Szczegóły

Tytuł artykułu

Variability of chlorophyll-a and diatoms in the frontal ecosystem of Indian Ocean sector of the Southern Ocean

Tytuł czasopisma

Polish Polar Research

Rocznik

2017

Wolumin

vol. 38

Numer

No 3

Autorzy

Słowa kluczowe

Antarctic ; chlorophyll-a ; diatoms ; Southern Ocean

Wydział PAN

Nauki o Ziemi

Zakres

375-392

Wydawca

Polish Academy of Sciences ; Committee on Polar Research

Data

2017.09.01

Typ

Artykuły / Articles

Identyfikator

DOI: 10.1515/popore-2017-0014 ; ISSN 0138-0338 ; eISSN 2081-8262

Źródło

Polish Polar Research; 2017; vol. 38; No 3; 375-392

Referencje

FurnasM (1991), Net in situ growth rates of phytoplankton in an oligotrophic tropical shelf ecosystem and, Limnology Oceanography, 36, 13. ; LandryM (2001), BrownS Microbial community structure and biomass in surface waters during a Polar Front summer bloom along º Deep - Sea II, Research, 170. ; MannD (1999), The species concept in diatoms, Phycologia, 437. ; MishraR (2017), Shifting of phytoplankton community in the frontal regions of Indian Ocean sector of the Southern Ocean using in situ and satellite data, Journal of Applied Remote Sensing, 1. ; Martin (2000), Silicon metabolism in diatoms Implications for growth of, Journal Phycology, 821. ; SigmanD (2010), The polar ocean and glacial cycles in atmospheric CO concentration, Nature, 466. ; MooreJ (2002), Surface chlorophyll concentrations in relation to the Antarctic Polar Front : seasonal and spatial patterns from satellite observations of System, Journal, 37. ; BuesselerK (2003), The effect of marginal ice - edge dynamics on production and export in the Southern Ocean along ºW Deep - Sea Research II, null, 170. ; MishraR (2015), Adaptations of phytoplankton in the Indian Ocean sector of the Southern Ocean during austral summer of Frontier, Earth Science, 2015. ; StoermerE (1999), The diatoms Applications for the environmental University, Earth Sciences, 469. ; VanHeukelemL (2001), - assisted high - performance liquid chromatography method development with applications to the isolation and analysis of phytoplankton pigments of, Computer Journal Chromatography, 910. ; PalmisanoA (1993), Microorganisms in Antarctic sea ice In ed microbiologyWiley New York, null, 167. ; NelsonD (1995), Production and dissolution of biogenic silica in the ocean : Revised global estimates comparison with regional data and relationship to biogenic sedimentation Global Biogeochemical Cycle, null, 359. ; OrsiA (1995), On the meridional extent and fronts of the Antarctic Circumpolar Current Deep - Sea, Research, 641. ; BintageR (2013), Important role for ocean warming and increased ice - shelf melt in Antarctic sea - ice expansion, Nature Geoscience, 376. ; TreguerP (1995), The silica balance in the world ocean reestimate, Science, 268. ; BarlowR (2007), Seasonal pigment patterns of surface phytoplankton in the subtropical southern hemisphere Deep - Sea, Research, 1687. ; GaoS (2013), - temporal variability of chlorophyll a and its responses to sea surface temperature winds and height anomaly in the western South China Sea, Acta Oceanologica Sinica, 32. ; KirkmanC (2011), The effect of the sea ice freshwater flux on Southern Ocean temperatures in Deep - ocean warming and delayed surface warming of, Journal Climatology, 24, 2224. ; ArrigoK (1998), Physical forcing of phytoplankton dynamics in the western Sea of, Journal Geophysical Research, 103. ; AbbottM (2000), The spring bloom in the Antarctic Polar Frontal Zone as observed from a mesoscale array of bio - optical sensors Deep - Sea II, Research, 3285. ; ParkerM (2008), Genomic insights into marine microalgae of, Annual Review Genetics, 619. ; HonjoS (2008), Particulate organic carbon fluxes to the ocean interior and factors controlling the biological pump ; a synthesis of global sediment trap programmes since in, Progress Oceanography, 217. ; SalasM (2011), Protistan communities in the Australian sector of the Subantarctic Zone during SAZ - Sense Deep - Sea II, Research, 49. ; ArmbrustE (2004), The genome of the diatomThalassiosira pseudonana evolution metabolism, ecology Science, 306. ; FitchD (2007), Wind speed influence on phytoplankton bloom dynamics in the Southern Ocean marginal ice zone of, Journal Geophysical Research, 112. ; BarbaraR (2014), Polar New approaches towards understanding adaptations to an extreme and changing environment Biology, null, 56. ; Morgan (2006), Adaptation and Acclimation of Photosynthetic Microorganisms to Permanently Cold Environments and, Microbiology Molecular Biology Reviews, 222. ; SmetacekV (2004), The role of grazing in structuring Southern Ocean pelagic ecosystems and biogeochemical cycles, Antarctic Science, 16, 541. ; MengeltC (2001), Phytoplankton pigment distribution in relation to silicic acid iron and the physical structure across the Antarctic Polar Front º during austral summer Deep - Sea II, Research, 170. ; MooreJ (2002), FungI Iron cycling and nutrient - limitation patterns in surface waters of the World Ocean Deep - Sea II, Research, 49. ; ArrigoK (1999), Phytoplankton community structure and the drawdown of nutrients and CO in the Southern Ocean, Science, 283. ; GrasshoffK (1983), of seawater analysis ed Verlag Chemie Weinheim, Methods, 419. ; GreggW (2003), iron validation of a global three - dimensional ocean biogeochemical model Deep - Sea II, Research, 3143. ; SalleeJ (2010), Zonally asymmetric response of the Southern Ocean mixed - layer depth to the Southern Annular Mode, Nature Geoscience, 273. ; HollidayN (1998), Surface oceanic fronts between Deep - Sea, Africa Research, 217. ; GaoY (2003), FanS iron input to the ocean through precipitation scavenging modelling perspective and its implication for natural iron fertilization of the ocean of, Journal Geophysical Research, 108. ; SigmanD (2000), Glacial variations in atmospheric carbon dioxide, Nature, 407. ; ArmandL (2005), The biogeography of major diatom taxa in Southern Ocean sediments Sea ice related species, Palaeogeography Palaeoclimatology Palaeoecology, 1.

