Biblio
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Ocean Eddy Signature on SAR-Derived Sea Ice Drift and Vorticity. Geophysical Research Letters 48, (2021).
An ocean modelling and assimilation guide to using GOCE geoid products. Ocean Science 7, (2011). Abstract
Download: gocino_paper.pdf (2.23 MB)
Oceanic forcing of the global warming slowdown in multi-model simulations. International Journal of Climatology (2020).doi:10.1002/joc.6548
Ocean–atmosphere coupled Pacific Decadal variability simulated by a climate model. Climate Dynamics 54, (2020).
Overview of the Norwegian Earth System Model (NorESM2) and key climate response of CMIP6 DECK, historical, and scenario simulations. Geoscientific Model Development 13, (2020).
Overview of the results of the project ‘Loads on Structure and Waves in Ice’ (LS-WICE). Konferansebidrag Proceedings of the HYDRALAB+ Joint User Meeting, (2019).
Pan Eurasian Experiment (PEEX) - A research initiative meeting the grand challenges of the changing environment of the Northern Pan-Eurasian Arctic Boreal Areas. Geography, Environment, Sustainability (2014).doi:10.24057/2071-9388-2014-7-2-13-48 Download: lappalinen_esau_etal_2014_ges_peex_description.pdf (730.59 KB)
Pan-Eurasian Experiment (PEEX): Towards a holistic understanding of the feedbacks and interactions in the land-Atmosphere-ocean-society continuum in the northern Eurasian region. Atmospheric Chemistry and Physics (ACP) 16, (2016).
Parameterization of an iceberg drift model in the Barents Sea. Journal of atmospheric and oceanic technology 26, 12 (2009).
The plankton community in Norwegian coastal waters - abundance, composition, spatial distribution and diel variation. Continental Shelf Research 31, 14 (2011). Download: Bratbak-2011-14ef840bab756b8233e36bf3288125fc.pdf (2.56 MB)
Polar Ocean Observations: A critical gap in the observing system and its effect on environmental predictions from hours to a season. Frontiers in Marine Science (2019).doi:10.3389/fmars.2019.00429
Poleward ocean heat transports, sea ice processes, and Arctic sea ice variability in NorESM1-M simulations. Journal of Geophysical Research (JGR): Biogeosciences 119, (2014).
Possibilities of applying the concept of “winter city” in the Russian Arctic (On the example of the city of Nadym). Arktika: Ekologija i ekonomika 11, (2021).
A possible mechanism for the strong weakening of the North Atlantic subpolar gyre in the mid-1990s. Geophysical Research Letters 36, (2009). Download: 2009GL039166.pdf (193.77 KB)
Potential changes in the connectivity of marine protected areas driven by extreme ocean warming. Scientific Reports 11, (2021). Abstract
Preceding winter Okhotsk Sea ice as a precursor to the following winter extreme precipitation in South China. Atmospheric Science Letters 23, (2022).
Propagation of Thermohaline Anomalies and Their Predictive Potential along the Atlantic Water Pathway. Journal of Climate 35, (2021).
Quality assessment of the TOPAZ4 reanalysis in the Arctic over the period 1991-2013. Ocean Science 13, (2017).
Quantification of the Arctic Sea Ice‐Driven Atmospheric Circulation Variability in Coordinated Large Ensemble Simulations. Geophysical Research Letters 47, (2020).
Radar backscattering changes in Arctic sea ice from late summer to early autumn observed by space-borne X-band HH-polarization SAR. Remote Sensing Letters 7, (2016).
Reassessing changes in diurnal temperature range: A new data set and characterization of data biases. Journal of Geophysical Research (JGR): Atmospheres 121, (2016).
Reassessing changes in Diurnal Temperature Range: A new dataset and characterization of data biases. Journal of Geophysical Research (JGR): Atmospheres 121, (2016).
