The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes

Two Antarctic lakes near Hope Bay were studied during summers 1998 and 1999. One of the lakes (Boeckella) is located near Esperanza Station and exhibits a meso-eutrophic condition due to the input of nutrients of a nearby penguin rookery. Its surface generally remains ice-free during the Antarctic s...

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Bibliographic Details
Main Authors: Allende, Luz, Izaguirre, Irina
Language:unknown
Published: 2003
Subjects:
Antarctic lakes
Functional groups
Picocyanobacteria
Thermal patterns
Bacteria
Biodiversity
Biomass
Ecology
Lakes
Phase equilibria
Wind
Water bodies
Marine biology
community structure
ecological stability
functional group
ice cover
lake ecosystem
phytoplankton
steady-state equilibrium
stratification
Antarctic Peninsula
Antarctica
Lake Boeckella
Lake Chico
West Antarctica
algae
Bacteria (microorganisms)
Chlamydomonas
Chromulina
Chrysophyceae
Esperanza
Ochromonas
Spheniscidae
Antarctic
Boeckella
Boeckella Lake
Esperanza Station
Hope Bay
Mount Flora
The Antarctic
Antarc*
Online Access:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00188158_v502_n_p211_Allende
https://hdl.handle.net/20.500.12110/paper_00188158_v502_n_p211_Allende
id ftunibueairesbd:paper:paper_00188158_v502_n_p211_Allende
record_format openpolar
spelling ftunibueairesbd:paper:paper_00188158_v502_n_p211_Allende 2023-05-15T13:51:25+02:00 The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes Allende, Luz Izaguirre, Irina 2003 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00188158_v502_n_p211_Allende https://hdl.handle.net/20.500.12110/paper_00188158_v502_n_p211_Allende unknown https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00188158_v502_n_p211_Allende http://hdl.handle.net/20.500.12110/paper_00188158_v502_n_p211_Allende Antarctic lakes Functional groups Picocyanobacteria Thermal patterns Bacteria Biodiversity Biomass Ecology Lakes Phase equilibria Wind Water bodies Marine biology community structure ecological stability functional group ice cover lake ecosystem phytoplankton steady-state equilibrium stratification Antarctic Peninsula Antarctica Lake Boeckella Lake Chico West Antarctica algae Bacteria (microorganisms) Chlamydomonas Chromulina Chrysophyceae Esperanza Ochromonas Spheniscidae 2003 ftunibueairesbd https://doi.org/20.500.12110/paper_00188158_v502_n_p211_Allende 2023-02-16T02:19:50Z Two Antarctic lakes near Hope Bay were studied during summers 1998 and 1999. One of the lakes (Boeckella) is located near Esperanza Station and exhibits a meso-eutrophic condition due to the input of nutrients of a nearby penguin rookery. Its surface generally remains ice-free during the Antarctic summer (December-March). The other lake (Chico) is situated on the Mount Flora shelf, is typically oligotrophic and its surface is ice-free only during brief periods in the summer season. The difference in the duration of the ice-cover insures that the wind mixes the former lake continuously throughout the summer, while the latter remains almost always stratified. X2, X3 and Z functional groups defined by Reynolds dominated phytoplankton in both lakes. In Lake Boeckella, Chlamydomonas spp. followed by Ochromonas sp. were the most frequently encountered taxa in the nano-phytoplankton fraction, however the latter species was dominant when the lake froze. In Lake Chico, the major contribution to this fraction was due to different genera of flagellated Chrysophyceae (Ochromonas sp., Chromulina spp., cf. Chrysidalis). In terms of density and biomass in both lakes picocyanobacteria represented a large proportion of the phytoplankton. Probably due to the typically low algal biodiversity of Antarctic lakes, both water bodies showed periods of more than 2 weeks when a maximum of only three species comprised more than 80% of the standing crop. In spite of this, Chico Lake was the only one in which no significant change was recorded in total biomass. Thus, we were able to identify equilibrium phases in the latter lake, which were confirmed by a low coefficient of variation. The presence of an almost permanent ice cover in Chico Lake generated more stable ecological conditions, allowing the development of steady state assemblages. On the contrary, the wind influence in the shallow Antarctic ice free lake (Lake Boeckella) provided continuous mixing events, disrupting the possibility of establishing a steady state. Fil:Allende, L. ... Other/Unknown Material Antarc* Antarctic Antarctic Peninsula Antarctica West Antarctica Biblioteca Digital FCEN-UBA (Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires) Antarctic Antarctic Peninsula Boeckella ENVELOPE(-56.999,-56.999,-63.404,-63.404) Boeckella Lake ENVELOPE(-56.999,-56.999,-63.404,-63.404) Esperanza ENVELOPE(-56.983,-56.983,-63.400,-63.400) Esperanza Station ENVELOPE(-56.996,-56.996,-63.395,-63.395) Hope Bay ENVELOPE(-57.038,-57.038,-63.403,-63.403) Lake Boeckella ENVELOPE(-57.000,-57.000,-63.400,-63.400) Mount Flora ENVELOPE(-57.008,-57.008,-63.417,-63.417) The Antarctic West Antarctica
institution Open Polar
collection Biblioteca Digital FCEN-UBA (Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires)
op_collection_id ftunibueairesbd
language unknown
topic Antarctic lakes
Functional groups
Picocyanobacteria
Thermal patterns
Bacteria
Biodiversity
Biomass
Ecology
Lakes
Phase equilibria
