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Cyclic Development of Sedimentary Basins. (2005)

Mabesoone, J. M.

San Diego :Elsevier Science & Technology,

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Keywords: Settling basins. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (530 pages)

Edition: 1st ed.

ISBN: 9780080461373

Series Statement: Issn Series ; v.Volume 57

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=270303

DDC: 552.5

Language: English

Note: COVER -- Cyclic Development of Sedimentary Basins -- Copyright Page -- Table of Contents -- Chapter 1. Long-term cyclicities: introduction -- 1.1 Types of long-term cycles -- 1.2 Early ideas -- 1.3 Further development -- 1.4 Current research -- Chapter 2. Causes of cyclicity -- 2.1 Introduction -- 2.2 Theses of system geotectonics -- 2.3 Stratigraphy and the galactic year -- 2.4 The geodynamic cycle and orogenic epochs -- 2.5 Geodynamic megacycles of evolution -- 2.6 Final remarks -- Chapter 3. Cyclicity in earth's geological evolution -- 3.1 Earth's history -- 3.2 Cyclicity in earth's processes -- 3.3 Tectonic-sedimentary episodes -- 3.4 Cyclic basin formation -- 3.5 Sedimentary fill -- 3.6 Metallogenic epochs -- 3.7 Final remarks -- Chapter 4. Examples of sedimentary basins of world -- 4.1 Introduction -- 4.2 Andes Fueginos -- 4.3 Andean foreland basins: Patagonia -- 4.4 Karoo Basin (South Africa) -- 4.5 Northwest and Central Europe -- 4.6 Ireland -- 4.7 Duero Basin (Spain) -- Chapter 5. The sedimentary record of foreland-basin, tectophase cycles: examples from the Appalachian Basin, USA -- 5.1 Introduction -- 5.2 Flexural rationale and stratigraphic manifestations -- 5.3 Appalachian basin foreland-basin cycles -- 5.4 Discussion and conclusions -- Chapter 6. Geological history of the Greater Amazonas Basin in Brazil -- 6.1 Introduction -- 6.2 Acre Basin -- 6.3 Solimoes Basin -- 6.4 Amazonas Basin -- 6.5 Amazon Mouth Basin -- 6.6 Integration of data and conclusions -- Chapter 7. Sedimentary basins of Brazilian Borborema and São Francisco tectonic provinces since Mesoproterozoic -- 7.1 Introduction -- 7.2 Tectonic history -- 7.3 Geology of São Francisco and Borborema provinces -- 7.4 Sedimentary basins -- 7.5 Basin evolution and sediment fill -- 7.6 Final remarks -- Chapter 8. Russian Arctic shelf sedimentary basins -- 8.1 Introduction. , 8.2 Barents-North Kara Basin -- 8.3 South Kara Basin -- 8.4 Laptev Sea Basin -- 8.5 Sedimentary basins of the East-Siberian and Chukchi Seas -- 8.6 Conclusions -- Acknowledgments -- Chapter 9. Cyclicity in the evolution of the Neogene North Croatian Basin (Pannonian Basin system) -- 9.1 Introduction -- 9.2 Deposition in the North Croatian Basin during the Neogene and cyclicity -- 9.3 Conclusions -- Chapter 10. Long-period cycles: a case study from the Arabian-Nubian craton -- 10.1 Introduction -- 10.2 Najd fault cycle -- 10.3 Nubian cycle I -- 10.4 Nubian cycle II -- 10.5 Hoggar emergent cycle -- 10.6 Nubian cycle III -- 10.7 Hercynian cycle -- 10.8 Jurhom cycle -- 10.9 Neotethys cycle -- 10.10 Arabian Plate cycle -- 10.11 Conclusions -- Acknowledgments -- Chapter 11. Cyclicity in Paleoproterozoic to Neoproterozoic Cuddapah Supergroup and its significance in basinal evolution -- 11.1 Introduction -- 11.2 Evolutionary trends of the Proterozoic basins -- 11.3 The Cuddapah Basin -- 11.4 Discussion -- Acknowledgments -- Chapter 12. Cyclicity of the Mesozoic sedimentation on the eastern margin of the Chinese craton as a response to the main geodynamic events in the adjacent active oceanic area -- 12.1 Introduction -- 12.2 Mesozoic sedimentation and geodynamic settings on the eastern margin of the Chinese craton -- 12.3 Triassic -- 12.4 Jurassic -- 12.5 Cretaceous -- 12.6 Mesozoic sedimentation and geodynamic settings in the tectonical passive and active areas -- 12.7 Conclusions -- Acknowledgments -- Chapter 13. Sedimentary basins of polycyclic development in the south-eastern part of the Siberian platform: Uchur-Maiskaya Basin and Vilyuiskaya Syneclise -- 13.1 Introduction -- 13.2 Geological structure of the sedimentary cover of the Uchur-Maiskaya basin -- 13.3 Vilyuiskaya Syneclise -- Chapter 14. Overview -- 14.1 Introduction -- 14.2 Andes Fueginos. , 14.3 Andes foreland: Patagonia -- 14.4 Greater Amazonas Basin -- 14.5 NE Brazilian Borborema and São Francisco provinces -- 14.6 Appalachian foreland basin -- 14.7 West Ireland -- 14.8 North-west and Central Europe -- 14.9 Duero Basin (Spain) -- 14.10 North Croatian Basin -- 14.11 Russian Arctic shelf basins -- 14.12 South-east Siberian platform -- 14.13 Eastern margin of Chinese craton -- 14.14 Proterozoic Cuddapah Basin (India) -- 14.15 Arabian-Nubian shield -- 14.16 Karoo Basin (South Africa) -- 14.17 Concluding remarks -- Chapter 15. Conclusions -- 15.1 Introduction -- 15.2 Causes of cyclicity -- 15.3 Cyclicity of earth's geological phenomena -- 15.4 Final remarks -- References -- Index.

