Oldest Atlantic seafloor

Basalt recovered beneath Jurassic sediments in the western Atlantic at Deep Sea Drilling Project sites 100 and 105 of leg 11 has petrographic features characteristic of water-quenched basalt extruded along modern ocean ridges. Site 100 basalt appears to represent two or three massive cooling units, and an extrusive emplacement is probable. Site 105 basalt is less altered and appears to be a compositionally homogeneous pillow lava sequence related to a single eruptive episode.Although the leg 11 basalts are much more closely related in time to the Triassic lavas and intrusives of eastern continental North America, their geochemical features are closely comparable to those of modern Mid-Atlantic Ridge basalts unrelated to postulated mantle plume activity. Projection of leg 11 sites back along accepted spreading flow lines to their presumed points of origin shows that these origins are also outside the influence of modern plume activity. Thus, these oldest Atlantic seafloor basalts provide no information on the time of initiation of these plumes. The Triassic continental diabases show north to south compositional variations in Rb, Ba, La, and Sr which lie within the range of plume-related basalt on the Mid-Atlantic Ridge (20 °–40 °N). This suggests that these diabases had mantle sources similar in composition to those beneath the present Mid-Atlantic Ridge. Plumes related to deep mantle sources may have contributed to the LIL-element enrichment in the Triassic diabase and may alos have been instrumental in initiating the rifting of the North Atlantic. Systematically high values for K and Sr⁸⁷/Sr⁸⁶ in the Triassic diabases may reflect superimposed effects of crustal contamination in the Triassic magmas.Contribution Number 3953 from the Woods Hole Oceanographic Institution     

Variations in temperature and extent of Atlantic Water in the northern North Atlantic during the Holocene

We compare six high-resolution Holocene, sediment cores along a S–N transect on the Norwegian–Svalbard continental margin from ca 60°N to 77.4°N, northern North Atlantic. Planktonic foraminifera in the cores were investigated to show the changes in upper surface and subsurface water mass distribution and properties, including summer sea-surface temperatures (SST). The cores are located below the axis of the Norwegian Current and the West Spitsbergen Current, which today transport warm Atlantic Water to the Arctic. Sediment accumulation rates are generally high at all the core sites, allowing for a temporal resolution of 10–10² years. SST is reconstructed using different types of transfer functions, resulting in very similar SST trends, with deviations of no more than ±1.0/1.5 °C. A transfer function based on the maximum likelihood statistical approach is found to be most relevant. The reconstruction documents an abrupt change in planktonic foraminiferal faunal composition and an associated warming at the Younger Dryas–Preboreal transition. The earliest part of the Holocene was characterized by large temperature variability, including the Preboreal Oscillations and the 8.2 k event. In general, the early Holocene was characterized by SSTs similar to those of today in the south and warmer than today in the north, and a smaller S–N temperature gradient (0.23 °C/°N) compared to the present temperature gradient (0.46 °C/°N). The southern proxy records (60–69°N) were more strongly influenced by slightly cooler subsurface water probably due to the seasonality of the orbital forcing and increased stratification due to freshening. The northern records (72–77.4°N) display a millennial-scale change associated with reduced insolation and a gradual weakening of the North Atlantic thermohaline circulation (THC). The observed northwards amplification of the early Holocene warming is comparable to the pattern of recent global warming and future climate modelling, which predicts greater warming at higher latitudes. The overall trend during mid and late Holocene was a cooling in the north, stable or weak warming in the south, and a maximum S–N SST gradient of ca 0.7 °C/°N at 5000 cal. years BP. Superimposed on this trend were several abrupt temperature shifts. Four of these shifts, dated to 9000–8000, 5500–3000 and 1000 and 400 cal. years BP, appear to be global, as they correlate with periods of global climate change. In general, there is a good correlation between the northern North Atlantic temperature records and climate records from Norway and Svalbard.     

