a global survey[J]. Hydrobiologia,2005,532(1-3): 103-110. [22]王金凤.鄱阳湖湿地植被演替和水位对土壤有机碳、微生物多样性的影响[D].江西师范大学,2016. [23]曾静,李旭,侯志勇,等.洞庭湖湿地3种典型植物群落土壤酶活性特征[J].湖泊科学,2017,29(04):907-913. [24]李晓红.鄱阳湖湿地不同植物群落土壤养分和土壤酶活性垂直分布特征[J].水土保持研究,2019,26(01):69-75+81. [25]吴俐莎,唐杰,罗强,等.若尔盖湿地土壤酶活性和理化性质与微生物关系的研究[J].土壤通报,2012,43(01):52-59. [26]于昊天,黄时豪,刘亚军,等.鄱阳湖湿地土壤酶及微生物生物量的剖面分布特征[J].环境科学研究,2017,30(11):1715-1722. [27]马玲,丁新华,顾伟,等.扎龙季节性湿草甸土壤养分和土壤微生物特性[J].应用生态学报,2011,22(07):1717-1724. [28]Senga Y, Hiroki M, Terui S, et al.Variation in microbial function through soil depth profiles in the Kushiro Wetland, northeastern Hokkaido, Japan [J]. Ecological Research,2015,30(4):563-572. [29]韩园园,王铭,王升忠,董彦民,刘双双,徐志伟.长白山区金川泥炭沼泽土壤酶活性特征[J].湿地科学,2018,16(05):671-678. [30]Stocker T F, Qin D, Plattner G K, et al. Climate change 2013: The physical science basis[J]. 2013. [31]Kang H, Freeman C. Phosphatase and arylsulphatase activities in wetland soils: annual variation and controlling factors[J]. Soil Biology and Biochemistry,1999,31(3):449-454. [32]郭冬楠,臧淑英,赵光影.冻融交替对不同年代排水造林湿地土壤微生物活性及有机碳密度的影响[J].冰川冻土,2017,39(01):175-184. [33]韩玮,孙晨曦,苏敬.模拟增温和酸雨对水稻土酶活性及温度敏感性的影响[J].生态与农村环境报,2017,33(12):1117-1124. [34]高艳娜,戚志伟,仲启铖,等.长江口芦苇湿地土壤酶活性对长期模拟升温的响应[J].应用与环境生物学报,2017,23(03):535- 541. [35]Sardans J, Pe?uelas J, Estiarte M. Changes in soil enzymes related to C and N cycle and in soil C and N content under prolonged warming and drought in a Mediterranean shrubland[J]. Applied Soil Ecology,2008,39(2):223-235. [36]侯鹏,蒋卫国,陈自力,等.降水对洞庭湖湿地水文补给效应[J].地理研究,2009,28(02):371-378. [37]孟焕,王琳,张仲胜,等.气候变化对中国内陆湿地空间分布和主要生态功能的影响研究[J].湿地科学,2016,14(05):710-716. [38]Van Bodegom P M, Broekman R, Van Dijk J, et al. Ferrous iron stimulates phenol oxidase activity and organic matter decomposition in waterlogged wetlands[J]. Biogeochemistry,2005,76(1):69-83. [39]Freeman C,Liska G,Ostle N J,et al.Microbial activity and enzymic decomposition processes following peatland water table drawdown[J].Plant and soil,1996,180(1):121-127. [40]陈艳鑫,耿玉清,黄金,崔雪晴,侯盟.青海湖鸟岛地区不同淹水条件下土壤酶活性的差异及其影响因素[J].生态学杂志,2019,38(03):735-743. [41]仙旋旋,孔范龙,朱梅珂,李悦,郗敏.水盐梯度对滨海湿地土壤养分指标和酶活性的影响[J].水土保持通报,2019,39(01):65-71. [42]Li X F, Han S J, Guo Z L, et al. Changes in soil microbial biomass carbon and enzyme activities under elevated CO2 affect fine root decomposition processes in a Mongolian oak ecosystem [J]. Soil Biology and Biochemistry,2010,42:1101-1107. [43]Chung H, Zak D R, Reich P B, et al. Plant species richness,elevated CO2 and atmospheric nitrogen decomposition alter soil microbial community composition and function[J]. Global Change Biology,2007,13:980-989. [44]Freeman C, Liska G, Ostle N J, et al. Enzymes and biogeochemical cycling in wetlands during a simulated drought[J]. Biogeochemistry,1997,39(2):177-187. [45]Bonnett S A F, Ostle N, Freeman C. Seasonal variations in decomposition processes in a valley bottom riparian peatland[J]. Science of the Total Environment,2006,370:561-573. [46]Kang H, Freeman C, Lock M A. Trace gas emissions from a north Wales fen-role of hydrochemistry and soil enzyme activity[J]. Water, Air, and Soil Pollution,1998,105(1-2):107-116. [47]DeLaune R D, Reddy K R. Biogeochemistry of wetlands: science and applications[M]. CRC press,2008. [48]Contosta A R, Frey S D, Cooper A B. Seasonal dynamics of soil respiration and N mineralization in chronically warmed and fertilized soils[J]. Ecosphere,2011,2(3):1-21. [49]Sudhakaran M, Ramamoorthy D, Savitha V, et al. Soil Enzyme Activities and Their Relationship with Soil Physico-Chemical Properties and Oxide Minerals in Coastal Agroecosystem of Puducherry[J]. Geomicrobiology Journal,2019,36(5):452-459. [50]肖新,朱伟,肖靓,等.适宜的水氮处理提高稻基农田土壤酶活性和土壤微生物量碳氮[J].农业工程学报,2013,29(21):91-98. [51]张艺.氮添加对若尔盖高寒泥炭湿地土壤碳稳定性的影响[D].北京林业大学,2016. [52]张闯,邹洪涛,张心昱,寇亮,杨洋,孙晓敏,李胜功,王辉民.氮添加对湿地松林土壤水解酶和氧化酶活性的影响[J].应用生态学报,2016,27(11):3427-3434.
|