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Benthos fauna in the North Sea from 2 surveys in 1986 and 1987

Frauenheim, Karin ; Neumann, V ; Thiel, Hjalmar ; [et al.]

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In: Supplement to: Frauenheim, Karin; Neumann, V; Thiel, Hjalmar; Türkay, Michael (1989): The distribution of the larger epifauna during summer and winter in the North Sea and its suitability for environmental monitoring. Senckenbergiana maritima, 20(3/4), 101-118, https://www.schweizerbart.de/publications/detail/artno/190702003

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Publication Date: 2023-05-12

Description: During two surveys in the North Sea, in summer 1986 and in winter 1987, larger epibenthos was collected with a 2 m beam trawl. The distributions of the species were checked for average linkage by means of the JACCARD-index cluster analysis. In summer two main clusters can be recognized. These are situated to the north and to the south of the Dogger Bank. In winter two main clusters may be recognized as well, but these clusters divide the North Sea into a western and an eastern part. We conclude, that these differences of epibenthos characteristics are correlated with seasonal changes in water body distributions.

Keywords: Circulation and Transfer of Pollutants in the North Sea; MULT; Multiple investigations; North Sea; Skagerrak; South Atlantic Ocean; VA44; VA44_1/00; VA44_100/00; VA44_101/00; VA44_103/00; VA44_105/00; VA44_108/00; VA44_109/00; VA44_11/00; VA44_110/00; VA44_111/00; VA44_119/00; VA44_12/00; VA44_120/00; VA44_121/00; VA44_123/00; VA44_125/00; VA44_14/00; VA44_2/00; VA44_20/00; VA44_21/00; VA44_22/00; VA44_23/00; VA44_24/00; VA44_25/00; VA44_26/00; VA44_27/00; VA44_28/00; VA44_29/00; VA44_3/00; VA44_30/00; VA44_31/00; VA44_34/00; VA44_35/00; VA44_36/00; VA44_37/00; VA44_38/00; VA44_39/00; VA44_4/00; VA44_40/00; VA44_41/00; VA44_43/00; VA44_47/00; VA44_48/00; VA44_49/00; VA44_5/00; VA44_50/00; VA44_52/00; VA44_53/00; VA44_54/00; VA44_55/00; VA44_56/00; VA44_57/00; VA44_58/00; VA44_59/00; VA44_6/00; VA44_60/00; VA44_61/00; VA44_64/00; VA44_65/00; VA44_66/00; VA44_67/00; VA44_68/00; VA44_69/00; VA44_70/00; VA44_71/00; VA44_72/00; VA44_73/00; VA44_74/00; VA44_75/00; VA44_76/00; VA44_77/00; VA44_78/00; VA44_79/00; VA44_8/00; VA44_81/00; VA44_82/00; VA44_83/00; VA44_84/00; VA44_85/00; VA44_86/00; VA44_88/00; VA44_89/00; VA44_90/00; VA44_91/00; VA44_92/00; VA44_93/00; VA44_94/00; VA44_95/00; VA44_96/00; VA44_97/00; VA44_98/00; VA44_99/00; VA53; VA53_102-1; VA53_103-1; VA53_104-1; VA53_105-1; VA53_107-1; VA53_108-1; VA53_109-1; VA53_1-1; VA53_110-1; VA53_111-1; VA53_112-1; VA53_113-1; VA53_114-1; VA53_115-1; VA53_116-1; VA53_120-1; VA53_122-1; VA53_123-1; VA53_124-1; VA53_126-1; VA53_127-1; VA53_128-1; VA53_129-1; VA53_130-1; VA53_133-1; VA53_134-1; VA53_137-1; VA53_138-1; VA53_140-1; VA53_145-1; VA53_146-1; VA53_147-1; VA53_16-1; VA53_17-1; VA53_2-1; VA53_21-1; VA53_23-1; VA53_24-1; VA53_25-1; VA53_26-1; VA53_27-1; VA53_28-1; VA53_29-1; VA53_30-1; VA53_3-1; VA53_31-1; VA53_32-1; VA53_33-1; VA53_34-1; VA53_35-1; VA53_36-1; VA53_37-1; VA53_39-1; VA53_40-1; VA53_4-1; VA53_42-1; VA53_43-1; VA53_45-1; VA53_46-1; VA53_47-1; VA53_48-1; VA53_49-1; VA53_50-1; VA53_5-1; VA53_51-1; VA53_52-1; VA53_55-1; VA53_56-1; VA53_57-1; VA53_58-1; VA53_59-1; VA53_60-1; VA53_6-1; VA53_62-1; VA53_63-1; VA53_64-1; VA53_65-1; VA53_66-1; VA53_67-1; VA53_68-1; VA53_69-1; VA53_70-1; VA53_71-1; VA53_72-1; VA53_73-1; VA53_74-1; VA53_75-1; VA53_76-1; VA53_77-1; VA53_78-1; VA53_79-1; VA53_80-1; VA53_8-1; VA53_81-1; VA53_82-1; VA53_83-1; VA53_84-1; VA53_85-1; VA53_86-1; VA53_87-1; VA53_88-1; VA53_89-1; VA53_90-1; VA53_9-1; VA53_91-1; VA53_92-1; VA53_93-1; VA53_94-1; VA53_95-1; VA53_96-1; VA53_97-1; VA53_98-1; VA53_99-1; Valdivia (1961); ZISCH

