冻融作用对土壤微生物的影响综述-《江苏农业科学》

参考文献/References:

［1］吕贻忠，李保国. 土壤学［M］. 北京：中国农业出版社，2006：139-143.
［2］汪太明，王业耀，香宝，等. 交替冻融对东北典型土壤腐殖质的影响［J］. 生态环境学报，2010，19(12)：2870-2874.
［3］王恩姮，赵雨森，陈祥伟. 典型黑土耕作区土壤结构对季节性冻融的响应［J］. 应用生态学报，2010，21(7)：1744-1750.
［4］Martin J P，Martin W P，Page J B. Soil aggregation［J］. Advance in Agronomy，1995，7：1-37.
［5］Summerfield R J，Rieley J O. Substrate freezing and thawing as a factor in the mineral nutrient status of mire ecosystems［J］. Plant and Soil，1973，38(3)：557-566.
［6］Hentschel K，Borken W，Matzner E. Repeated freeze-thaw events affect leaching losses of nitrogen and dissolved organic matter in a frost soil［J］. Plant Nutr Soil Sci，2008，171(5)：699-706.
［7］孙辉，秦纪洪，吴杨. 土壤冻融交替生态效应研究进展［J］. 土壤，2008，40(4)：505-509.
［8］Zhang T，Barry R G，Knowles K，et al. Distribution of seasonally and perennially frozen ground in Northern Hemisphere［C］//Proceedings of the Eighth International Conference on Permafrost，2003：284-1289.
［9］朴春和，刘广深，洪业汤. 干湿交替和冻融作用对土壤肥力和生态环境的影响［J］. 生态学杂志，1995，14(6)：29-34.
［10］Herrmann A，Witter E. Source of C and N contributing to the flush in mineralization upon freeze-thaw cycles in soils［J］. Soil Biology & Bio-chemistry，2002，34：1495-1504.
［11］王风，韩晓增，李良皓，等. 冻融过程对黑土水稳性团聚体含量影响［J］. 冰川冻土，2009，31(5)：915-919.
［12］Mellander P E，Laudon H，Bishop K. Modelling variability of snow depths and soil temperatures in Scots pine stands［J］. Agricultural and Forest Meteorology，2009，133(1/2/3/4)：109-118.
［13］Hobbie S E，Chapin F . Winter regulation of tundra litter carbon and nitrogen dynamics［J］. Biogeochemistry，1996，35(2)：327-338.
［14］Mellander P E，Lfvenius M O，Laudon H. Climate change impact on snow and soil temprerature in boreal Scots pine stands［J］. Climatic Change，2007，85(1/2)：179-193.
［15］Henry H L. Climate change and soil freezing dynamics：historical trends and projected changes［J］. Climatic Change，2008，87(3/4)：421-434.
［16］Mazur P. Cryobiology：the freezing of biological systems［J］. Science，1970，168(3934)：939-949.
［17］Methé B A，Nelson K E，Deming J W，et al. The psychrophilic lifestyle as revealed by the genome sequence of Colwellia psychrerythraea ³⁴H through genomic and proteomic analyses［J］. Proceedings of the National Academy of Sciences of the United States of America，2005，102(31)：10913-10918.
［18］Rivkina E M，Friedmann E I，Mckay C P，et al. Metabolic activity of permafrost bacteria below the freezing point［J］. Applied and Environmental Microbiology，2000，66(8)：3230-3233.
［19］Finegold L. Molecular and biophysical aspects of adaptation of life to temperatures below the freezing point［J］. Advances in Space Research，1996，18(12)：87-95.
［20］朱琳，刘宁，张英华，等. 乳酸菌细胞膜的冻干损伤［J］. 食品科学，2006，27(2)：266-269.
［21］杨思忠，金会军. 冻融作用对冻土区微生物生理和生态的影响［J］. 生态学报，2008，28(10)：5065-5074.
［22］Horneck G，Baumstark-Khan C. Astrobiology：the quest for the conditions of life［M］. Berlin：Springer，2001：125-142.