Time and space distribution of megaripples and associated bedforms, Middle Atlantic Bight, North American Atlantic Shelf

Three genetically distinct size classes of lower regime transverse bedforms have long been known from laboratory studies, and from studies of the intertidal zone; ripples, megaripples, and sand waves. These features are also present on the subtidal shelf surface of the Middle Atlantic Bight, and their distribution in time and space allows us to draw inferences concerning the time and space pattern of sediment transport. Transverse bedforms in the Middle Atlantic Bight occur in response to tidal flows at estuary and inlet mouths and on tide-dominated banks; on the shelf surface, however, they are primarily responses to wind-driven flows. Ripples are the most widespread of the three classes. They are current-formed during peak storm flows, but are probably remade as oscillatory wave ripples as the flow wanes. Megaripples are found primarily on the inner shelf, also as responses to peak storm flows. Sand waves of several metres amplitude occur on the inner shelf in the vicinity of topographic highs; low amplitude sand waves (< 2m), solitary or in trains, are widespread on the inner shelf. They survive through many seasons of storm flows. Megaripples are especially interesting as records of specific flow events. They are widespread on the inner shelf during the winter, occurring in fields up to several kilometres in diameter. On a portion of the Long Island inner shelf during December 1976, megaripple fields covered approximately 15% of the shelf surface. They tend to be erased during the succeeding summer months. Both megaripples (short-term response elements) and sand waves (long-term response elements) indicate that sand transport in the Middle Atlantic Bight is directed to the southeast, parallel with the regional trend of the isobaths.     

Asymmetric Atlantic continental margins

We analyze the gross crustal structure of the Atlantic Ocean passive continental margins from north to the south, comparing eleven sections of the conjugate margins. As a general result, the western margins show a sharper continental-ocean transition with respect to the eastern margins that rather show a wider stretched and thinner margin. The Moho is in average about 5.7°±1° dipping toward the interior of the continent on the western side, whereas it is about 2.7°±1° in the eastern margins. Moreover, the stretched continental crust is on average 244 km wide on the western side, whereas it is up to about 439 km on the eastern side of the Atlantic. This systematic asymmetry reflects the early stages of the diachronous Mesozoic to Cenozoic continental rifting, which is inferred as the result of a polarized westward motion of both western and eastern plates, being Greenland, Northern and Southern Americas plates moving westward faster with respect to Scandinavia, Europe and Africa, relative to the underlying mantle.     

Iceland and the North Atlantic: A review

Iceland is a special volcanic island in an anomalous ocean basin. A review of the unusual features shows that among others topography and gravity are broadly positive, spreading has been and still is complex, seismicity is slightly diffuse and the chemistry of the basalts is different from that at normal ridges. In summary we observe a tendency of lithospheric dispersal and spreading in the North Atlantic and its surroundings. These observations together with what is known about Icelandic crust, heat flow, tectonic history, etc., point to a hot mantle upwelling beneath Iceland. The shape of the upwelling currents is not known. Although at present much speculation is possible, the authors prefers to think of a broad rising region uplifting the lithospheric plates such that they tend to slide away from Iceland more forcefully than is the case from normal spreading ridges.     

Late Neogene Atlantic circulation model

A hydrodynamical-numerical model of the general circulation in the Paleo-Atlantic Ocean is applied to the climatological conditions of the period 3.6 to 2.4 m.a. b.p. For three different stages of this interval representing the transition from a warmer to a cooler climate the circulation and the temperature fields are calculated. Generally, a tendency towards a weakening of the currents is achieved.

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Zusammenfassung Ein hydrodynamisch-numerisches Modell der allgemeinen Zirkulation im Paläoatlantik wird mit den klimatologischen Randbedingungen der Periode 3.6 bis 2.4 m.a. zurück betrieben. Für drei verschiedene Zustände dieses Intervalls, die den Übergang von einer Warmzeit zu einer Kaltzeit darstellen, werden die Zirkulation und die Temperaturverteilung berechnet. Generell ergibt sich ein Trend zu einer Abschwächung des Strömungssystems.

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Résumé Un modèle numérique hydrodynamique de la circulation générale dans l'Océan Paléoatlantique est appliqué aux conditions climatiques de la période comprise entre 3.6 et 2.4 ma. Pour trois moments différents de cet intervalle, représentant la transition entre un climat plus chaud et un climat plus froid, on a calculé la distribution des circulations et des températures. En général, on observe que les courants ont tendance à atténuer.

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3,6 2,4 . , . .