Type: Dataset

Format: application/zip, 2 datasets

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Benthos counted on dredged samples during Valdivia cruise VA44 (2009)

Frauenheim, Karin ; Neumann, V ; Thiel, Hjalmar ; [et al.]

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Publication Date: 2023-07-09

Keywords: Acanthocardia aculeata; Acanthocardia echinata; Acanthocardia tuberculata; Actiniaria sp.; Adamsia palliata; Adamsia sp.; Agonus cataphractus; Alcyonidium diaphanum; Alcyonidium digitatum; Alcyonium palmatum; Allorossia glaucopis; Allotheutis subulata; Ammodytes lanceolatum; Ammodytes marinus; Ammodytes sp.; Ammodytes tobianus; Amphipoda; Anapagurus laevis; Antedon bifida; Anthozoa; Anthozoa sp.; Aphrodite aculeata; Aplidium proliferum; Aplidium sp.; Aporrhais pespelecani; Aporrhais serresianus; Archidoris pseudoargus; Arctica islandica; Argentina silus; Argentina sphyraena; Arnoglossus laterna; Ascidia mentula; Ascidia sp.; Astacilla sp.; Astarte borealis; Astarte elliptica; Asterias muelleri; Asterias rubens; Asteriodea; Astropecten aurantiacus; Astropecten irregularis; Astropecten sp.; Atelecyclus rotundatus; Atherinidae sp.; Bathypolypus arcticus; Benthos, other; Berungius turtoni; Bivalvia; Bivalvia sp.; Bothidea sp.; Brissopsis lyrifera; Bryozoa; Bryozoa sp.; Buccinum sp.; Buccinum undatum; Buglossidium luteum; Callionymus lyra; Callionymus mascarenus; Callionymus phaeton; Callionymus reticulatus; Calliostoma zizyphinum; Calocarides coronatus; Calocarides macandracea; Cancer pagurus; Capulus hungaricus; Carcinus maenas; Cardium edule; Cardium sp.; Cephalopoda; Chimaera monstrosa; Chim re.; Chlamys nivea; Chlamys opercularis; Chlamys septemradiatus; Chlamys sp.; Chlamys striata; Chordata; Ciliata mustela; Ciliata septentrionalis; Ciona intestinalis; Circulation and Transfer of Pollutants in the North Sea; Clupea harengus; Clupea sp.; Colus gracilis; Colus islandicus; Colus sp.; Coryphaenoides rupestris; Corystes cassivelaunus; Corystes sp.; Counting dredged samples; Crangon allmanni; Crangon crangon; Crustacea; Cyprina islandica; Date/Time of event; Dentalium entalis; Dentalium sp.; DEPTH, sediment/rock; Dichelopandalus bonnieri; Diplopteraster multipes; Ebalia sp.; Echinocardium cordatum; Echinocardium flavescens; Echinocyamus pusillus; Echinus acutus; Echinus esculentus; Echiuridea; Echiurus; Echiurus echiurus; Echiurus sp.; Eledone cirrhosa; Elevation of event; Enchelyopus cimbrius; Ensis ensis; Ensis siliqua; Entelurus aequoreus; Epizoanthes sp.; Euphausiacea sp.; Eutrigla gurnardus; Event label; Flustra foliacea; Funiculina quadrangularis; Gadiculus argenteus thori; Gadidae sp.; Gadus morhua; Gaidropsarus mediterraneus; Galathea dispersa; Galathea nexa; Galthea sp.; Gasterosteus aculeatus; Gastropoda; Geryon tridens; Glyptocephalus cynoglossus; Gorgonocephalus caput-medusae; Halichondria panicea; Halichondria sp.; Hemichordata; Henricia oculata; Henricia sanguinolenta; Hippasteria phrygiana; Hippoglossoides platessoides; Hippoglossoides sp.; Holothuria; Holothuria sp.; Hyas araneus; Hyas coarctatus; Hyas sp.; Hydroidea sp.; Hydrozoa; Hyperoplus lanceolatus; Inachus dorsettensis; Inachus leptochirus; Inachus phalangium; Kophobelemnon stelliferum; Latitude of event; Lepadogaster bimaculatus; Lepidorhombus whiffiagonis; Limanda limanda; Liocarcinus depurator; Liocarcinus holsatus; Liocarcinus marmoreus; Liocarcinus puber; Liocarcinus pusillus; Liocarcinus sp.; Liparis liparis; Liparis montagui; Liparis vulgaris; Lithodes maja; Littorina sp.; Longitude of event; Lophius piscatorius; Luidia sarsi; Luidia sp.; Lumpenus lampretaeformis; Lunatia catena; Lunatia fusca; Lunatia sp.; Lundia tenuimana; Lycodes vahlii; Lyocodes esmarkii; Lysenchelys