Biblio
Filters: Author is Eldevik, Tor [Clear All Filters]
Gas exploration beyond the shelf break: an oceanographic challenge. Environmental Modelling & Software 21, 136-141 (2006).
THE ROLE OF THE BARENTS SEA IN THE ARCTIC CLIMATE SYSTEM. Reviews of geophysics 51, (2013). Download: The role of the Barents_ROG.pdf (3.32 MB)
Mechanisms for variable North Atlantic–Nordic seas exchanges. Journal of Geophysical Research 117, (2012).
Mechanisms for variable North Atlantic-Nordic seas exchanges. Journal of Geophysical Research (JGR): Oceans 117, (2012).
The Lofoten Vortex of the Nordic Seas. Deep Sea Research Part I: Oceanographic Research Papers 96, (2015).
Mesoscale ocean eddy dataset in the Lofoten Basin from Satellite Altimetry. Journal of Geophysical Research - Oceans 121, (2016).
Quantifying mesoscale eddies in the Lofoten Basin. Journal of Geophysical Research (JGR): Oceans 121, (2016).
Impact of initialization methods on the predictive skill in NorCPM: an Arctic–Atlantic case study. Climate Dynamics (2022).doi:10.1007/s00382-022-06437-4
Intermediate water from the Greenland Sea in the Faroe Bank Channel: spreading of released sulphur hexafluoride. Deep-Sea Research 52, 279-294 (2005).
A Greenland Sea perspective on the dynamics of post-convective eddies. Journal of physical oceanography 2755-2771 (2008).
Observed Sources and variability of Nordic seas overflow. IPY - OsloScience Conference (2010). Download: Nilsen-IPY-OSC2010_abstract.pdf (66.76 KB)
On the reconstruction of ocean circulation and climate based on the “Gardar Drift” (poster). The Past Earth Network (PEN) opening conference (2015). Download: langehaug_poster_pen.pdf (3.38 MB)
Mechanisms for decadal scale variability in the North Atlantic Ocean circulation in the Bergen Climate Model (talk). European Geophysical Union (2012). Download: egu2012_abstract.pdf (33.7 KB)
Mechanisms for decadal scale variability in a simulated Atlantic meridional overturning circulation (paper). Climate Dynamics (2012).doi:DOI 10.1007/s00382-011-1124-z
Mechanisms for decadal scale variability in a simulated Atlantic Meridional Overturning Circulation. Climate Dynamics 39, (2012).
Klima i de lange linjers perspektiv. (2009).at <http://www.forskning.no/artikler/2009/juni/223350> Download: forskning.no > Klima i de lange linjers perspektiv.pdf (137.65 KB)
Water mass transformation and the North Atlantic Current in three multicentury climate model simulations. Journal of Geophysical Research (JGR): Oceans 117, (2012).
Mechanisms for decadal scale variability in the North Atlantic Ocean circulation in the BCM (talk). Joint ASOF/THOR workshop (2011). Download: asof_thor2011_abstract.pdf (51.28 KB)
Decadal predictability of winter SST in the Nordic Seas and the Barents Sea in three CMIP5 models (talk). Annual Meeting NACLIM (2014).
On model differences and skill in predicting sea surface temperature in the Nordic and Barents Seas. Climate Dynamics 48, (2016).
Water mass transformation and the North Atlantic Current in three multi-century climate model simulations (talk). Ocean Sciences Meeting (2012). Download: osm2012_abstract.pdf (50.73 KB)
On the reconstruction of ocean circulation and climate based on the “Gardar Drift” (talk). Arctic Workshop 2015 (2015).
Circulation and transformation of Atlantic and Arctic water masses in climate models. Doctoral thesis no. 94 180 (2011).at <http://hdl.handle.net/1956/5282>
Decadal predictability of SST in the North Atlantic sector in three CMIP5 models (talk). Workshop on predictability of climate in the North Atlantic Sector (2014).