     

Mesozoic and Cenozoic reconstructions of the South Atlantic

The movement of Antarctica with respect to South America has a number of implications for paleocirculation as well as for the reconstructions of Gondwanaland. Recent papers on the Southwest Indian Ridge have published new or revised poles of opening for Africa and Antarctica which can be combined with the poles of opening between South America and Africa to give resultant motions between South America and Antarctica.The first indication of a complete closure between South America and the Antarctic Peninsula is at anomaly 28 time (64 Ma) as the two continents are now configured. Between anomaly 28 time (64 Ma) and anomaly M0 time (119 Ma) the amount of closure does not change greatly, and the small computed overlap can be explained by minor uncertainties in the rotation poles used for the reconstructions or some slight extension between East and West Antarctica. By 135 Ma some rotation or translation of the Antarctic Peninsula with respect to East Antarctica must be postulated in addition to any presumed extension between East and West Antarctica in order to avoid an overlap of South America with the Antarctic Peninsula.Having determined what we feel to be a viable reconstruction of Western Gondwanaland and holding South America fixed, we rotated Africa and Antarctica, with respect to South America, for eight different times during the past. Africa moved away from South America in a more or less consistent manner throughout the time period, closure to present, while Antarctica moved away from Africa in a consistent manner only between 160 Ma and 64 Ma. At 64 Ma its motion changed abruptly: it slowed its north-south motion with respect to Africa and began slow east-west extension with respect to South America. This change supports the hypothesis that a major reorganization of the triple junction between Africa, Antarctica and South America occurred between 60 and 65 Ma. The triple junction changed from ridge-ridge-ridge to ridge-fault-fault at the time of the major westward jump of the Mid-Atlantic Ridge just south of the Falkland-Agulhas Fracture Zone.The Mesozoic opening of the Somali Basin moved Madagascar from its presumed original position with Africa in Gondwanaland. The closure of Sri Lanka with India produces a unique fit for India and Sri Lanka with respect to Africa, Madagascar and Antarctica. This fit juxtaposes geological localities in Southeast India against similar localities in Enderhy Land. East Antarctica. The late Jurassic opening in the Somali Basin is tied to opening of the same age in the Mozambique Basin. Since this late Jurassic movement represents the initial break-up of Gondwanaland, it is assumed that similar movement must have occurred in what is now the western Weddell Sea and may also explain the opening evidenced by the Rocas Verdes region of southern South America.     

Microcontinents in the Atlantic ocean

Fragments of continental structures are widespread in the North and South Atlantic and almost absent in the central segment of the ocean. This implies that the fragments are related to the geodynamics of the surrounding continents. The fragments are subdivided into two groups: microcontinents and submarine prominences of marginal continental blocks. Both groups are briefly characterized in this paper, and views on mechanisms of their formation are expressed. In my opinion, there is a good reason to believe that this line of research makes a substantial contribution to mobilistic geotectonics.     

Major change in Atlantic Deep and bottom waters 700,000 yr ago: Benthonic foraminiferal evidence from the South Atlantic

In the modern South Atlantic the transition between deep water and bottom water is marked by a clear change in the associated benthonic foraminiferal fauna. uvigerina and Globocassidulina characterize oxygen-poor Circumpolar Deep Water which has long been isolated from the surface. Planulina and miliolids are found associated with the more newly formed, oxygen-rich North Atlantic Deep Water. Antarctic Bottom Water is characterized by “Epistominella” umbonifera. Analysis of the benthonic foraminiferal faunas in two sediment cores recovered from the Vema and Hunter Channels in the western South Atlantic shows that the level of the transition between deep and bottom waters shallowed sharply about 700,000 yr ago. This rise indicates a sharp, sustained increase in the volume of bottom water flowing through the South Atlantic after this time. Prior to about 700,000 yr ago, the amount of Antarctic Bottom Water entering the western South Atlantic was greatly reduced and Circumpolar Deep Water apparently accounted for the bulk of northward flow. Production of southward-flowing North Atlantic Deep Water seems not to have been affected. The timing of this change in circulation regime suggests a possible causal link to similar changes in records of terrestrial and sea-surface climate.     