sarsi; Macropodia deflexa; Macropodia parva; Macropodia rostrata; Macropodia sp.; Macropodia tenuirostris; Mactra corallina; Mactra sp.; Melanogrammus aeglefinus; Merlangius merlangus; Merluccius merluccius; Metridium senile; Microstomus kitt; Modiolus modiolus; MULT; Multiple investigations; Munida rugosa; Munida sarsi; Munida sp.; Munida tenuimana; Mytilus edulis; Myxine glutinosa; Myxocephalus scorpius; Nassarius reticulatus; Natica catena; Natica sp.; Nephrops norvegicus; Neptunea antiqua; North Sea; Nucula nitida; Nudibranchia sp.; Nymphon gracile; Nymphon hirtum; Nymphon rubrum; Nymphon sp.; Ophiopholis aculeata; Ophiothrix fragilis; Ophiothrix sp.; Ophiura albida; Ophiura robusta; Ophiura sarsi; Ophiura sp.; Ophiura texturata; Ophiuridea; Pagurus bernhardus; Pagurus prideaux; Pagurus pubescens; Pagurus sp.; Pagurus variabilis; Pandalida sp.; Pandalus borealis; Pandalus montagui; Pandalus propinquus; Pantopoda; Parazoanthus sp.; Pasiphea multidentata; Pecten sp.; Pennatula phosphorea; Pennatularia sp.; Pholis gunnellus; Phrynorhombus norvegicus; Pilumnus hirtellus; Pisidia sp.; Platichthys flesus; Pleuronectes platessa; Polybius henslowii; Polychaeta; Polychaeta sp.; Pomatoschistus microps; Pomatoschistus minutus; Pomatoschistus pictus; Pomatoschistus sp.; Pontaster tenuispinus; Pontophilus norvegicus; Pontophilus sp.; Pontophilus spinosus; Porania pulvillus; Poraniomorpha hispida; Porifera; Porifera sp.; Portunus latipes; Portunus sp.; Processa sp.; Prosobranchia; Psammechinus miliaris; Pseudarchaster parelii; Psilaster andromeda; Psolus phantapus; Pycnogonum littorale; Raja batis; Raja clavata; Raja radiata; Raja sp.; Rhinonemus cimbrius; Sabinea sarsii; Scaphander lignarius; Scophthalmus rhombus; Scrobicularia plana; Scyllarus sp.; Sebastes viviparus; Securiflustra securifrons; Sepietta neglecta; Sepietta sp.; Sepiola atlantica; Sertularia cupressina; Sipunculus nudus; Skagerrak; Solaster endeca; Solaster papposus; Solea solea; South Atlantic Ocean; Spatangus purpureus; Spatangus raschi; Spirontocaris liljeborg; Spirorbis spirorbis; Spisula sp.; Sprattus sprattus; Stichastrella rosea; Strongylocentrotus droebachiensis; Stylatyla elegans; Syngnathus acus; Syngnathus rostellatus; Syngnathus sp.; Taurulus lilljeborgi; Tealia felina; Tealia sp.; Trachinus vipera; Trachiunus draco; Trigla lucerna; Trigla sp.; Triglops murrayi; Trisopterus esmarkii; Trisopterus luscus; Trisopterus minutus; Troschelia berniciensis; Turritella communis; VA44; VA44_1/00; VA44_100/00; VA44_101/00; VA44_103/00; VA44_105/00; VA44_108/00; VA44_109/00; VA44_11/00; VA44_110/00; VA44_111/00; VA44_119/00; VA44_12/00; VA44_120/00; VA44_121/00; VA44_123/00; VA44_125/00; VA44_14/00; VA44_2/00; VA44_20/00; VA44_21/00; VA44_22/00; VA44_23/00; VA44_24/00; VA44_25/00; VA44_26/00; VA44_27/00; VA44_28/00; VA44_29/00; VA44_3/00; VA44_30/00; VA44_31/00; VA44_34/00; VA44_35/00; VA44_36/00; VA44_37/00; VA44_38/00; VA44_39/00; VA44_4/00; VA44_40/00; VA44_41/00; VA44_43/00; VA44_47/00; VA44_48/00; VA44_49/00; VA44_5/00; VA44_50/00; VA44_52/00; VA44_53/00; VA44_54/00; VA44_55/00; VA44_56/00; VA44_57/00; VA44_58/00; VA44_59/00; VA44_6/00; VA44_60/00; VA44_61/00; VA44_64/00; VA44_65/00; VA44_66/00; VA44_67/00; VA44_68/00; VA44_69/00; VA44_70/00; VA44_71/00; VA44_72/00; VA44_73/00; VA44_74/00; VA44_75/00; VA44_76/00; VA44_77/00; VA44_78/00; VA44_79/00; VA44_8/00; VA44_81/00; VA44_82/00; VA44_83/00; VA44_84/00; VA44_85/00; VA44_86/00; VA44_88/00; VA44_89/00; VA44_90/00; VA44_91/00; VA44_92/00; VA44_93/00; VA44_94/00; VA44_95/00; VA44_96/00; VA44_97/00; VA44_98/00; VA44_99/00; Valdivia (1961); Velutina sp.; Velutina velutina; Venerupis sp.; Venus casina; Venus striatula; Venus verrucosa; ZISCH; Zoarces viviparus

