Surdyck S. & Fujita S. (1995). Microwave dielectric properties of snow:modeling and measurements. Geophysical research letters, 22(8), 965–968.
|
Delmonte B., Petit J.R. & Maggi V. (2002). Glacial to Holocene implications of the new 27000-year dust record from the EPICA Dome C (East Antarctica) ice core. Climate dynamics, 18(8), 647–660.
|
Ropert-Coudert Y., Wilson R.P. (2005). Trends and perspectives in animal-attached recording tags. Frontiers in ecology and the environment, 3(8), 437–444.
|
Harding, A.M.A., J.F. Piatt, J.A. Schmutz, M.T Shultz, T.I. Van Pelt, A.B. Kettle and S.G. Speckman. (2007). Prey density and the behavioural flexibility of a marine predator: the common guillemot (Uria aalge). Ecology, 88(8), 2024–2033.
|
Savarino J, Kaiser J, Morin S, Sigman D M, Thiemens M H, . (2007). Nitrogen and oxygen isotopic constraints on the origin of atmospheric nitrate in coastal Antarctica
. Atmospheric Chemistry and Physics, 7(8), 1925–1945.
Abstract: Throughout the year 2001, aerosol samples were collected continuously for 10 to 15 days at the French Antarctic Station Dumont d'Urville DDU) (66 degrees 40' S, 140 degrees 01' E, 40m above mean sea level). The nitrogen and oxygen isotopic ratios of particulate nitrate at DDU exhibit seasonal variations that are among the most extreme observed for nitrate on Earth. In association with concentration measurements, the isotope ratios delineate four distinct periods, broadly consistent with previous studies on Antarctic coastal areas. During austral autumn and early winter March to mid-July), nitrate concentrations attain a minimum between 10 and 30 ng m(-3) referred to as Period 2). Two local maxima in August (55 ng m(-3)) and November/December (165 ng m(-3)) are used to assign Period 3 (mid-July to September) and Period 4 October to December). Period 1 January to March) is a transition period between the maximum concentration of Period 4 and the background concentration of Period 2. These seasonal changes are reflected in changes of the nitrogen and oxygen isotope ratios. During Period 2, which is characterized by background concentrations, the isotope ratios are in the range of previous measurements at midlatitudes: delta O-18(vsmow)=(77.2 8.6)parts per thousand; Delta O-17=(29.8 4.4)parts per thousand; delta N-15(air)=(- 4.4 5.4)parts per thousand mean one standard deviation). Period 3 is accompanied by a significant increase of the oxygen isotope ratios and a small increase of the nitrogen isotope ratio to delta O-18(vsmow)=( 98.8 13.9)parts per thousand; Delta O-17=(38.8 4.7)parts per thousand and delta N-15(air)=(4.3 8.20 parts per thousand). Period 4 is characterized by a minimum N-15/N-14 ratio, only matched by one prior study of Antarctic aerosols, and oxygen isotope ratios similar to Period 2: delta O-18(vsmow)=(77.2 7.7)parts per thousand; Delta O-17=(31.1 3.2)parts per thousand; delta N-15(air)=(- 32.7 8.4)parts per thousand. Finally, during Period 1, isotope ratios reach minimum values for oxygen and intermediate values for nitrogen: delta O-18(vsmow)= 63.2 2.5 parts per thousand; Delta O-17= 24.0 1.1 parts per thousand; delta N-15(air)=- 17.9 4.0 parts per thousand). Based on the measured isotopic composition, known atmospheric transport patterns and the current understanding of kinetics and isotope effects of relevant atmospheric chemical processes, we suggest that elevated tropospheric nitrate levels during Period 3 are most likely the result of nitrate sedimentation from polar stratospheric clouds (PSCs), whereas elevated nitrate levels during Period 4 are likely to result from snow re-emission of nitrogen oxide species. We are unable to attribute the source of the nitrate during periods 1 and 2 to local production or long-range transport, but note that the oxygen isotopic composition is in agreement with day and night time nitrate chemistry driven by the diurnal solar cycle. A precise quantification is difficult, due to our insufficient knowledge of isotope fractionation during the reactions leading to nitrate formation, among other reasons.
Programme: 414
|
Crouzet N, Guillot T, Fressin F, Blazit A, the A STEP team, . (2007). Front- vs. back-illuminated CCD cameras for photometric surveys: a noise budget analysis
(Vol. 328). WILEY-VCH Verlag.
Keywords: instrumentation: detectors, methods: numerica, technique: photometric,
Programme: 1066
|
. (2009). Microstructures of Antarctic cidaroid spines: diversity of shapes and ectosymbiont attachments
. Mar. Biol., 156(8), 1559–1572.
|
Nevoux M, Forcada J, Barbraud C, Croxall J, Weimerskirch H, . (2010). Bet-hedging response to environmental variability, an intraspecific comparison
. Ecology, 91(8), 2416–2427.
|
. (2011). The Antarctic fish genus Artedidraco is paraphyletic (Teleostei, Notothenioidei, Artedidraconidae)
. Polar Biol., 34(8), 1135–1145.
Abstract: Artedidraconids (Plunderfishes) are small benthic notothenioid fishes of the Antarctic and South Georgia shelf and slope. The family Artedidraconidae is monophyletic; however, the relationships within the family have remained poorly explored until now, and based on a small sample of the genus Artedidraco . The present study focuses on the interrelationships among the artedidraconid genera and the phylogeny of the genus Artedidraco . 2,353 base pairs from 77 specimens were sequenced from the partial mitochondrial cytochrome oxidase I gene and cytochrome b gene, the partial mitochondrial control region and the partial nuclear rhodopsin retrogene. The genus Artedidraco is not monophyletic, confirming the preliminary relationships found by Derome et al. (Mol Phylogenet Evol 24:139152, 2002 ): Pogonophryne , Dolloidraco and Histiodraco are well embedded within the genus Artedidraco . From Artedidraco skottsbergi and A. loennbergi to A. orianae and A. mirus , the tree shows that there is an increasing number of upper lateral line tubular scales and decreasing number of disc-shaped scales. There is also a trend toward a decrease in the number of epipleural ribs and an increase in number of pleural ribs along the tree.
Keywords: Biomedical and Life Sciences,
Programme: 1124
|
Bousquet P, Ringeval B, Pison I, Dlugokencky E J, Brunke E-G, Carouge C, Chevallier F, Fortems-Cheiney A, Frankenberg C, Hauglustaine D A, Krummel P B, Langenfelds R L, Ramonet M, Schmidt M, Steele L P, Szopa S, Yver C, Viovy N, Ciais P, . (2011). Source attribution of the changes in atmospheric methane for 2006-2008
. 1680-7316, 11(8), 3689–3700.
|