［23］Brinton K F，Tsapin A I，Gilichinsky D A，et al. Aspartic acid racemization and age depth relationships for organic carbon in Siberian permafrost［J］. Astrobiology，2002，2(1)：77-82.
［24］Gilichinsky D，Wagener S. Microbial life in permafrost：a historical review［J］. Permafrost and Periglacial Processes，1995，6(3)：243-250.
［25］Pesaro M，Widmer F，Nicollier G，et al. Effects of freeze-thaw stress during soil storage on microbial communities and methidathion degration［J］. Soil Biology and Biochemistry，2003，35(8)：1049-1061.
［26］Gilichinsky D A，Soina V S，Petrova M A. Cryoprotective properties of water in the earth cryolithosphere and its role in exobiology［J］. Origins of Life and Evolution of the Biosphere：the Journal of the International Society for the Study of the Origin of Life，1993，23(1)：65-75.
［27］Price P B，Sowers T. Temperature dependence of metabolic rates for microbial growth，maintenance，and survival［J］. Proceedings of the National Academy of Sciences of the United States of America，2004，101(13)：4631-4636.
［28］Morita R Y. Bioavailability of energy and its relationship to growth and starvation survival in nature［J］. Canadian Journal of Microbiology，1988，34(4)：436-441.
［29］Dumont F，Marechal P A，Gervais P. Influence of cooling rate on Saccharomyces cerevisiae destruction during freezing：unexpected viability at ultra-rapid cooling rates［J］. Cryobiology，2003，46(1)：33-42.
［30］Deluca T H，Keeney D R，Mccarty G W. Effect of freeze-thaw events on mineralization of soil nitrogen［J］. Biology and Fertility of Soils，1992，14(2)：116-120.
［31］Walker V K，Palmer G R，Voordouw G. Freeze-thaw tolerance and clues to the winter survival of a soil community［J］. Applied and Environmental Microbiology，2006，72(3)：1784-1792.
［32］范志平，李胜男，李法云，等. 冻融交替对河岸缓冲带土壤无机氮和土壤微生物量氮的影响［J］. 气象与环境学报，2013，29(4)：106-111.
［33］徐俊俊，吴彦，张新全，等. 冻融交替对高寒草甸土壤微生物量氮和有机氮组分的影响［J］. 应用与环境生物学报，2011，17(1)：57-62.
［34］熊雪晶. 季节性冻融对亚高山冷杉林土壤微生物活性的影响［D］. 雅安：四川农业大学，2009.
［35］Jarvis S C，Stockdal E A，Shepherd M A，et al. Nitrogen mineralization in temperate agricultural soils：processes and measurement［J］. Advances in Agronomy，1996，57(8)：187-235.
［36］王洋，刘景双，王国平，等. 冻融作用与土壤理化效应的关系研究［J］. 地理与地理信息科学，2007，23(2)：91-96.
［37］廖晓勇，张杨珠，刘学军，等. 农业生态系统中土壤氮素行为的研究现状与展望［J］. 西南农业学报，2001，1(3)：94-98.
［38］巨晓棠，李生秀. 土壤氮素矿化的温度水分效应［J］. 植物营养与肥料学报，1998，4(1)：37-42.
［39］周才平，欧阳华. 温度和湿度对长白山两种林型下土壤氮矿化的影响［J］. 应用生态学报，2001，12(4)：505-508.
［40］Puri G，Ashman M R. Relationship between soil microbal biomass and gross N mineralization［J］. Soil Biology and Biochemistry，1998，30(2)：251-256.
［41］章燕平. 环境因素对菜地土壤氮素转化及其生物学特性的影响［D］. 杭州：浙江大学，2010：1-3.
［42］夏北成. 环境污染物生物降解［M］. 北京：化学工业出版社，2002：179-187.
［43］邓西民，王坚，朱文珊，等. 冻融作用对犁底层土壤的物理性状的影响［J］. 科学通报，1998，43(23)：2538-2541.
［44］刘虹，刘翠竹，白俊峰.冻融作用对土壤中阿特拉津微生物降解的影响研究［J］. 吉林化工学院学报，2010，27(4)：36-40.