Type: Dataset

Format: text/tab-separated-values, 29072 data points

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Benthos counted on dredged samples during Valdivia cruise VA53 (2009)

Frauenheim, Karin ; Neumann, V ; Thiel, Hjalmar ; [et al.]

PANGAEA

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Publication Date: 2023-07-09

Keywords: Acanthocardia aculeata; Acanthocardia echinata; Acanthocardia tuberculata; Actiniaria sp.; Adamsia palliata; Adamsia sp.; Agonus cataphractus; Alcyonidium diaphanum; Alcyonidium digitatum; Alcyonium palmatum; Allorossia glaucopis; Allotheutis subulata; Ammodytes lanceolatum; Ammodytes marinus; Ammodytes sp.; Ammodytes tobianus; Amphipoda; Anapagurus laevis; Antedon bifida; Anthozoa; Anthozoa sp.; Aphrodite aculeata; Aplidium proliferum; Aplidium sp.; Aporrhais pespelecani; Aporrhais serresianus; Archidoris pseudoargus; Arctica islandica; Argentina silus; Argentina sphyraena; Arnoglossus laterna; Ascidia mentula; Ascidia sp.; Astacilla sp.; Astarte borealis; Astarte elliptica; Asterias muelleri; Asterias rubens; Asteriodea; Astropecten aurantiacus; Astropecten irregularis; Astropecten sp.; Atelecyclus rotundatus; Atherinidae sp.; Bathypolypus arcticus; Benthos, other; Berungius turtoni; Bivalvia; Bivalvia sp.; Bothidea sp.; Brissopsis lyrifera; Bryozoa; Bryozoa sp.; Buccinum sp.; Buccinum undatum; Buglossidium luteum; Callionymus lyra; Callionymus mascarenus; Callionymus phaeton; Callionymus reticulatus; Calliostoma zizyphinum; Calocarides coronatus; Calocarides macandracea; Cancer pagurus; Capulus hungaricus; Carcinus maenas; Cardium edule; Cardium sp.; Cephalopoda; Chimaera monstrosa; Chim re.; Chlamys nivea; Chlamys opercularis; Chlamys septemradiatus; Chlamys sp.; Chlamys striata; Chordata; Ciliata mustela; Ciliata septentrionalis; Ciona intestinalis; Circulation and Transfer of Pollutants in the North Sea; Clupea harengus; Clupea sp.; Colus gracilis; Colus islandicus; Colus sp.; Coryphaenoides rupestris; Corystes cassivelaunus; Corystes sp.; Counting dredged samples; Crangon allmanni; Crangon crangon; Crustacea; Cyprina islandica; Date/Time of event; Dentalium entalis; Dentalium sp.; DEPTH, sediment/rock; Dichelopandalus bonnieri; Diplopteraster multipes; Ebalia sp.; Echinocardium cordatum; Echinocardium flavescens; Echinocyamus pusillus; Echinus acutus; Echinus esculentus; Echiuridea; Echiurus; Echiurus echiurus; Echiurus sp.; Eledone cirrhosa; Elevation of event; Enchelyopus cimbrius; Ensis ensis; Ensis siliqua; Entelurus aequoreus; Epizoanthes sp.; Euphausiacea sp.; Eutrigla gurnardus; Event label; Flustra foliacea; Funiculina quadrangularis; Gadiculus argenteus thori; Gadidae sp.; Gadus morhua; Gaidropsarus mediterraneus; Galathea dispersa; Galathea nexa; Galthea sp.; Gasterosteus aculeatus; Gastropoda; Geryon tridens; Glyptocephalus cynoglossus; Gorgonocephalus caput-medusae; Halichondria panicea; Halichondria sp.; Hemichordata; Henricia oculata; Henricia sanguinolenta; Hippasteria phrygiana; Hippoglossoides platessoides; Hippoglossoides sp.; Holothuria; Holothuria sp.; Hyas araneus; Hyas coarctatus; Hyas sp.; Hydroidea sp.; Hydrozoa; Hyperoplus lanceolatus; Inachus dorsettensis; Inachus leptochirus; Inachus phalangium; Kophobelemnon stelliferum; Latitude of event; Lepadogaster bimaculatus; Lepidorhombus whiffiagonis; Limanda limanda; Liocarcinus depurator; Liocarcinus holsatus; Liocarcinus marmoreus; Liocarcinus puber; Liocarcinus pusillus; Liocarcinus sp.; Liparis liparis; Liparis montagui; Liparis vulgaris; Lithodes maja; Littorina sp.; Longitude of event; Lophius piscatorius; Luidia sarsi; Luidia sp.; Lumpenus lampretaeformis; Lunatia catena; Lunatia fusca; Lunatia sp.; Lundia tenuimana; Lycodes vahlii; Lyocodes esmarkii; Lysenchelys sarsi; Macropodia deflexa; Macropodia parva; Macropodia