Bottom sediments and near-bottom currents in the Southwestern Atlantic

On the basis of the author’s data on the composition of sediments and seismic cross sections, together with literature data, the bottom topography was described and the main structural features of the top 10–100 m thick sedimentary sequence in the Southwestern Atlantic (Brazil Basin) were identified. The presence of a heavy northward flow of Antarctic bottom water (AABW) and its active erosive activity were confirmed. The AABW caused the erosion or redeposition of red pelagic clays and hemipelagic clays, which accumulated in the Brazil Basin in the Holocene and Pleistocene; the clays contain abundant redeposited Pleistocene diatoms and Neogene and Paleogene discoasters. In most of the sediment cores of the Brazil Basin, the red pelagic clays are of Pleistocene age. Contourites and sandy microlayers have been found in the sediments at the foot of the continental slope of South America; this is the effect of the Deep Western Boundary Current on the ocean floor. The AABW transfers Antarctic diatom species along the continental slope of South America to 10°-5° S. The presence of the Equatorial Midocean Channel with a relative depth of 149 m in the western pelagic equatorial part of the Atlantic was confirmed, and new channels, such as Vavilov and Akademik Ioffe, have been found. The AABW flows northward along the Equatorial Mid-Ocean Channel. Apparently, the Akademik Ioffe Channel is not a proper midocean channel. At 20° S (at a depth of 5000 m), Pleistocene diatomic (Ethmodiscus rex) ooze containing up to 74% amorphous SiO₂ was detected. On the Amazon-Mid-Atlantic Ridge profile, the AABW flows into the Guyana Basin through only one valley of the Nara Plain, with a depth of 4620 m. Near the Ceara Rise and on the Amazon Fan, no geologic traces of the AABW flow into the Guyana Basin were found. Near the Rio Grande Rise, the AABW might have appeared in the Eocene. The formation of the Vema Channel, which separates the Rio Grande Rise from South America, also began at that time. The AABW flows were the heaviest before the largest glaciations (particularly at isotopic stages 7/6 and 3/2).     

Composition and origin of North Atlantic deep sea cherts

Rocks described as chert from the North Atlantic, recovered during the Deep Sea Drilling Project, consist of quartz or disordered cristobalite. They occur in a wide variety of sediment types; only a few are associated with radiolarian oozes. Some of the cristobalitic cherts contain abundant clinoptilolite or palygorskite and sepiolite.The cherts have a variety of origins. They are most probably replacement cherts at sites 5, 6, and 7; direct alteration products of radiolarian ooze at site 8; and either alteration products of volanic glass or direct precipitates from hydrothermal solutions at sites 9 and 12. Evidence for these diverse origins is preserved as unusual mineral assemblages in these geologically young rocks.     

Triassic-Liassic basins and climate of the Atlantic passive margins

As the Laurasian Plate tracked north over the New England hotspots in the LateTriassic, the heated and stretched crust failed along re-activated basement structures including micro-plate sutures, and continental extensions of transforms. This created the rifted passive margins of the Atlantic and established the tectonic and climatic setting of wrench-generated coastal ranges and detrital basins bordering vast salt flats that were overlain with waters from the Tethys Sea.In tracking north from an equatorial position in the Late Triassic to a subtropical latitude in the Middle Jurassic, the plate transgressed first humid, then savanna and finally arid climatic zones, which were then bordered by a transgressing epeiric Tethyan Sea. Within these climatic zones, monsoonal circulation profoundly affected patterns of sedimentation as tropical air masses cooled and warmed adiabatically as they crossed the coastal ranges and broad salt flats.Where the basement had been pulled apart as in the Newark-Gettysburg Basin or the Argana Basin of Morocco, plutons intruded the axis of the basin in the form of dikes, lava flows and subaqueous fissure flows. Differential horizontal shear along strike-slip faults created assymetric basins with an upthrown leading plate and a subsiding trailing plate. Strata within the basins record a history of recurrent, but alternating, transtentional and transpressional episodes in an overall wrench-tectonic regime. While the borderfault facies is marked by complex unconformities, young basin sediment, volcanics, en-echelon folds, fanglomerates, turbidites and deep-water lacustrine deposits with organic-rich black shale, sediments on the trailing plate are marked by an older suite of gently inclined fluvialdeltaic sands that rest with profound unconformity on the Hercynian — Variscan basement.Where shallow marine waters of the Tethys Ocean transgressed sagged pull-apart basins (as in the Khemisset and Berrichid Basins of Morocco) or where the basement was faulted by straignt, non-branching transforms (as in Grand Banks), vast salt flats occurred forming thick, deposits of halite and potash salt. The extent of Tethyan transgression and concomitant subsidence of these basins is marked by salt diapirs in the Baltimore Canyon Trough and in the Aaiun Basin of Africa.

