about
Small-scale patterns in snowmelt timing affect gene flow and the distribution of genetic diversity in the alpine dwarf shrub Salix herbaceaExperiment, monitoring, and gradient methods used to infer climate change effects on plant communities yield consistent patternsPhenological response of tundra plants to background climate variation tested using the International Tundra Experiment.Facilitative plant interactions and climate simultaneously drive alpine plant diversity.The Response of the Alpine Dwarf Shrub Salix herbacea to Altered Snowmelt Timing: Lessons from a Multi-Site Transplant Experiment.Small-scale drivers: the importance of nutrient availability and snowmelt timing on performance of the alpine shrub Salix herbacea.Evolutionary potential in the Alpine: trait heritabilities and performance variation of the dwarf willow Salix herbacea from different elevations and microhabitats'Hearing' alpine plants growing after snowmelt: ultrasonic snow sensors provide long-term series of alpine plant phenology.Greater temperature sensitivity of plant phenology at colder sites: implications for convergence across northern latitudes.Functional traits and root morphology of alpine plantsGlobal assessment of experimental climate warming on tundra vegetation: heterogeneity over space and time.Biodiversity simultaneously enhances the production and stability of community biomass, but the effects are independent.Growth and phenology of three dwarf shrub species in a six-year soil warming experiment at the alpine treeline.Alpine Grassland Phenology as Seen in AVHRR, VEGETATION, and MODIS NDVI Time Series - a Comparison with In Situ Measurements.Growth and community responses of alpine dwarf shrubs to in situ CO₂ enrichment and soil warming.An alpine treeline in a carbon dioxide-rich world: synthesis of a nine-year free-air carbon dioxide enrichment study.Increased spring freezing vulnerability for alpine shrubs under early snowmelt.CO2 enrichment alters diurnal stem radius fluctuations of 36-yr-old Larix decidua growing at the alpine tree line.Soil warming and CO2 enrichment induce biomass shifts in alpine tree line vegetation.Soil warming opens the nitrogen cycle at the alpine treeline.Improved water retention links high species richness with increased productivity in arctic tundra moss communities.Alpine cushion plants inhibit the loss of phylogenetic diversity in severe environments.Shrub expansion in tundra ecosystems: dynamics, impacts and research prioritiesBiotic and abiotic drivers of tree seedling recruitment across an alpine treeline ecotoneA plant diversity×water chemistry experiment in subalpine grasslandEffects of ski piste preparation on alpine vegetationThe rich sides of mountain summits - a pan-European view on aspect preferences of alpine plantsCorrigendum to "Changes in alpine plant growth under future climate conditions" published in Biogeosciences, 7, 2013-2024, doi:10.5194/bg-7-2013-2010, 2010Species removal and experimental warming in a subarctic tundra plant communityInterrill erosion at disturbed alpine sites: Effects of plant functional diversity and vegetation coverPlot-scale evidence of tundra vegetation change and links to recent summer warmingClimate sensitivity of shrub growth across the tundra biomeSoil erosion and organic carbon export by wet snow avalanchesMethods for measuring arctic and alpine shrub growth: A reviewShort-term responses of ecosystem carbon fluxes to experimental soil warming at the Swiss alpine treelineLinking traits between plants and invertebrate herbivores to track functional effects of land-use changesAxial xylem architecture of Larix decidua exposed to CO2 enrichment and soil warming at the tree lineBud freezing resistance in alpine shrubs across snow depth gradientsElevation gradient of successful plant traits for colonizing alpine summits under climate change
P50
Q28601560-7D008950-E284-431D-B498-CCECAE00A8F5Q28652057-C5B38A45-0AC4-45DB-B42C-BFC679275A98Q30654173-ADA5C5C5-E850-4F11-A448-E40E1BE521AEQ30695766-6688982E-B5C1-4FAD-B27B-14E5F1520C51Q30936911-31E390A8-E27F-46F4-B635-9D06B6A1D486Q30984577-1CB5D10E-B56A-4AD8-9618-6E5A243C9481Q31121285-9892B557-B0D0-4661-8C4A-148F6BBCF33FQ31122365-E821EF06-1A76-4252-AAB1-4F1C672F0CE9Q31154361-12C60004-776B-44F7-859E-DBB93EE4EA84Q33973275-A80CFA0F-27A9-433A-A651-153F56E69CAAQ34089721-8921EF88-E79A-4BDC-8DBA-85CF5CC19A15Q34981843-F30A09B9-CA21-4D63-889C-5474A964F943Q35193336-C00F7E88-BADE-45D9-BA68-45CCEAC827E4Q36904870-0F394C3B-9913-49FA-9D68-28A1355016ECQ39115268-54CC02E7-5A73-4F16-B53E-0BEE6F236187Q39121375-2454328C-ED3E-42DD-BB05-9FF8B8791EC6Q39125648-3CB1C929-C97C-4B43-85CD-128000F3DEBBQ39126157-C0B0B0F6-763E-4405-8E9E-20DD2EF9A751Q39129664-2ED52D44-4950-4884-B15D-D691907F061CQ39137627-69318260-0D57-4106-9D08-40CEC19EDA1CQ39400865-4AB06831-BBE5-41EE-8519-1CB0910BD88AQ44118705-CA948BEA-B63B-4B3A-AF9F-F8DD328435DDQ56068887-B52F9809-0DCE-417A-9A7F-2C8CAC96BD9FQ56976278-D9E195EE-F1E0-4A06-9AA6-C3A02C55B019Q57026906-2071C71F-FEF4-43DD-A193-7B98081CE188Q57027023-C51E57AB-62D0-483F-9E9A-A79EDCD16E49Q57043297-0FD7C874-3FBD-4E56-97A9-50732A8B33F9Q57060335-59605651-A884-4A90-96B6-DD8D09DD59A0Q57126716-92196D9E-822F-4E2B-8C30-505B0CA626A7Q57236585-B3846E80-3596-4753-A4D3-E3F730F2ED95Q57258314-58EA12D2-546D-4DD4-BC03-DB62EC3032BBQ57614689-C83FD9F3-C571-4615-9852-6A9B088E9033Q57975017-75882A40-B2EF-4B4D-9EB9-8F676C7E1B0BQ58239289-8A591D6F-E6BD-483A-B6CA-E9877401FB99Q58407567-34CE508E-D588-438B-8DD0-A88F7BEDAD4FQ58653545-3ADD7193-BCC3-41B5-B292-77B6B86732ECQ59274286-F8E911BA-765D-4F56-92BB-ADAAD5A6C044Q59274297-97C753F2-475A-4609-A0C4-E6D621DD3D2BQ59274338-B87B164F-8420-4217-A797-F8CF661EA5B4
P50
description
onderzoeker
@nl
researcher
@en
ricercatore
@it
հետազոտող
@hy
name
Christian Rixen
@ast
Christian Rixen
@en
Christian Rixen
@es
Christian Rixen
@nl
type
label
Christian Rixen
@ast
Christian Rixen
@en
Christian Rixen
@es
Christian Rixen
@nl
prefLabel
Christian Rixen
@ast
Christian Rixen
@en
Christian Rixen
@es
Christian Rixen
@nl
P214
P106
P1153
57190425858
P21
P214
P31
P496
0000-0002-2486-9988
P735
P7859
viaf-205231767