rostrata; Macropodia sp.; Macropodia tenuirostris; Mactra corallina; Mactra sp.; Melanogrammus aeglefinus; Merlangius merlangus; Merluccius merluccius; Metridium senile; Microstomus kitt; Modiolus modiolus; MULT; Multiple investigations; Munida rugosa; Munida sarsi; Munida sp.; Munida tenuimana; Mytilus edulis; Myxine glutinosa; Myxocephalus scorpius; Nassarius reticulatus; Natica catena; Natica sp.; Nephrops norvegicus; Neptunea antiqua; North Sea; Nucula nitida; Nudibranchia sp.; Nymphon gracile; Nymphon hirtum; Nymphon rubrum; Nymphon sp.; Ophiopholis aculeata; Ophiothrix fragilis; Ophiothrix sp.; Ophiura albida; Ophiura robusta; Ophiura sarsi; Ophiura sp.; Ophiura texturata; Ophiuridea; Pagurus bernhardus; Pagurus prideaux; Pagurus pubescens; Pagurus sp.; Pagurus variabilis; Pandalida sp.; Pandalus borealis; Pandalus montagui; Pandalus propinquus; Pantopoda; Parazoanthus sp.; Pasiphea multidentata; Pecten sp.; Pennatula phosphorea; Pennatularia sp.; Pholis gunnellus; Phrynorhombus norvegicus; Pilumnus hirtellus; Pisidia sp.; Platichthys flesus; Pleuronectes platessa; Polybius henslowii; Polychaeta; Polychaeta sp.; Pomatoschistus microps; Pomatoschistus minutus; Pomatoschistus pictus; Pomatoschistus sp.; Pontaster tenuispinus; Pontophilus norvegicus; Pontophilus sp.; Pontophilus spinosus; Porania pulvillus; Poraniomorpha hispida; Porifera; Porifera sp.; Portunus latipes; Portunus sp.; Processa sp.; Prosobranchia; Psammechinus miliaris; Pseudarchaster parelii; Psilaster andromeda; Psolus phantapus; Pycnogonum littorale; Raja batis; Raja clavata; Raja radiata; Raja sp.; Rhinonemus cimbrius; Sabinea sarsii; Scaphander lignarius; Scophthalmus rhombus; Scrobicularia plana; Scyllarus sp.; Sebastes viviparus; Securiflustra securifrons; Sepietta neglecta; Sepietta sp.; Sepiola atlantica; Sertularia cupressina; Sipunculus nudus; Skagerrak; Solaster endeca; Solaster papposus; Solea solea; South Atlantic Ocean; Spatangus purpureus; Spatangus raschi; Spirontocaris liljeborg; Spirorbis spirorbis; Spisula sp.; Sprattus sprattus; Stichastrella rosea; Strongylocentrotus droebachiensis; Stylatyla elegans; Syngnathus acus; Syngnathus rostellatus; Syngnathus sp.; Taurulus lilljeborgi; Tealia felina; Tealia sp.; Trachinus vipera; Trachiunus draco; Trigla lucerna; Trigla sp.; Triglops murrayi; Trisopterus esmarkii; Trisopterus luscus; Trisopterus minutus; Troschelia berniciensis; Turritella communis; VA53; VA53_102-1; VA53_103-1; VA53_104-1; VA53_105-1; VA53_107-1; VA53_108-1; VA53_109-1; VA53_1-1; VA53_110-1; VA53_111-1; VA53_112-1; VA53_113-1; VA53_114-1; VA53_115-1; VA53_116-1; VA53_120-1; VA53_122-1; VA53_123-1; VA53_124-1; VA53_126-1; VA53_127-1; VA53_128-1; VA53_129-1; VA53_130-1; VA53_133-1; VA53_134-1; VA53_137-1; VA53_138-1; VA53_140-1; VA53_145-1; VA53_146-1; VA53_147-1; VA53_16-1; VA53_17-1; VA53_2-1; VA53_21-1; VA53_23-1; VA53_24-1; VA53_25-1; VA53_26-1; VA53_27-1; VA53_28-1; VA53_29-1; VA53_30-1; VA53_3-1; VA53_31-1; VA53_32-1; VA53_33-1; VA53_34-1; VA53_35-1; VA53_36-1; VA53_37-1; VA53_39-1; VA53_40-1; VA53_4-1; VA53_42-1; VA53_43-1; VA53_45-1; VA53_46-1; VA53_47-1; VA53_48-1; VA53_49-1; VA53_50-1; VA53_5-1; VA53_51-1; VA53_52-1; VA53_55-1; VA53_56-1; VA53_57-1; VA53_58-1; VA53_59-1; VA53_60-1; VA53_6-1; VA53_62-1; VA53_63-1; VA53_64-1; VA53_65-1; VA53_66-1; VA53_67-1; VA53_68-1; VA53_69-1; VA53_70-1; VA53_71-1; VA53_72-1; VA53_73-1; VA53_74-1; VA53_75-1; VA53_76-1; VA53_77-1; VA53_78-1; VA53_79-1; VA53_80-1; VA53_8-1; VA53_81-1; VA53_82-1; VA53_83-1; VA53_84-1; VA53_85-1; VA53_86-1; VA53_87-1; VA53_88-1; VA53_89-1; VA53_90-1; VA53_9-1; VA53_91-1; VA53_92-1; VA53_93-1; VA53_94-1; VA53_95-1; VA53_96-1; VA53_97-1; VA53_98-1; VA53_99-1; Valdivia (1961); Velutina sp.; Velutina velutina; Venerupis sp.; Venus casina; Venus striatula; Venus verrucosa; ZISCH; Zoarces viviparus

