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Sedimentation im europäischen Nordmeer : Organisation und Forschungsprogramm des Sonderforschungsbereiches 313 für den Zeitraum 1988 - 1990 (1988)

Thiede, Jörn [Hrsg.] ; Gerlach, Sebastian A. [Hrsg.] ; Altenbach, Alexander V. [Hrsg.]

Kiel : Sonderforschungsbereich 313

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Call number: ZSP-167-8

In: Berichte aus dem Sonderforschungsbereich 313 "Sedimentation im europäischen Nordmeer"

Type of Medium: Series available for loan

Pages: 211 S. : zahlr. graph. Darst., Kt.

Series Statement: Berichte aus dem Sonderforschungsbereich 313 "Sedimentation im europäischen Nordmeer" 8

Branch Library: AWI Library

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In memory of Bertil Swedmark (1975)

Gerlach, Sebastian A.

Springer

Marine biology 33 (1975), S. 279-280

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ISSN: 1432-1793

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00390565

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3

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A Bathynellid from the New World (1956)

GERLACH, SEBASTIAN A. ; SIEWING, ROLF

[s.l.] : Nature Publishing Group

Nature 177 (1956), S. 289-289

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ISSN: 1476-4687

Source: Nature Archives 1869 - 2009

Topics: Biology , Chemistry and Pharmacology , Medicine , Natural Sciences in General , Physics

Notes: [Auszug] A locality on the American continent can now be added. In 1954 S. Gerlach undertook a voyage to Brazil, assisted by a fellowship of Sao Paulo University and the Deutsche Forschungsgemeinschaft. On January 13, 1955, he discovered a bathynellid species at Icoaraci, about 17 km. north of Belem (Para), ...

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1038/177289a0

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Benthic-pelagic coupling in the Greenland-Norwegian Sea and its effect on the geological record (1995)

Graf, Gerhard ; Gerlach, Sebastian A. ; Linke, Peter ; [et al.]

Springer

International journal of earth sciences 84 (1995), S. 49-58

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ISSN: 1437-3262

Keywords: Benthic-pelagic coupling ; Greenland-Norwegian Sea ; Remineralization ; Bioturbation ; Sediment accumulation

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Notes: Abstract The sedimentation pattern of organic material in the Greenland-Norwegian Sea is reflected in the surface sediments, although less than 0.5% of the organic matter is buried in the sediment. Maximum fluxes and benthic responses are observed during June and/or August/September, following the pattern of export production in the pelagial zone. The annual remineralization rate on the Vøring Plateau is 3.0 g C m−2 a −1 Freshly settled phytodetritus, as detected by chlorophyll measurements, is rapidly mixed into the sediment and decomposed. It stimulates the activity of benthic organisms, especially foraminifera. The mixing coefficient for this material is D b=0.2 cm2 d−1, which is two to three orders of magnitude higher than that estimated from radiotracer methods. The effect on the geological record, however, is likely to be small. Chlorophyll-containing particles are at first very evenly distributed on the seafloor. After partial decomposition and resuspension, a secondary redistribution of particles occurs which can result in the formation of a high accumulation area, with an up to 80-fold increase in the sedimentation rate by lateral advection. This is mainly due to physical processes, because biodeposition mediated by benthic animals increases sedimentation by only a factor of two or three.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00192241

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Freilebende Nematoden als Nahrung der SandgarneleCrangon crangon (1969)