［45］Williams M A，Rice C W. Seven years of enhanced water availability influences the physiological，structural，and functional attributes of a soil microbial community［J］. Applied Soil Ecology，2007，35(3)：535-545.
［46］张立新，韩文玉，顾同欣.冻融过程对景电灌区草窝滩盆地土壤水盐动态的影响［J］. 冰川冻土，2003，25(3)：297-302.
［47］Clein J S，Schimel J P. Microbial activity of tundra and taiga soils at sub-zero temperatures［J］. Soil Biology and Biochemistry，1995，27(9)：1231-1234.
［48］Brooks P D，Williams M W，Schmidt S K. Inorganic nitrogen and microbial biomass dynamics before and during spring snowmelt［J］. Biogeochemistry，1998，43(1)：1-15.
［49］Brooks P D，Williams M W. Snowpack controls on nitrogen cycling and export in seasonally snow-covered catchments［J］. Hydrological Processes，1999，13(14/15)：2177-2190.
［50］龚家栋，祁旭升，谢忠奎，等. 季节性冻融对土壤水分的作用及在农业生产中的意义［J］. 冰川冻土，1997，19(4)：328-333.
［51］宋长春，王毅勇，王跃思，等. 季节性冻融期沼泽湿地CO₂、CH₄和N₂O排放动态［J］. 环境科学，2005，26(4)：7-12.
［52］Lipson D A，Schmidt S K. Seasonal changes in an alpine soil bacterial community in the Colorado Rocky mountains［J］. Applied and Environmental Microbiology，2004，70(5)：2867-2879.
［53］Edwards A C，Cresser M S. Freezing and its effect on chemical and biological properties of soil［J］. Advances in Soil Science，1992，18：59-79.
［54］Lipson D A，Schadt C W，Schmidt S K. Changes in soil microbial community structure and function in an alpine dry meadow following spring snow melt［J］. Microbial Ecology，2002，43(3)：307-314.
［55］Grogan P，Michelsen A，Ambus P，et al. Freeze-thaw regime effects on carbon and nitrogen dynamics in sub-arctic heath tundra mesocosms［J］. Soil Biology & Biochemistry，2004，36(4)：641-654.
［56］Sharma S，Szele Z，Schilling R，et al. Influence of freeze-thaw stress on the structure and function of microbial communities and denitrifying populations in soil［J］. Applied and Environmental Microbiology，2006，72(3)：2148-2154.
［57］王奥. 季节性冻融对高山森林土壤微生物与生化特性的影响［D］. 雅安：四川农业大学，2012.
［58］Mecleod R A，Calcott P H. Cold shock and freezing damage to microbes the survival of vegetative microbes［M］. Cambridge：Cambridge University Press，2003：81-109.
［59］Goodroad L L，Keeney D R. Nitrous oxide emissions from soil during thawing［J］. Canadian Journal of Soil Science，1984，64(2)：187-194.
［60］Burton D L，Beanchamp E G. Profile nitrous oxide and carbon dioxide concentration in a soil subject to freezing［J］. Soil Science Society of America Journal，1994，58(1)：115-122.
［61］Somova L A，Pechurkin N S. Functional，regulatory and indicator features of microorganisms in man-made ecosystems［J］. Advances in Space Research，2001，27(9)：1563-1570.
［62］Yang W Q，Feng R F，Zhang J，et at. Carbon stock and biochemical properties in the organic layer and mineral soil under three subalpine forests in Western China ［J］. Acta Ecologica Sinica，2007，27(10)：4157-4165.
［63］Palacios-Vargas J G，Gomez-Anaya J G G. Lista actualizada de colémbolos micetófilos de México(Hexapoda：Entognatha) ［J］. Folia Entomologica Mexicana，1994，92：21-30.
［64］Six J，Bossuyt H，Degryze S，et al. A history of research on the link between (micro) aggregates，soil biota，and soil orgnic matter dynamics ［J］. Soil and Tillage Research，2004，79(1)：7-31.