Type: Dataset

Format: text/tab-separated-values, 35708 data points

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DATA PANGAEA

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5

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High frequency, inductively coupled plasma torch for pure and doped silica deposition

Berthou, H. ; Neumann, V. ; Hintermann, H.E.

Amsterdam : Elsevier

Surface & Coatings Technology 61 (1993), S. 164-170

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ISSN: 0257-8972

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Physics

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0257-8972(93)90220-I

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Mechanically enhanced capillary columns

Berthou, H. ; Neumann, V. ; Dan, J.P. ; [et al.]

Amsterdam : Elsevier

Surface & Coatings Technology 61 (1993), S. 93-96

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ISSN: 0257-8972

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics , Physics

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0257-8972(93)90208-6

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Clozapine inhibits catalepsy induced by olanzapine and loxapine, but prolongs catalepsy induced by SCH 23390 in rats (1997)

Kalkman, H. O. ; Neumann, V. ; Tricklebank, M. D.

Springer

Naunyn-Schmiedeberg's archives of pharmacology 355 (1997), S. 361-364

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ISSN: 1432-1912

Keywords: Key words Clozapine ; Olanzapine ; Loxapine ; SCH 23390 ; Catalepsy

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Loxapine (0.3mg/kg s.c.), olanzapine (10 mg/ kg s.c.) and SCH 23390 (R-(+)-chloro-2, 3, 4, 5-tetrahydro-3-methyl-5-phenyl-1-H-3-benzazepine; 1mg/kg, s.c.), but not clozapine (10mg/kg, s.c.), induced catalepsy in rats. Co-administration of clozapine (1, 3 and 10mg/ kg s.c.) dose-dependently inhibited loxapine-induced catalepsy. Clozapine (10mg/kg s.c.) also prevented the induction of catalepsy by olanzapine. In addition, clozapine abolished the catalepsy induced by loxapine when it was administered after the response had fully developed. In contrast, the duration of SCH 23390-induced catalepsy was prolonged by clozapine, indicating that its anti-catalepsy effects against olanzapine and loxapine are unlikely to be caused by muscle relaxation, sedation or stimulation. Since SCH 23390-induced catalepsy is reported to be blocked by scopolamine, dizocilpine (MK-801) or 8-hydroxy-dipropylamino-tetralin, it is unlikely that muscarinic blockade, NMDA ion channel blockade and 5-HT1A receptor agonism, respectively, are involved in clozapine’s action, but the mechanism by which clozapine exerts this anti-cataleptic effect remains unknown.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/PL00004955

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Peritoneale Mesotheliome – Häufigkeiten und Ätiologie (1999)

Neumann, V. ; Müller, K.-M. ; Fischer, M.

Springer

Der Pathologe 20 (1999), S. 169-176

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ISSN: 1432-1963

Keywords: Schlüsselwörter Peritoneale Mesotheliome ; Wachstumsmuster ; Überlebenszeiten ; Asbestbelastung ; Asbestexpositionen ; Key words Peritoneal mesotheliomas ; Subtype ; Survival time ; Asbestos burden ; Asbestos exposure