Wind
Water bodies
Marine biology
community structure
ecological stability
functional group
ice cover
lake ecosystem
phytoplankton
steady-state equilibrium
stratification
Antarctic Peninsula
Antarctica
Lake Boeckella
Lake Chico
West Antarctica
algae
Bacteria (microorganisms)
Chlamydomonas
Chromulina
Chrysophyceae
Esperanza
Ochromonas
Spheniscidae
spellingShingle Antarctic lakes
Functional groups
Picocyanobacteria
Thermal patterns
Bacteria
Biodiversity
Biomass
Ecology
Lakes
Phase equilibria
Wind
Water bodies
Marine biology
community structure
ecological stability
functional group
ice cover
lake ecosystem
phytoplankton
steady-state equilibrium
stratification
Antarctic Peninsula
Antarctica
Lake Boeckella
Lake Chico
West Antarctica
algae
Bacteria (microorganisms)
Chlamydomonas
Chromulina
Chrysophyceae
Esperanza
Ochromonas
Spheniscidae
Allende, Luz
Izaguirre, Irina
The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
topic_facet Antarctic lakes
Functional groups
Picocyanobacteria
Thermal patterns
Bacteria
Biodiversity
Biomass
Ecology
Lakes
Phase equilibria
Wind
Water bodies
Marine biology
community structure
ecological stability
functional group
ice cover
lake ecosystem
phytoplankton
steady-state equilibrium
stratification
Antarctic Peninsula
Antarctica
Lake Boeckella
Lake Chico
West Antarctica
algae
Bacteria (microorganisms)
Chlamydomonas
Chromulina
Chrysophyceae
Esperanza
Ochromonas
Spheniscidae
description Two Antarctic lakes near Hope Bay were studied during summers 1998 and 1999. One of the lakes (Boeckella) is located near Esperanza Station and exhibits a meso-eutrophic condition due to the input of nutrients of a nearby penguin rookery. Its surface generally remains ice-free during the Antarctic summer (December-March). The other lake (Chico) is situated on the Mount Flora shelf, is typically oligotrophic and its surface is ice-free only during brief periods in the summer season. The difference in the duration of the ice-cover insures that the wind mixes the former lake continuously throughout the summer, while the latter remains almost always stratified. X2, X3 and Z functional groups defined by Reynolds dominated phytoplankton in both lakes. In Lake Boeckella, Chlamydomonas spp. followed by Ochromonas sp. were the most frequently encountered taxa in the nano-phytoplankton fraction, however the latter species was dominant when the lake froze. In Lake Chico, the major contribution to this fraction was due to different genera of flagellated Chrysophyceae (Ochromonas sp., Chromulina spp., cf. Chrysidalis). In terms of density and biomass in both lakes picocyanobacteria represented a large proportion of the phytoplankton. Probably due to the typically low algal biodiversity of Antarctic lakes, both water bodies showed periods of more than 2 weeks when a maximum of only three species comprised more than 80% of the standing crop. In spite of this, Chico Lake was the only one in which no significant change was recorded in total biomass. Thus, we were able to identify equilibrium phases in the latter lake, which were confirmed by a low coefficient of variation. The presence of an almost permanent ice cover in Chico Lake generated more stable ecological conditions, allowing the development of steady state assemblages. On the contrary, the wind influence in the shallow Antarctic ice free lake (Lake Boeckella) provided continuous mixing events, disrupting the possibility of establishing a steady state. Fil:Allende, L. ...
author Allende, Luz
Izaguirre, Irina
author_facet Allende, Luz
Izaguirre, Irina
author_sort Allende, Luz
title The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
title_short The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
title_full The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
title_fullStr The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
title_full_unstemmed The role of physical stability on the establishment of steady states in the phytoplankton community of two Maritime Antarctic lakes
title_sort role of physical stability on the establishment of steady states in the phytoplankton community of two maritime antarctic lakes
publishDate 2003
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00188158_v502_n_p211_Allende
https://hdl.handle.net/20.500.12110/paper_00188158_v502_n_p211_Allende
long_lat ENVELOPE(-56.999,-56.999,-63.404,-63.404)
ENVELOPE(-56.999,-56.999,-63.404,-63.404)
ENVELOPE(-56.983,-56.983,-63.400,-63.400)
ENVELOPE(-56.996,-56.996,-63.395,-63.395)
ENVELOPE(-57.038,-57.038,-63.403,-63.403)
ENVELOPE(-57.000,-57.000,-63.400,-63.400)
ENVELOPE(-57.008,-57.008,-63.417,-63.417)
geographic Antarctic
Antarctic Peninsula
Boeckella
Boeckella Lake
Esperanza
Esperanza Station
Hope Bay
Lake Boeckella
Mount Flora
The Antarctic
West Antarctica
geographic_facet Antarctic
Antarctic Peninsula
Boeckella
Boeckella Lake
Esperanza
Esperanza Station
Hope Bay
Lake Boeckella
Mount Flora
The Antarctic
West Antarctica
genre Antarc*
Antarctic
Antarctic Peninsula
Antarctica
West Antarctica
genre_facet Antarc*
Antarctic
Antarctic Peninsula
Antarctica
West Antarctica
op_relation https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00188158_v502_n_p211_Allende
http://hdl.handle.net/20.500.12110/paper_00188158_v502_n_p211_Allende
op_doi https://doi.org/20.500.12110/paper_00188158_v502_n_p211_Allende
_version_ 1766255281480663040

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