Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
about
The regulation by phenolic compounds of soil organic matter dynamics under a changing environmentTerrestrial nitrogen-carbon cycle interactions at the global scaleGenotypic trait variation modifies effects of climate warming and nitrogen deposition on litter mass loss and microbial respiration.Molecular mechanisms of water table lowering and nitrogen deposition in affecting greenhouse gas emissions from a Tibetan alpine wetland.Microbial metabolic potential for carbon degradation and nutrient (nitrogen and phosphorus) acquisition in an ombrotrophic peatlandEnzymology under global change: organic nitrogen turnover in alpine and sub-Arctic soils.Microbial community composition explains soil respiration responses to changing carbon inputs along an Andes-to-Amazon elevation gradient.Increase in carbon accumulation in a boreal peatland following a period of wetter climate and long-term decrease in nitrogen deposition.The microbe-mediated mechanisms affecting topsoil carbon stock in Tibetan grasslandsNitrogen deposition alters nitrogen cycling and reduces soil carbon content in low-productivity semiarid Mediterranean ecosystemsMicrobial community composition and carbon cycling within soil microenvironments of conventional, low-input, and organic cropping systemsWater and nitrogen availability co-control ecosystem CO2 exchange in a semiarid temperate steppe.Elevated CO2 stimulates marsh elevation gain, counterbalancing sea-level rise.Combination of herbivore removal and nitrogen deposition increases upland carbon storage.Effects of extreme experimental drought and rewetting on CO2 and CH4 exchange in mesocosms of 14 European peatlands with different nitrogen and sulfur deposition.Photosynthesis, growth, and decay traits in Sphagnum - a multispecies comparison.Vegetation feedbacks of nutrient addition lead to a weaker carbon sink in an ombrotrophic bog.Bacterial populations and environmental factors controlling cellulose degradation in an acidic Sphagnum peat.The Sphagnome Project: enabling ecological and evolutionary insights through a genus-level sequencing project.The Methuselah of plant diaspores: Sphagnum spores can survive in nature for centuries.Microbial Communities as Environmental Indicators of Ecological Disturbance in Restored Carbonate Fen-Results of 10 Years of Studies.Changes of soil bacterial activities and functions after different N additions in a temperate forest.Eutrophication triggers contrasting multilevel feedbacks on litter accumulation and decomposition in fens.Nitrous oxide emission potentials of Burkholderia species isolated from the leaves of a boreal peat moss Sphagnum fuscum.Transformation and stabilization of pyrogenic organic matter in a temperate forest field experiment.Linking Nitrogen Load to the Structure and Function of Wetland Soil and Rhizosphere Microbial Communities.Long-term nutrient addition increased CH4 emission from a bog through direct and indirect effects.Peatland vegetation composition and phenology drive the seasonal trajectory of maximum gross primary production.Microbe-mediated plant–soil feedback and its roles in a changing worldRestoration effects on water table depths and CO2 fluxes from climatically marginal blanket bogA frozen feast: thawing permafrost increases plant-available nitrogen in subarctic peatlandsSummer warming accelerates sub-arctic peatland nitrogen cycling without changing enzyme pools or microbial community structureResponses