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POLAR NIGHT Marine Ecology : Life and Light in the Dead of Night (2020)

Berge, Jørgen. [editor.] ; Johnsen, Geir. [editor.] ; Cohen, Jonathan H. [editor.]

Cham :Springer International Publishing :

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Keywords: Biotic communities. ; Biodiversity. ; Freshwater ecology. ; Marine ecology. ; Climatology. ; Physical geography. ; Botanical chemistry. ; Ecosystems. ; Biodiversity. ; Freshwater and Marine Ecology. ; Climate Sciences. ; Physical Geography. ; Plant Biochemistry.

Description / Table of Contents: Preface -- The marine physical environment during the Polar Night -- Light in the Polar Night -- Marine micro- and macroalgae in the Polar Night -- Zooplankton in the Polar Night -- Benthic communities in the Polar Night -- Fish ecology in the Polar Night -- Biological clocks and rhythms in polar organisms -- Sensor carrying platforms -- Operative habitat mapping and monitoring in the Polar Night -- The Polar Night exhibition: Life and light at the dead of night -- Index.

Abstract: Until recently, the prevailing view of marine life at high latitudes has been that organisms enter a general resting state during the dark Polar Night and that the system only awakens with the return of the sun. Recent research, however, with coordinated, multidisciplinary field campaigns based on the high Arctic Archipelago of Svalbard, have provided a radical new perspective. Instead of a system in dormancy, a new perspective of a system in full operation and with high levels of activity across all major phyla is emerging. Examples of such activities and processes include: Active marine organisms at sea surface, water column and the sea-floor. At surface we find active foraging in seabirds and fish, in the water column we find a high biodiversity and activity of zooplankton and larvae such as active light induced synchronized diurnal vertical migration, and at seafloor there is a high biodiversity in benthic animals and macroalgae. The Polar Night is a period for reproduction in many benthic and pelagic taxa, mass occurrence of ghost shrimps (Caprellides), high abundance of Ctenophores, physiological evidence of micro- and macroalgal cells that are ready to utilize the first rays of light when they appear, deep water fishes found at water surface in the Polar night, and continuous growth of bivalves throughout the winter. These findings not only begin to shape a new paradigm for marine winter ecology in the high Arctic, but also provide conclusive evidence for a top-down controlled system in which primary production levels are close to zero. In an era of environmental change that is accelerated at high latitudes, we believe that this new insight is likely to strongly impact how the scientific community views the high latitude marine ecosystem. Despite the overwhelming darkness, the main environmental variable affecting marine organisms in the Polar Night is in fact light. The light regime during the Polar Night is unique with respect to light intensity, spectral composition of light and photoperiod. .

Type of Medium: Online Resource

Pages: XI, 375 p. 133 illus., 116 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9783030332082

Series Statement: Advances in Polar Ecology, 4

URL: https://doi.org/10.1007/978-3-030-33208-2

DOI: 10.1007/978-3-030-33208-2

DDC: 577

Language: English

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Polar night marine ecology : life and light in the dead of night (2020)

Berge, Jørgen [HerausgeberIn] ; Johnsen, Geir [HerausgeberIn] ; Cohen, Jonathan H. [HerausgeberIn]

Cham : Springer

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Call number: 9783030332082 (e-book)