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Zusammenfassung Während sich die Laurasische Platte in der späten Trias nordwärts bewegte über die Hotspots Neuenglands hinweg, brach die erwärmte und gedehnte Kruste entlang reaktivierter Strukturen des Basements, sowie entlang von Mikroplatten-Rändern und entlang der Fortsetzungen von Querstörungen auf den Kontinenten. Dieser Vorgang schuf die abgesenkten passiven Ränder des Atlantik und etablierte die tektonische und klimatische Situation der Küstenketten und Sedimentationsbecken, die weite mit Tethys-Meerwasser bedeckte Salzpfannen säumten.Während der Drift der Platte von einer äquatorialen Lage zur späten Triaszeit hin in eine subtropische Breite zur mittleren Jurazeit durchlief sie zunächst humide, dann Savannen- und schließlich aride Klimazonen. Diese wurden gerahmt von dem transgredierenden epirischen Tethys-Meer. Innerhalb dieser Klimazonen wurde die Sedimentation nachhaltig durch Monsum-Zirkulation beeinflußt dadurch, daß tropische Luftmassen sich abkühlten und adiabatisch erwärmten beim Überqueren der Küstenketten und der breiten Salzebenen.Dort, wo das Basement aufriß, wie etwa im Newark-Gettysburg Becken oder im Argana Becken von Morocco, drangen Plutone in die Achse des Beckens ein in Form von Gängen, Lavaergüssen und subaquatischen Spaltenergüssen. Differentielle horizontale Schubspannungen entlang Blattverschiebungen sorgten für asymmetrische Becken mit aufgeschobener Leitplatte und abgesenkter Schlepp-Platte. Die Ablagerungen innerhalb der Becken bilden eine Geschichte periodischer aber alternierender durch Zug- und Druckspannungen beherrschte Episoden ab.Die Fazies des Randstörungssystems ist durch komplexe Diskordanzen markiert, durch junge Beckensedimente, vulkanische Gesteine, girlandenartige Faltenzüge, Fanglomerate, Turbidite und Tiefwasser-Seesedimente mit organogen-reichen Schwarzschiefern. Dagegen sind die Sedimente der Schlepp-Platten gekennzeichnet durch eine ältere Folge von schwach geneigten fluviatil-deltaischen Sanden, die mit markanter Diskordanz auf dem herzynisch-variskischen Basement ruhen.Dort, wo der flache Tethys-Ozean über die sich absenkenden Dehnungs-Becken (wie etwa die Becken von Khemisset und Berrichid von Morocco) transgredierte oder wo das Basement durch geradlinige, nicht verzweigte Querstörungen zerschnitten wurde (wie im Gebiet der Great Banks), breiteten sich weite Salzebenen aus, die dicke Halit- und Kalisalzlager bildeten. Die Ausdehnung der Tethys-Transgression und die einhergehende Absenkung dieser Becken wird durch Salz-Diapire im Baltimore Canyon Graben und im Becken von Aaiun in Afrika markiert.