of soil microbial biomass and enzymatic activities to different forms of organic nitrogen deposition in the subtropical forests in East ChinaMixed Inorganic and Organic Nitrogen Addition Enhanced Extracellular Enzymatic Activities in a Subtropical Forest Soil in East ChinaResponse of litter decomposition and related soil enzyme activities to different forms of nitrogen fertilization in a subtropical forestCoupled Carbon and Nitrogen Inputs Increase Microbial Biomass and Activity in Prairie Bioenergy SystemsLinking variability in soil solution dissolved organic carbon to climate, soil type, and vegetation typeDual controls on carbon loss during drought in peatlandsCarbon preservation in humic lakes; a hierarchical regulatory pathwayNitrogen limitation of heterotrophic biofilms in boreal streams
P2860
Q26779977-D78F1454-0535-4557-A1C5-B38A51210C79Q28681415-D25AD99B-86CC-40A5-A3D5-3D6913388DADQ30841042-0BE26378-6976-423A-89A2-D4908D71FF6EQ31122274-F71A7E76-C84D-4688-AC30-BC06D933E3B6Q31154965-0D8FC0F4-3E0D-4F0E-A1F7-1AD9461F44FDQ33803312-031890B0-736A-407F-A762-C3F37AD27153Q34678609-98F84BB5-F525-4F79-A118-A5168CC30DB2Q35560376-71A855AB-5147-4F19-ACF7-8197085D6BF8Q35562608-A3C90B90-F5BE-474F-8963-64F74E8C96E0Q35593714-B239AFA2-1CC3-4860-B90A-A25672A8E437Q35678719-16C729D7-635A-4FFC-85D7-9EDDAD4822BFQ36192525-7FA484A3-D7C8-4175-BEC1-BBEB5E971222Q37141386-E76EFF5F-A0B6-45A5-893D-F08044C97EFDQ37152686-D1E295A1-C2C0-4581-8A7A-C34F45B9A396Q38995846-DF508C94-C5DE-4FA3-909E-6BB5A34F12E6Q40237239-BE26B2C9-2C7F-4246-8B73-5F72BA045B00Q43533406-61F05756-9950-484A-A712-D4E3581EA78AQ46021651-89F12EDE-1C32-4B20-B2C1-1797BC064537Q46273473-959F8263-3793-49FE-98CC-6DE26C1D56AFQ46385081-1FEDAC51-6083-4707-ABC0-6DFF70C026F9Q46408115-2F8D308E-A6F2-4DCA-B453-063A7EB13A99Q46452928-175CF334-367D-46EB-BA13-5401B5BA43DAQ46458502-6ED4755E-63CC-4752-8A0A-1F8F790731EFQ46701665-19C2F5EB-5219-4530-B2F8-D525C2E3900BQ46793221-2B481A0E-AF85-4535-92CA-5680B7493BC3Q48102077-2DD4A439-420E-4E65-9177-572DC84CF744Q53825269-C491D767-8388-4D85-ACD2-1FF0253E7EDCQ55208923-A7617374-3F95-419A-8F4A-4D1FABE17F50Q56561276-D6F8EF15-4454-41D6-AD40-0FB568134E2DQ56752619-522B81B3-E703-487B-A9C7-80C660BDC112Q56964146-BB73734F-5DB6-4C04-928E-9229A7DE86B1Q56964198-67DC423D-AD06-441C-979D-A1103BB8991BQ57001393-A1DD0F5B-334D-4D31-9353-336F7FAB6D25Q57001409-5E0A1620-8AA0-4462-B1FE-345CA3C51C6AQ57001412-434683E1-B51A-45B8-8787-686E2996073FQ57014491-CBADAC6B-4B7E-4AAB-8307-3779961F27BEQ57044639-D08A6B16-3BB4-4B3B-BF21-B54FF40751A8Q57067189-71B086B2-BE3B-444A-9F66-91C6BF9B2D65Q57117153-FFFF0295-DCCA-4CEF-96DD-1BC28C81D7DEQ57202761-C8857925-CC63-4FCC-B2ED-F97E1FDFDB2D
P2860
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
description
2006 nî lūn-bûn
@nan
2006 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
name
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@ast
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@en
type
label
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@ast
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@en
prefLabel
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@ast
Atmospheric nitrogen deposition promotes carbon loss from peat bogs.
@en
P2093
P2860
P50
P356
P1476
Atmospheric nitrogen deposition promotes carbon loss from peat bogs
@en
P2093
Chris Freeman
Hannah Toberman
Håkan Rydin
Lado Kutnar
Michal Hájek
Nathalie Fenner
Renato Gerdol
Teemu Tahvanainen
Timothy Jones
P2860
P304
19386-19389
P356
10.1073/PNAS.0606629104
P407
P577
2006-12-06T00:00:00Z