Description / Table of Contents: Until recently, the prevailing view of marine life at high latitudes has been that organisms enter a general resting state during the dark Polar Night and that the system only awakens with the return of the sun. Recent research, however, with coordinated, multidisciplinary field campaigns based on the high Arctic Archipelago of Svalbard, have provided a radical new perspective. Instead of a system in dormancy, a new perspective of a system in full operation and with high levels of activity across all major phyla is emerging. Examples of such activities and processes include: Active marine organisms at sea surface, water column and the sea-floor. At surface we find active foraging in seabirds and fish, in the water column we find a high biodiversity and activity of zooplankton and larvae such as active light induced synchronized diurnal vertical migration, and at seafloor there is a high biodiversity in benthic animals and macroalgae. The Polar Night is a period for reproduction in many benthic and pelagic taxa, mass occurrence of ghost shrimps (Caprellides), high abundance of Ctenophores, physiological evidence of micro- and macroalgal cells that are ready to utilize the first rays of light when they appear, deep water fishes found at water surface in the Polar night, and continuous growth of bivalves throughout the winter. These findings not only begin to shape a new paradigm for marine winter ecology in the high Arctic, but also provide conclusive evidence for a top-down controlled system in which primary production levels are close to zero. In an era of environmental change that is accelerated at high latitudes, we believe that this new insight is likely to strongly impact how the scientific community views the high latitude marine ecosystem. Despite the overwhelming darkness, the main environmental variable affecting marine organisms in the Polar Night is in fact light. The light regime during the Polar Night is unique with respect to light intensity, spectral composition of light and photoperiod. .

Type of Medium: 12

Pages: 1 Online-Ressource (XI, 375 Seiten) , Illustrationen, Diagramme, Karten (farbig)

ISBN: 9783030332082 , 978-3-030-33208-2

ISSN: 2468-5720 , 2468-5712

Series Statement: Advances in polar ecology volume 4

URL: https://doi.org/10.1007/978-3-030-33208-2

Language: English

Note: Contents 1 Introduction / Jørgen Berge, Geir Johnsen, and Jonathan H. Cohen 2 The Marine Physical Environment During the Polar Night / Finlo Cottier and Marie Porter 3 Light in the Polar Night / Jonathan H. Cohen, Jørgen Berge, Mark A. Moline, Geir Johnsen, and Artur P. Zolich 4 Marine Micro- and Macroalgae in the Polar Night / Geir Johnsen, Eva Leu, and Rolf Gradinger 5 Zooplankton in the Polar Night / Jørgen Berge, Malin Daase, Laura Hobbs, Stig Falk-Petersen, Gerald Darnis, and Janne E. Søreide 6 Benthic Communities in the Polar Night / Paul E. Renaud, William G. Ambrose Jr., and Jan Marcin Węsławski 7 Fish Ecology During the Polar Night / Maxime Geoffroy and Pierre Priou 8 Biological Clocks and Rhythms in Polar Organisms / Kim S. Last, N. Sören Häfker, Vicki J. Hendrick, Bettina Meyer, Damien Tran, and Fabio Piccolin 9 Sensor-Carrying Platforms / Asgeir J. Sørensen, Martin Ludvigsen, Petter Norgren, Øyvind Ødegård, and Finlo Cottier 10 Operative Habitat Mapping and Monitoring in the Polar Night / Geir Johnsen, Aksel A. Mogstad, Jørgen Berge, and Jonathan H. Cohen 11 Life and Light at the Dead of Night / Jørgen Berge and Geir Johnsen Index

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The influence of predation on horizontal distribution of zooplankton species (1987)

JAKOBSEN, PER JOHAN ; JOHNSEN, GEIR HELGE

Oxford, UK : Blackwell Publishing Ltd

Freshwater biology 17 (1987), S. 0

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ISSN: 1365-2427

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Biology

Notes: SUMMARY. 1. The horizontal distributions of Daphnia longispina and Bosmina tongispina in Lake Kvernavatn (Norway) were investigated twice in 1982. In late spring, when populations were small, the two species inhabited the same areas, and they were evenly distributed from the littoral to the pelagic. At high population densities, during midsummer, the species were spatially segregated, D. longispina being pelagic and B. longispina littoral in distribution.2. The distribution and feeding of three-spined sticklebacks (Gasteros-teus aculeatus) were also studied. The sticklebacks were apparently forced into littoral areas by larger piscivorous predators in the pelagic and they were consequently restricted to foraging primarily on B. longispina, which formed dense swarms during daytime in summer.3. We suggest that predation and competition influence the spatial distribution of zooplankton species. The feeding efficiency of fish foraging on high-density zooplankton populations can be reduced by spatial segregation of zooplankton species. Where high local densities occur, due to swarm formation, predation is changed from size-selective feeding to consumption of spatially isolated individuals.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-2427.1987.tb01070.x

