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. (2019). A comparison of approaches for the prediction and inversion of surface wave phase delays (Vol. 217).
Abstract: SUMMARY. A controlled experiment was performed to investigate the influence of different assumptions made about the propagation of surface waves in surface wav
Programme: 133
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Tolle F., Prokop A., Bernard E., Friedt J.-M., Marlin C., Griselin M. (2014). A comparison of in situ and remote techniques to detect changes in an Arctic glacier basin: from ablation stakes to photogrammetry..
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Cunningham G.B., Van Buskirk R.W., Bonadonna F., Weimerskirch H. & Nevitt G.A. (2003). A comparison of the olfactory abilities of three species of procellariiform chicks. J. Exp. Biol., 206, 1615–1620.
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Clausen H., Hammer C.U., Hvidberg C.S., Dahl Jensen D., Steffensen J.P., Kipstuhl J. & Legrand M. (1997). A comparison of the volcanic records over the past 4000 years from the Greenland Ice Core Project and Dye 3 Greenland ice cores. J. Geophys. Res., 102(C12), 26707–26723.
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Waelbroeck C., Jouzel J., Labeyrie L., Lorius C., Stievenard M. & Barkov N.I. (1995). A comparison of the Vostok ice deuterium record and series from Southern Ocean core MD 88-770 over the last two glacial-interglacial cycles. Climate dynamics, 12, 113–123.
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Sanne Muis, Martin Verlaan, Robert J. Nicholls, Sally Brown, Jochen Hinkel, Daniel Lincke, Athanasios T. Vafeidis, Paolo Scussolini, Hessel C. Winsemius, Philip J. Ward. (2017). A comparison of two global datasets of extreme sea levels and resulting flood exposure (Vol. 5).
Keywords: coastal floods extreme sea levels flood risk hydrodynamic modeling natural hazards storm surge
Programme: 688
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Provost C., Bernier C. & Blayo L.E. (1994). A comparison of Two Numerical methods for Integrating a Quasi-geostrophic Multilayer Model of Ocean Circulations: Finite Difference Methods. Journal of computational physics, 110, 341–359.
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Preiss N., Melieres M.A. & Pourchet M. (1996). A compilation of data on lead-210 concentration in surface air and fluxes at the air-surface and water-sediment interfaces. J. Geophys. Res., D22(101), 847–862.
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. (2015). Ecography, 38(2), 111–113.
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. (2013). A comprehensive isotopic investigation of habitat preferences in nonbreeding albatrosses from the Southern Ocean
. ECOGRAPHY, 36(3), 277–286.
Abstract: Albatrosses are among the world's most endangered seabirds. Threats during the nonbreeding period have major impacts on their population dynamics, but for most species, detailed information on distribution and ecology remains essentially unknown. We used stable isotope values (δ13C and δ15N) in feathers to infer and compare the moulting (nonbreeding) habitats of 35 populations that include all the 20 species and subspecies (444 individuals) of albatrosses breeding within the Southern Ocean and in fringing subtropical waters. Isotopic values together with a review of available information show that the 20 albatrosses can be categorized into three groups depending on their favoured moulting grounds: 12 (60%) taxa forage primarily in warm neritic waters, six (30%) in northern oceanic waters and two (10%) in oceanic waters of the Southern Ocean. Stable isotopes indicate that habitat preferences during the nonbreeding period vary much less among different breeding populations in some species (wandering, Salvin's, grey-headed and light-mantled sooty albatrosses), than others (black-browed, Indian yellow-nosed and sooty albatrosses). The major finding of our isotopic investigation is that the great majority of albatrosses spend the nonbreeding period outside the Southern Ocean, with only three species (and in the sooty albatross, just one of the breeding populations) favouring oceanic subantarctic waters at that time. Hence, the study highlights the overwhelming importance of subtropical waters for albatrosses, where the birds are known to interact with human activities and are more likely to be negatively affected by the diverse range of fisheries operating in both neritic and oceanic waters.
Programme: 109
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