Rada naukowa


Editorial Advisory Board


Angelika BRANDT (Hamburg),

Claude DE BROYER (Bruxelles),

Peter CONVEY (Cambridge, UK),

J. Alistair CRAME (Cambridge, UK),

Rodney M. FELDMANN (Kent, OH),

Jane E. FRANCIS (Cambridge, UK),

Andrzej GAŹDZICKI (Warszawa)

Aleksander GUTERCH (Warszawa),

Jacek JANIA (Sosnowiec),

Jiří KOMÁREK (Třeboň),

Wiesława KRAWCZYK (Sosnowiec),

German L. LEITCHENKOV (Sankt Petersburg),

Jerónimo LÓPEZ-MARTINEZ (Madrid),

Sergio A. MARENSSI (Buenos Aires),

Jerzy NAWROCKI (Warszawa),

Ryszard OCHYRA (Kraków),

Maria OLECH (Kraków)

Sandra PASSCHIER (Montclair, NJ),

Jan PAWŁOWSKI (Genève),

Gerhard SCHMIEDL (Hamburg),

Jacek SICIŃSKI (Łódź),

Michael STODDART (Hobart),

Witold SZCZUCIŃSKI (Poznań),

Andrzej TATUR (Warszawa),

Wim VADER (Tromsø),

Tony R. WALKER (Halifax, Nova Scotia),

Jan Marcin WĘSŁAWSKI (Sopot) - President.

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