- E-postannette.samuelsen@uib.no
- BesøksadresseAllégaten 705007 Bergen
- PostadressePostboks 78035020 Bergen
Vitenskapelig artikkel
- (2024). Gathering users and developers to shape together the next-generation ocean reanalysis. Bulletin of The American Meteorological Society - (BAMS).
- (2023). Phytoplankton abundance in the Barents Sea is predictable up to five years in advance. Communications Earth & Environment. 9 sider.
- (2023). Key physical processes and their model representation for projecting climate impacts on subarctic Atlantic net primary production: A synthesis. Progress in Oceanography. 11 sider.
- (2023). An along-Track Biogeochemical Argo modelling framework: A case study of model improvements for the Nordic seas. Geoscientific Model Development. 6875-6897.
- (2022). Implementation and evaluation of open boundary conditions for sea ice in a regional coupled ocean (ROMS) and sea ice (CICE) modeling system. Geoscientific Model Development. 4373-4392.
- (2022). Environmental Change at Deep-Sea Sponge Habitats Over the Last Half Century: A Model Hindcast Study for the Age of Anthropogenic Climate Change. Frontiers in Marine Science. 1-17.
- (2022). ECOSMO II(CHL): a marine biogeochemical model for the North Atlantic and the Arctic. Geoscientific Model Development. 3901-3921.
- (2021). Water masses constrain the distribution of deep-sea sponges in the North Atlantic Ocean and Nordic Seas. Marine Ecology Progress Series. 75-96.
- (2021). Twenty-One Years of Phytoplankton Bloom Phenology in the Barents, Norwegian, and North Seas. Frontiers in Marine Science. 1-16.
- (2021). Surface freshwater fluxes in the Arctic and Subarctic Seas during contrasting years of high and low summer sea ice extent. Remote Sensing.
- (2021). NorCPM1 and its contribution to CMIP6 DCPP. Geoscientific Model Development. 7073-7116.
- (2021). Can Environmental Conditions at North Atlantic Deep-Sea Habitats Be Predicted Several Years Ahead? ——Taking Sponge Habitats as an Example. Frontiers in Marine Science. 1-22.
- (2020). Ocean Biogeochemical Predictions—Initialization and Limits of Predictability. Frontiers in Marine Science.
- (2019). Risk of oil contamination of fish eggs and larvae under different oceanic and weather conditions. ICES Journal of Marine Science. 1902-1916.
- (2019). Evaluation of Arctic Ocean surface salinities from the Soil Moisture and Ocean Salinity (SMOS) mission against a regional reanalysis and in situ data. Ocean Science. 1191-1206.
- (2018). Sensitivity of the simulated Oxygen Minimum Zone to geochemical processes at an oligotrophic site in the Arabian Sea. Ecological Modelling. 12-23.
- (2018). Ocean heat content, In: Copernicus Marine Service Ocean State Report. Journal of operational oceanography. Publisher: The Institute of Marine Engineering, Science & Technology.
- (2018). Delineation of marine ecosystem zones in the northern Arabian Sea using an objective method. Biogeosciences. 1395-1414.
- (2018). Agulhas Current Meanders Facilitate Shelf-Slope Exchange on the Eastern Agulhas Bank. Journal of Geophysical Research (JGR): Oceans. 4762-4778.
- (2017). Online tuning of ocean biogeochemical model parameters using ensemble estimation techniques: Application to a one-dimensional model in the North Atlantic. Journal of Marine Systems. 1-16.
- (2017). Ensemble data assimilation for ocean biogeochemical state and parameter estimation at different sites. Ocean Modelling. 65-89.
- (2016). The Copernicus Marine Environment Monitoring Service Ocean State Report. Journal of operational oceanography. Publisher: The Institute of Marine Engineering, Science & Technology. s235-s320.
- (2016). Net primary productivity estimates and environmental variables in the Arctic Ocean: An assessment of coupled physical-biogeochemical models. Journal of Geophysical Research (JGR): Oceans. 8635-8669.
- (2015). Tuning and assessment of the HYCOM-NORWECOM V2.1 biogeochemical modeling system for the North Atlantic and Arctic oceans. Geoscientific Model Development. 2187-2202.
- (2015). Experiences in multiyear combined state-parameter estimation with an ecosystem model of the North Atlantic and Arctic Oceans using the Ensemble Kalman Filter. Journal of Marine Systems. 1-17.
- (2015). Building the capacity for forecasting marine biogeochemistry and ecosystems: recent advances and future developments. Journal of operational oceanography. Publisher: The Institute of Marine Engineering, Science & Technology.
- (2012). Particle aggregation at the edges of anticyclonic eddies and implications for distribution of biomass. Ocean Science. 389-400.
- (2012). Mesoscale Eddies Are Oases for Higher Trophic Marine Life. PLOS ONE. 9 sider.
- (2012). Estimation of positive sum-to-one constrained zooplankton grazing preferences with the DEnKF: a twin experiment. Ocean Science. 587-602.
- (2010). Validation of a hybrid coordinate ocean model for the Indian Ocean. Journal of operational oceanography. Publisher: The Institute of Marine Engineering, Science & Technology. 25-38.
