about
Footprints of climate change in the Arctic marine ecosystemTowards quantifying the glacial runoff signal in the freshwater input to Tyrolerfjord-Young Sound, NE Greenland.A synthesis of the arctic terrestrial and marine carbon cycles under pressure from a dwindling cryosphereContinuous daylight in the high-Arctic summer supports high plankton respiration rates compared to those supported in the dark.Anaerobic ammonium-oxidizing bacteria in marine environments: widespread occurrence but low diversity.Phytoplankton Productivity in an Arctic Fjord (West Greenland): Estimating Electron Requirements for Carbon Fixation and Oxygen ProductionGenetic diversity and connectivity within Mytilus spp. in the subarctic and Arctic.Sea ice and primary production proxies in surface sediments from a High Arctic Greenland fjord: Spatial distribution and implications for palaeoenvironmental studiesSeasonal sea ice cover as principal driver of spatial and temporal variation in depth extension and annual production of kelp in GreenlandLong photoperiods sustain high pH in Arctic kelp forests.Marine-terminating glaciers sustain high productivity in Greenland fjords.Food supply confers calcifiers resistance to ocean acidification.Postscript: The future of the Greenland Ecosystem Monitoring programme.Foreword: Synthesis of the Greenland Ecosystem Monitoring program.Evidence of local and regional freshening of Northeast Greenland coastal waters.High geothermal heat flux in close proximity to the Northeast Greenland Ice Stream.Does acute lead (Pb) contamination influence membrane fatty acid composition and freeze tolerance in intertidal blue mussels in arctic Greenland?Reply to 'Increased food supply mitigates ocean acidification effects on calcification but exacerbates effects on growth'.Seasonal dynamics of autotrophic and heterotrophic plankton metabolism and PCO2 in a subarctic Greenland fjordAir-water exchange and vertical profiles of organic carbon in a subarctic fjordImpacts of climate warming on polar marine and freshwater ecosystemsTowards a pan-Arctic inventory of the species diversity of the macro- and megabenthic fauna of the Arctic shelf seasCoastal Freshening Prevents Fjord Bottom Water Renewal in Northeast Greenland: A Mooring Study From 2003 to 2015Carbon Bioavailability in a High Arctic Fjord Influenced by Glacial Meltwater, NE GreenlandThe influence of glacial melt water on bio-optical properties in two contrasting Greenlandic fjordsAcute oil exposure reduces physiological process rates in Arctic phyto- and zooplanktonSpatial, seasonal and inter-annual variation in abundance and carbon turnover of small copepods in Young Sound, Northeast GreenlandCanopy-Forming Macroalgae Facilitate Recolonization of Sub-Arctic Intertidal Fauna and Reduce Temperature ExtremesSubtidal benthic recruitment in a sub-Arctic glacial fjord system: Temporal and spatial variability and potential driversTemporal variability of air-sea CO2 exchange in a low-emission estuaryClimate change effects on Arctic fjord and coastal macrobenthic diversity—observations and predictionsSpring Succession and Vertical Export of Diatoms and IP25 in a Seasonally Ice-Covered High Arctic FjordSilicic acid limitation drives bloom termination and potential carbon sequestration in an Arctic bloom.Local cold adaption increases the thermal window of temperate mussels in the ArcticIn vivo31P-MRS of muscle bioenergetics in marine invertebrates: Future ocean limits scallops' performanceBiomineralization plasticity and environmental heterogeneity predict geographical resilience patterns of foundation species to future change
P50
Q29395414-3AD8F678-964D-4B42-A5D8-B89533B7D216Q30835997-11235194-7E0E-4060-A561-73372ECF3BCDQ31156331-8DBBA78F-A3AA-445A-B989-A0DB459518C4Q33681871-14D25990-A98F-4C3D-A788-E68615CDAF54Q34004157-26C54192-1B06-4134-B7F2-3BB44BBC1E74Q35719308-FF684667-10F5-4C76-873F-6DF134E61D24Q36236080-CDE73C91-5691-4AE2-ACD4-DDC1B69E36BBQ36258361-EBF84CF5-7DAF-4811-AF6F-5A907E6DEB9BQ36683817-A434BAA4-2EC2-4CC2-8B1A-DB1F9DFAC612Q37503391-AB38069C-C06B-4923-A6BA-147000D1F0EBQ38641340-D1D21771-B77A-47AC-9C32-8A2BF164DDA1Q39286053-FAC13C5D-576F-4F4C-920F-D0EBDE1BA907Q42328486-6C0645D6-F8F6-4102-A319-7F1DB4BAAF82Q42328487-873CC305-E486-4507-B224-1F42575B641FQ42377288-55C131C4-10DB-4FBC-AD12-022CA6D01592Q47705777-DAB14124-F50A-4F89-8AF2-327FB310865DQ50208805-304E5A15-7DD5-4A29-9358-BBAF62E5AB98Q55436474-ADAAFFF0-D48E-431D-9207-C9BB9FF6F0D6Q57208829-E84D411E-C626-43A1-9C62-2BDFBAD9FD07Q57208936-25118BA2-168F-4C9A-9B5C-205DA23FD7B9Q57208955-E5E7CE15-987D-4589-BF88-D6A76BB3A3C8Q58398031-AA77C124-72CC-4873-B1A5-189DD5895124Q58411927-AE61DDD2-3FB3-40B7-BEF5-C68C817C25C2Q58683496-624F280F-58CB-457E-8BB2-A3116A00062FQ58683531-5030F2D9-DF0C-4D35-9D6C-66AD7164BEFCQ60295748-53EBD963-8987-4373-80FA-B82CE765F5E8Q60295754-F9339D09-13BA-49E1-B6F5-845A2DC0D82AQ60295770-FC0EA74E-0BAA-4E23-85F8-927F1E006D64Q60295781-1DC351E5-1AC5-4244-908D-0F68CDB2C6A5Q60295855-8BFC9C28-F802-4150-A266-853414117398Q60296000-76601145-CA59-4E25-B6A5-C6B17C56D3E5Q63971394-2531E3B9-B920-4438-AF42-DE90C6ED7BFCQ64936364-2B2A8DAA-F644-4F4F-9C7A-15E114B86408Q92342130-810F61B7-399F-485D-AD43-A566F7A759B8Q92586282-88E4C5FD-5AA6-4B68-98D2-2501A5097181Q92740892-22E86EDD-0A39-4688-A5FF-458B81A53BFD
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Mikael K. Sejr
@ast
Mikael K. Sejr
@en
Mikael K. Sejr
@es
Mikael K. Sejr
@nl
Mikael K. Sejr
@sl
type
label
Mikael K. Sejr
@ast
Mikael K. Sejr
@en
Mikael K. Sejr
@es
Mikael K. Sejr
@nl
Mikael K. Sejr
@sl
prefLabel
Mikael K. Sejr
@ast
Mikael K. Sejr
@en
Mikael K. Sejr
@es
Mikael K. Sejr
@nl
Mikael K. Sejr
@sl
P1053
J-5459-2013
P106
P1153
6603493963
P21
P2798
P31
P3829
P3835
mikael-k-sejr
P496
0000-0001-8370-5791