Gerlach, Sebastian A. ; Schrage, Marion

Springer

Oecologia 2 (1969), S. 362-375

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ISSN: 1432-1939

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Description / Table of Contents: Zusammenfassung Sandgarnelen (Crangon crangon) verschiedener Größenklassen konnten unter Laboratoriumsbedingungen mit freilebenden Nematoden als einzige Nahrung bis zu 210 Tagen am Leben erhalten werden. Für diese Experimente wurde der saprobe NematodePanagrellus redivivus benutzt, der etwa gleichgroß ist wie marine freilebende Nematoden (0,0003–0,0015 mg Trockengewicht), und der ebensogern wie diese von den Garnelen als Nahrung angenommen wird. Die Garnelen können bis zu 5 Nematoden pro Minute aus dem Lückensystem des Sandes herausfangen, doch halten sie dieses Tempo nur etwa 1/2 Std durch und legen nach der Erbeutung von etwa 300 Nematoden (0,2 mg Trockengewicht) eine Freßpause ein. Deshalb wird sehr viel weniger Nahrung aufgenommen als bei der Erbeutung von Makrofauna-Vertretern, denn ein 1,5 mg schweres Stück des PolychaetenLanice füllt den Magen. Die größte Nahrungsaufnahme bei Nematodenernährung war bei 20 mm langenCrangon nur 1,5 mg am Tag. Hierdurch wird verständlich, daß bei den Experimenten nur ein sehr geringer Zuwachs beobachtet wurde (1 mm in 25–74 Tagen) oder ein Wachstumsstillstand eintrat. Ohne Nahrung sterbenCrangon unter den Versuchsbedingungen in 27–47 Tagen ab. Auch wenn es sicher ist, daß insbesondere größere Garnelen nicht gut mit einer ausschließlichen Nematoden-Ernährung gedeihen können, so ist doch nicht von der Hand zu weisen, daß Meiofauna-Populationen in Ermangelung besserer NahrungsquellenCrangon auch in freier Natur vor dem Verhungern bewahren können.

Notes: Summary Under laboratory conditions,Crangon crangon of different size classes survived periods of up to 210 days if fed exclusively with free-living nematodes. Experiments were performed with the saprobic nematode speciesPanagrellus redivivus which is of similar size (0.0003–0.0015 mg dry weight) as marine freeliving species and which is in the same way accepted as food by the shrimps. The shrimps are able to catch nematodes out of a sandy substratum at a rate of 5 nematodes/min, but they do so for only about 30 minutes, stopping after ingesting approximately 0.2 mg dry weight of nematodes. Thus the food intake is much less than with macrofauna prey, e.g. with the polychaeteLanice of which a shrimp may ingest 1.5 mg at one sitting. 20 mm long specimens ofCrangon feeding on nematodes had a maximum food intake of 1.5 mg dry weight per day only which explains why growth was insignificant (1 mm in 25–74 days) or non-existent. Shrimps left without food died within 27–47 days. Even if these animals, especially the larger ones, could not prosper on an exclusive diet of nematodes, in the absence of better food natural meiofauna populations may preventCrangon crangon from starving to death.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00778992

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Food-chain relationships in subtidal silty sand marine sediments and the role of meiofauna in stimulating bacterial productivity (1978)

Gerlach, Sebastian A.

Springer

Oecologia 33 (1978), S. 55-69

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ISSN: 1432-1939

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary From bibliographic data the biomass correlations (organic dry weight) are constructed for the subsurface layer of a hypothetical 30 m deep silty sand station: 200 μg/ml macrofauna (including 120 μg/ml subsurface deposit feeders), 50 μg/ml meiofauna, 20 μg/ml Foraminifera, 1 μg/ml Ciliata and Flagellata, and 100 μg/ml bacteria. ATP-biomass is discussed. Meiofauna and Foraminifera contribute with 30 and 12% to the living biomass in the sediment, and it is assumed that their contribution to the food of deposit-feeding macrofauna is of a similar percentage. This is corroborated by productivity estimations. Bacteria are the main food of deposit feeding macrofauna, meiofauna, and microfauna. From different calculations it becomes evident that the productivity of bacteria in the sediment is far below figures achieved in experimental cultures: the conclusion is that sediment bacteria, in general, do not live under good environmental conditions. A rather large part of the bacterial population in the sediment seems to be in the stationary phase of life, and only a fraction of the total population exhibits high metabolic rates and rapid duplications. Only these active bacteria are of importance for the breakdown of relatively refractive organic matter in the sediment. In soft bottom marine sediments where the input of organic matter is higher than the remineralization rate, benthic animals stimulate by their activities and by nutrient cycling the decomposition of detritus via bacteria. Though meiofauna, in principle, feeds upon the same food resource as macrofauna, there is no real competition for food, because meiofaunal animals by their activities and by excreting metabolic end products induce a bacterial productivity which would not be there without them, and feed on it. There are a few examples where more specialized interactions exist between benthic animals and bacteria; these interactions have been termed “gardening”. They could be highly important in the benthic ecosystem.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00376996

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