［65］Sjursen H S，Michelsen A，Holmstrup M. Effects of freeze-thaw cycles on microarthropods and nutrient availability in a sub-Arctic soil［J］. Applied Soil Ecology，2005，28(1)：79-93.
［66］刘利. 季节性冻融对亚高山/高山森林土壤微生物多样性的影响［D］. 雅安：四川农业大学，2010.
［67］Ostroumov V E，Siegert C. Exobiological aspecs of mass transfer in microzones of permafrost deposits［J］. Advance in Space Research，1996，18(12)：79-86
［68］Henry H A. Soil freeze-thaw cycle experiments：trends，methodological weaknesses and suggested improvements［J］. Soil Biology & Biochemistry，2007，39(5)：977-986.
［69］王怀玉，杨万勤. 积极我想冻融对亚高山冷杉林土壤微生物数量的影响［J］. 林业科学，2012，48(5)：88-94.
［70］Lipson D A，Schmidt S K，Monson R K. Links between microbial population dynamics and nitrogen availability in an alpine ecosystem［J］. Ecology，1999，80(5)：1623-1631.
［71］Buckeridge K M，Grogan P. Deepened snow alters soil microbial nutrient limitations in Arctic birch hummock tundra［J］. Applied Soil Ecology，2008，39(2)：210-222.
［72］Staricka J A，Benoit G R. Freeze-drying effects on wet and dry aggregate stability［J］. Soil Science Society of America Journal，1995，599(1)：218-223
［73］Schimel J P，Clein J S. Microbial response to freeze-thaw cycles in tundra and taiga soils［J］. Soil Biology and Biochemistry，1996，28(8)：1061-1066.
［74］Beare M H. Fungal and bacterial pathways of organic matter decomposition and nitrogen mineralization in arable soils［J］. Journal of the Optical society of America，1965，55(5)：574-575.
［75］Margesin R，Jud M，Tscherko D，et al. Microbial communities and activities in alpine and subalpine soils［J］. Fems Microbiology Ecology，2008，67(2)：208-218.
［76］Jefferies R L，Walker N A，Edwards K A. Is the decline of soil microbial biomass in late winter coupled to changes in the physical state of cold soils？［J］. Soil Biology & Biochemistry，2010，42(2)：129-135.
［77］杨玉莲，吴福忠，何振华，等. 雪被去除对川西高山冷杉林冬季土壤微生物生物量碳氮和可培养微生物数量的影响［J］. 应用生态学报，2012，23(7)：1809-1816.
［78］Mikan C J，Schimel J P，Doyle A P. Temperature controls of microbial respiration in arctic tundra soil above and below freezing［J］. Soil Biology&Biochemistry，2002，34(11)：1785-1795.
［79］Koponen H T，Jaakkola T，Keinanen-Toivola M M，et al. Microbial communities，biomass，and activities in soils as affected by freeze thaw cycles［J］. Soil Biology & Biochemistry，2006，38(7)：1861-1871.
［80］谭波，吴福忠，杨万勤，等. 川西亚高山/高山森林土壤氧化还原酶活性及其对季节性冻融的响应［J］. 生态学报，2012，32(21)：6670-6678.
［81］殷睿，蒋先敏，徐振锋，等. 季节性雪被对川西亚高山岷江冷杉林冬季土壤氮矿化和淋溶的影响［J］. 水土保持学报，2013，27(5)：138-143.
［82］Nielsen M N，Winding A，Binnerup S，et al. Microorganisms as indicators of soil health［R］. National Environmental Research Institute，2002：15-16.
［83］冯瑞芳.高寒森林土壤有机层酶活性动态及其对模拟气候变化的响应［D］. 雅安：四川农业大学，2007.
［84］Climate change 2007，the Scientific basis［M］. Cambridge：Cambridge University Press，2007.
［85］Lipson D A，Schmidt S K，Monson R K. Carbon availability and temperature control the post-snowmelt decline in alpine soil microbial biomass［J］. Soil Biology and Biochemistry，2000，32(4)：441-448.

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