- (2010). Anticyclonic eddies in the Norwegian Sea; their generation, evolution and impact on primary production. Deep Sea Research Part I: Oceanographic Research Papers.
- (2009). Shelf recruitment of Calanus finmarchicus off the west coast of Norway: role of physical processes and timing of diapause termination. Marine Ecology Progress Series. 163-180.
- (2009). Impact of data assimilation of physical variables on the spring bloom from TOPAZ operational runs in the North Atlantic. Ocean Science. 635-647.
- (2009). Hurricane-driven alteration in plankton community size structure in the Gulf of Mexico: A modeling study. Geophysical Research Letters. 6 sider.
Rapport
- (2022). MODELING MARINE PRIMARY PRODUCTION IN THE ARCTIC: THE IMPACT OF SEA ICE MODELS USING DIFFERENT SEA ICE RHEOLOGY. 414. 414. .
- (2020). Kepler Deliverable Report D5.1:Synthesis on the visions of the evolution of the Copernicus services. .
- (2016). D5.1 MANUSCRIPTS ON THE IMPACT OF AN OIL SPILL ON THE LTL GROUPS, ICHTHYOPLANKTON, AND FISH RECRUITMENT - DELIVERABLE FOR PROJECT: SEAMAN. 371. 371. .
- (2014). Towards the next generation plankton models – expert recommendations for the future development of plankton models. .
- (2014). SeaU report: Drift statistics. .
- (2014). Network building on oceanic meso-scale eddies and marine ecosystems. 335. 335. .
- (2012). Report on error quantified hindcast with data assimilation (GreenSeas). .
Faglig foredrag
- (2019). Biogeochemical Predictions - Initialization and Sources of Potential Predictability.
- (2019). Biogeochemical Predictions - An update from Bergen.
- (2016). ARCMFC Multi Year Products.
- (2016). ARCMFC CMEMS Annual Operations Review Multi Year Products Coordination.
Vitenskapelig foredrag
- (2023). Multiyear phytoplankton predictability in the Barents Sea.
- (2023). Biogeochemical data assimilation in Copernicus Marine Services - status and future evolution.
- (2022). Twenty-one years of Phytoplankton bloom phenology in the Barents, Norwegian and North seas.
- (2022). Skillful Prediction of Barents Sea Phytoplankton Concentration.
- (2021). Key physical processes for evaluating climate impacts on subarctic primary production.
- (2018). Using the Ensemble Kalman Filter for Arctic sea ice forecasting: towards a fully Lagrangian approach.
- (2018). Modelling Cross-latitude Variability in Carbon Export Efficiency.
- (2018). Making hindcast with HYCOM-ECOSMO.
- (2018). Does Indian dipole regulate the annual oil sardine (Sardinella longgiceps) landings in Kerala?
- (2018). Arctic sea ice (and icebergs) in a changing climate .
- (2018). Applications and recent developments of the biogeochemical model in the TOPAZ forecasting system.
- (2017). Modelling the influence of Atlantic water inflow on primary production and phytoplankton composition in the Fram Strait.
- (2016). Risk of oil contamination of fish eggs and larvae under different oceanic and weather conditions.
- (2015). Net primary Production as an ecological indicator: Application and efficacy of a marine ecosystem model.
- (2012). Mesoscale eddies stimulate higher trophic level marine life—acoustically recorded density distribution creates understanding of the impact of physical forcing.
- (2011). Ecosystem response top climate and high CO2.
Populærvitenskapelig artikkel
- (2012). Advanced data assimilation in oceanography. META. 8-12.
Kronikk
- (2012). Virvler i havet skaper oaser av liv. Bergens Tidende.
Programledelse
- (2019). Surfing, oljesøl og torskeyngel.
Poster
- (2023). The Nansen Centers, Trevor Platt and Shunha Sathyendranath – scientific association for capacity building.
- (2021). Predictability of Barents Sea Phytoplankton Concentration.
- (2021). Phytoplankton bloom phenology along the Norwegian continental shelf.
- (2020). Ocean Biogeochemical Predictions.
- (2018). Biogeochemical operational modeling in the Arctic using the TOPAZ forecasting system.
- (2017). Bio-ARGO as a potential source of regular validation and model improvement in an operational biogeochemical model.
- (2017). Bio-ARGO as a potential source of regular validation and model improvement in an operational biogeochemical model.
- (2016). The role of mesoscale eddies for primary production along the ice edge.
- (2016). The role of mesoscale eddies along the ice edge for primary production in the Fram Strait.
- (2016). Investigating the influence of Atlantic water inflow on primary production in a regional model for the Fram Strait .
- (2014). A MULTIMETHOD APPROACH TO LINKING MESOSCALE STRUCTURES TO DISTRIBUTION.
Vitenskapelig oversiktsartikkel/review
- (2015). Status and trends in the structure of Arctic benthic food webs. Polar Research.
Utstillingskatalog
- (2017). Hav er meir enn vatn.
Faglig kapittel
- (2016). MYOCEAN REGIONAL REANALYSES:OVERVIEW OF REANALYSES SYSTEMS AND MAIN RESULTS. 43-69. I:
- (2016). MERCATOR OCEAN JOURNAL NO 54: Main outcomes of the Myocean2 and Myocean follow-on projects. .