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Egg age distribution, the direct way to cladoceran birth rates (1983)

Johnsen, Geir

Springer

Oecologia 60 (1983), S. 234-236

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ISSN: 1432-1939

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Cladoceran hatching frequency can easily be calculated from observed egg age distribution and estimated egg development time. The large timelag errors of models incorporating birth rates in the equation are avoided, and the population growth rate can be estimated directly.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00379525

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Photoadaptation of sea-ice microalgae in the Barents Sea (1991)

Johnsen, Geir ; Hegseth, Else Nøst

Springer

Polar biology 11 (1991), S. 179-184

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ISSN: 1432-2056

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary Variations in under-ice scalar irradiance, P vs I parameters and the CHLa C−1 ratio of natural assemblages of sea-ice microalgae from the Barents Sea growing at -1.8°C in May and September 1988 are described, including one diurnal station. CHLa C−1 ratios of 0.031–0.071 mg mg−1 indicate shade adaptated assemblages both in May and September. Values for αB (photosynthetic efficiency) were generally low, e.g. 0.0025–0.0078 mg C (mg CHLa)−1 h−1 (μmol m−2 s−1)−1, and should be typical for self-shaded algae in mats or aggregates of about 4 mm thickness. Provided no self shading and the typical spectral distribution of light under ice without algae, αB would, however, be about 2.5 times higher. Photoinhibition of the photosynthetic response was negligible. Maximum carbon uptake P m B was 0.15–0.24 and 0.032–0.088 mg C (mg CHLa)−1 h−1 in May and September, respectively. Diurnal variations were small, particularly for P m B . Calculations of the maximum specific gross growth rate yielded an upper limit of 0.20–0.24 and 0.01–0.04 d−1 for assemblages in May and September, respectively; the latter may have been in a resting stage.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00240206

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Isolation of membrane bound light-harvesting-complexes from the dinoflagellates Heterocapsa pygmaea and Prorocentrum minimum (1995)

Jovine, Raffael V. M. ; Johnsen, Geir ; Prézelin, Barbara B.

Springer

Photosynthesis research 44 (1995), S. 127-138

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ISSN: 1573-5079

Keywords: diadinoxanthin ; dinoflagellate ; light-harvesting-complex ; peridinin ; photoacclimation ; photosynthesis

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract We have isolated Chl a-Chl c-carotenoid binding proteins from the dinoflagellates Prorocentrum minimum and Heterocapsa pygmaea grown under high (500 μmol m−2 s−1, HL) and low (35 μmol m−2 s−1, LL) light conditions. We compared various isolation procedures of membrane bound light harvesting complexes (LHCs) and assayed the functionality of the solubilized proteins by determining the energy transfer efficiency from the accessory pigments to Chl a by means of fluorescence excitation spectra. The identity of the newly isolated protein-complexes were confirmed by immunological cross-reactions with antibodies raised against the previously described membrane bound Chl a-c proteins (Boczar et al. (1980) FEBS Lett 120: 243–247). Spectroscopic analysis demonstrated the relatedness of these proteins with the recently described Chl-a-c 2-peridinin (ACP) binding protein (Hiller et al. (1993) Photochem Photobiol 57: 125–131; Iglesias Prieto et al. (1993) Phil Trans R Soc London B 338: 381–392). The water-soluble peridinin-Chl a binding-protein (PCP) was not detectable in P. minimum. Two functional forms of ACP with different pigmentation were isolated. A variant of ACP which was isolated from high-light grown cells, that specifically binds increased amounts of diadinoxanthin was compared to the previously described ACPs that bind proportionately more peridinin.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00018303

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