about
Winners always win: growth of a wide range of plant species from low to future high CO2Flourish or flush: effects of simulated extreme rainfall events on Sphagnum-dwelling testate amoebae in a subarctic bog (Abisko, Sweden).Consequences of biodiversity loss for litter decomposition across biomes.Inclusion of ecologically based trait variation in plant functional types reduces the projected land carbon sink in an earth system model.Decadal warming causes a consistent and persistent shift from heterotrophic to autotrophic respiration in contrasting permafrost ecosystems.Changing leaf litter feedbacks on plant production across contrasting sub-arctic peatland species and growth forms.Global negative vegetation feedback to climate warming responses of leaf litter decomposition rates in cold biomes.The effect of environmental change on vascular plant and cryptogam communities from the Falkland Islands and the Maritime AntarcticPlant species traits are the predominant control on litter decomposition rates within biomes worldwide.Neighbour identity hardly affects litter-mixture effects on decomposition rates of New Zealand forest species.Enzymology under global change: organic nitrogen turnover in alpine and sub-Arctic soils.Potential macro-detritivore range expansion into the subarctic stimulates litter decomposition: a new positive feedback mechanism to climate change?Sphagnum-dwelling testate amoebae in subarctic bogs are more sensitive to soil warming in the growing season than in winter: the results of eight-year field climate manipulations.Shifts in soil microorganisms in response to warming are consistent across a range of Antarctic environments.Mapping nutrient resorption efficiencies of subarctic cryptogams and seed plants onto the Tree of Life.Compositional Stability of the Bacterial Community in a Climate-Sensitive Sub-Arctic PeatlandVariable temperature effects of Open Top Chambers at polar and alpine sites explained by irradiance and snow depth.Highly consistent effects of plant litter identity and functional traits on decomposition across a latitudinal gradient.Do high levels of diffuse and chronic metal pollution in sediments of Rhine and Meuse floodplains affect structure and functioning of terrestrial ecosystems?Tundra in the rain: differential vegetation responses to three years of experimentally doubled summer precipitation in Siberian shrub and Swedish bog tundra.Are litter decomposition and fire linked through plant species traits?Variation in trait trade-offs allows differentiation among predefined plant functional types: implications for predictive ecology.Separating the effects of partial submergence and soil oxygen demand on plant physiology.Size and structure of bacterial, fungal and nematode communities along an Antarctic environmental gradient.Interspecific and intraspecific differences in shoot and leaf lifespan of four Carex species which differ in maximum dry matter production.Nutrient use efficiency in evergreen and deciduous species from heathlands.Leaf habit and woodiness regulate different leaf economy traits at a given nutrient supply.Substantial nutrient resorption from leaves, stems and roots in a subarctic flora: what is the link with other resource economics traits?Plant strategies in relation to resource supply in mesic to wet environments: does theory mirror nature?Raising groundwater differentially affects mineralization and plant species abundance in dune slacks.Heavy metal pollution affects consumption and reproduction of the landsnail Cepaea nemoralis fed on naturally polluted Urtica dioica leaves.Polar lessons learned: long-term management based on shared threats in Arctic and Antarctic environmentsA novel way to understand plant species preferences in relation to groundwater discharge conditions using a trait-based approachPotential impacts of groundwater conservation measures on catchment-wide vegetation patterns in a future climateIs the differential response of riparian plant performance to extreme drought and inundation events related to differences in intraspecific trait variation?No effects of experimental warming but contrasting seasonal patterns for soil peptidase and glycosidase enzymes in a sub-arctic peat bogTemperature sensitivity of peatland C and N cycling: Does substrate supply play a role?A frozen feast: thawing permafrost increases plant-available nitrogen in subarctic peatlandsProcess-based proxy of oxygen stress surpasses indirect ones in predicting vegetation characteristicsSuccession-induced trait shifts across a wide range of NW European ecosystems are driven by light and modulated by initial abiotic conditions
P50
Q28607017-0752292C-3FEE-4559-8A9E-B36358BA59F0Q30562531-AE1E853E-DE44-4A02-8387-A73F9CCB4CA0Q30815747-D3427A21-CECC-4EB9-A72D-3368550A1882Q30885591-720009EF-5767-4F35-A53B-BA82DADACC9BQ30978993-EDCAE8FF-83C1-4FFC-8944-8EE4261D799DQ31074377-F8C6FB0F-A26F-43E1-8E45-5CFFD4CA4D94Q31114428-6D8C6ECE-7C5C-4609-ADCA-34BCFFF1ACA9Q33311377-00EC36CD-152A-466E-A5D9-B64E0C73CBA2Q33351730-F6A05131-34D4-4752-B514-3586F641FAA0Q33599083-B9A6D08A-9931-4CEA-BD70-B1E48A6DD13AQ33803312-36AB8CA3-BD39-4984-AD29-E072E63DA0CFQ33953501-8EE224E3-F0A9-4E8C-B330-07A71B9B3593Q33992381-CA73CF40-3797-4F29-BFC8-6FF39E234A9EQ34027233-A5DAC089-489E-45A1-B9B2-6F60F762CABAQ35380752-D38073DE-BC9F-467E-AF71-DC0861FC7F11Q36317115-C60477B0-9F0D-4683-847E-071B83A31B1CQ39122099-9FDAE264-E256-4B33-8D1D-CD1A219D7C00Q39207064-21B6DF22-F5C0-42A9-A0BB-D54C3C8C03B1Q40058526-DEC304EF-6B78-4954-A013-E5F51EE53683Q42074270-3F8E3841-AAE0-4B3E-B4FA-76222C4ECABBQ46309140-9DAD698F-CB56-4895-841B-74808BCFAD7EQ46672377-5F9029E9-8ACD-4C67-A05A-50C1F0AD3136Q46674142-078F4A78-E04F-4479-BD88-5CDB293484B2Q47321454-F913C6F2-A598-47DA-90FC-4E478999A173Q51334168-344D7FBF-5EA2-482C-AC14-7F5DCBB242F7Q51336213-CD3C36A8-A211-4E04-804E-59BAC2FF83D4Q51612967-A3F1EB57-4B87-4FED-B721-C91AA6C405C8Q51634696-A21FF29E-8488-497C-A41A-F845BAF1527DQ51641885-7E739AC0-B43D-4468-9910-8ACE47B9BF82Q51718985-01BF3223-3790-498B-ADD4-0A2298BB36F3Q51728951-49E4110A-63DF-4BFC-B92E-9712A13E904AQ56429808-E6A5DA2A-166E-4668-BD5F-DA6ED82F80D5Q56963975-078C1367-9585-41DF-9D02-D755858B9FEFQ56964035-7B944136-6496-4BD9-8A30-FC002C690452Q56964061-2BC6EE5E-D1E3-40D3-9CC1-B12666BB22E9Q56964077-4F821A58-B169-43A6-B4DF-C66737C29B5DQ56964125-A291113D-F47B-424B-B50E-6250B699337AQ56964146-DF1F54F9-AFBE-4C37-A7F0-DFE84BCAEAE2Q56964177-19364A94-223E-46E5-9DFB-563A752BA4FBQ56964191-E9F443B3-BB37-4A3E-8362-2C8AA8480F3A
P50
name
Rien Aerts
@en
type
label
Rien Aerts
@en
prefLabel
Rien Aerts
@en