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Description / Table of Contents: Summary A total of 70 malignant and 4 benign peritoneal mesotheliomas were diagnosed by the German Mesothelioma Registry between 1992 and 1998. Malignant mesotheliomas developed mainly in men (55/70); only one man had a benign peritoneal alteration. Age at first diagnosis of malignant mesotheliomas is about 59 years; the women are on average 4 years younger than the men. Mean survival time ranges about 1 year; in 6 of 38 patients longer survival times of up to 7 years are known. The epitheloid subtype predominates, but no effect on survival time is noticed. The percentage of patients with combined asbestos-associated lung fibrosis is higher than that for pleural mesotheliomas; these patients become ill about 6.5 years earlier. The latency period is 36 years on average. For most patients asbestos exposure is related to their occupation mainly in metal industries, asbestos industries, and in the building trade. There is no evidence for an induction of benign peritoneal alterations by asbestos dust.

Notes: Zusammenfassung Zwischen 1992 und 1998 wurden im Deutschen Mesotheliomregister 70 peritoneale maligne und 4 benigne Mesotheliome pathologisch-anatomisch diagnostiziert. Die malignen Mesotheliome sind überwiegend (55/70) bei Männern entwickelt, bei den benignen Veränderungen ist nur ein Mann betroffen. Das Erkrankungsalter der Patienten mit malignen Mesotheliomen liegt im Mittel bei 59 Jahren, Frauen sind zum Zeitpunkt der Diagnose 4 Jahre jünger als Männer. Die mittlere Überlebensrate beträgt ca. 1 Jahr, bei 6/38 Patienten sind längere Überlebenszeiten bis zu 7 Jahren bekannt. Der epitheloide Wachstumstyp überwiegt, ein Einfluß auf die Überlebenszeit ist nicht zu belegen. Es findet sich ein deutlich höherer Anteil mit Minimalasbestosen/Asbestosen als in Fällen mit Pleuramesotheliomen, diese Patienten erkranken etwa 6,5 Jahre eher. Für den überwiegenden Teil der Patienten ist eine erhöhte Exposition bekannt. Die meisten Patienten waren in der Metallindustrie, in der Asbestindustrie und im Baugewerbe tätig. Die Latenzzeit liegt im Mittel bei 36 Jahren. Die Induktion benigner peritonealer Veränderungen durch z.B. Asbeststaub ist wissenschaftlich nicht belegt.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002920050340

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Electrically induced fusion of different human cell types (1986)

Neumann, V. ; Siegemund, F. ; Baeßler, B.

Springer

Journal of neurology 233 (1986), S. 153-156

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ISSN: 1432-1459

Keywords: Dielectrophoresis ; Charge pulse fusion ; Human cell types ; CSF cells

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The fusion of human cells of the cerebrospinal fluid and of the peripheral blood is reported, as well as the fusion of these cells with tomato protoplasts. The cells were fused by applying short-time electric pulses after dielectrophoretic collection. The importance of this method for diagnosis and therapy is discussed and possible applications are mentioned.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00314422

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Zur Trennung und zum Nachweis der bei der Äthanolyse von Lignin (1955)

Neumann, V.

Springer

Fresenius' Zeitschrift für analytische Chemie 147 (1955), S. 391-392

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ISSN: 1618-2650

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00432959

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