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Résumé Tandis que la plaque laurasiatique se déplaçait à la fin du Trias vers le nord sur les points chauds de la Nouvelle Angleterre, il s'est produit dans la croûte échauffée et sous tension, des ruptures le long de structures réactivées du socle ainsi que le long de bordures de microplaques et des prolongements de dérangements transversaux sur les continents. Ce processus conduisit à l'affaissement des bords de l'Atlantique, et à fixer la situation tectonique et climatique des chaînes cotières et des bassins de sédimentation qui bordaient de vastes dépressions salées couvertes par les eaux de la Téthys.Pedant sa dérive, à partir d'une position équatoriale à la fin du Trias jusqu'à une latitude subtropicale au Jurassique moyen, la plaque traversa des zones climatiques d'abord humides, puis à savannes et finalement arides, qui se trouvaient en bordure des transgressions épiriques del a Thétys. Dans ces zones climatiques, la sédimentation fut fortement influencée par la mousson sous l'effet des masses d'air tropical qui se refroidissaint et se réchauffaient adiabatiquement à la traversée des chaînes côtières et des plaines salifères ouvertes.Là où le socle apparaissait, comme dans le bassin de Newark-Gettysburg ou dans le bassin d'Argan au Maroc, des plutons pénétraient dans l'axe des bassins sous la forme de dikes, de coulées de lav et de coulées fissurales subaquatiques. Des poussées différentielles horizontales suivant des failles conduisirent à des bassins asymétriques, la plaque motrice en voie de soulèvement entraînant la plaque en voie d'affaissement. Les dépôts dans les bassins représentent une histoire faite d'épisodes périodiques et alternants dominés par des tensions et compressions.Le facie dans le système en bordure des dérangements, est marqué par des discordances complexes, des sédiments de bassin jeunes, des roches volcaniques, des faisceaux de plis en guirlande, des fanglomérats, des turbidites, et des sédiments de mer profonde avec des schistes noirs riches en matières organiques. Par contre les sédiments des plaques entraînées sont caractérisés par une série plus ancienne de sables fluvio-deltaïques faiblement inclinés qui reposent avec une discordance bien marquée sur le socle hercynovarisque.Là où la Thétys, de faible profondeur, transgressait sur les bassins d'extension en voie d'affaissement (comme les bassins de Khemisset et de Berrichid au Maroc), ou là ou le socle était recoupé par des fractures transversales rectilignes sans bifurcation (comme dans les Great Banks), s'étendaient de vastes aires salées avec formation d'épaisses couches de halite et de sels potassiques. L'extension de la transgression thétysienne et la continuelle dépression de ces bassins est marquée par des diapirs salins dans le Graben de Baltymore et dans le bassin d'Aaiun en Afrique.

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Tectonic provinces of the Atlantic Ocean

The tectonic structure of the floor of the Atlantic Ocean beyond the continental margins is insufficiently studied. This is also true of its tectonic demarcation. The segmentation of the floor into regional-scale tectonic provinces of several orders proposed in this paper is primarily based on structural and historical geological features. It is shown that deep oceanic basins and fault tectonics are of particular importance in this respect. Tectonic provinces of two orders are distinguished by a set of attributes. The first-order provinces are the North, Central, South, and Antarctic domains of the Atlantic Ocean. They are separated by wide demarcation fracture zones into Transatlantic (transverse) second-order tectonic provinces. Ten such provinces are recognized (from the north southward): Greenland-Lofoten, Greenland-Scandinavia, Greenland-Ireland, Newfoundland-European, North American-African, Antilles-African, Angola-Brazil, Cape-Argentine, North Antarctic, and South Antarctic. This subdivision demonstrates significant differentiation in the geodynamic state of the oceanic lithosphere that determines nonuniform ocean formation and the tectonic features of the ocean floor. The latitudinal orientation of the second-order provinces inherits the past tectonic pattern, though newly formed structural units cannot be ruled out. The Earth rotation exerts a crucial effect on the crust and the mantle.     

Extreme surface and near-bottom currents in the northwest Atlantic

This study presents a methodology for estimating extreme current speeds from numerical model results using extremal analysis techniques. This method is used to estimate the extreme near-surface and near-bottom current speeds of the northwest Atlantic Ocean with 50-year return periods from 17?years of model output. The non-tidal currents produced by a three-dimensional ocean circulation model for the 1988?C2004 period were first used to estimate and map the 17-year return period extreme current speeds at the surface and near the bottom. Extremal analysis techniques (i.e., fitting the annual maxima to the Type I probability distribution) are used to estimate and map the 50-year extreme current speeds. Tidal currents are dominant in some parts of the northwest Atlantic, and a Monte Carlo-based methodology is developed to take into account the fact that large non-tidal extrema may occur at different tidal phases. The inclusion of tidal currents in this way modifies the estimated 50-year extreme current speeds, and this is illustrated along several representative transects and depth profiles. Seasonal variations are examined by calculating the extreme current speeds for fall-winter and spring?Csummer. Finally, the distribution of extreme currents is interpreted taking into account (1) variability about the time-mean current speeds, (2) wind-driven Ekman currents, and (3) flow along isobaths.     

Evaluation of the Atlantic Multidecadal Oscillation Impact on Large-Scale Atmospheric Circulation in the Atlantic Region in Summer

Doklady Earth Sciences - The influence of the Atlantic Multidecadal Oscillation (AMO) on large-scale atmospheric circulation in the Atlantic region in summer for the period of 1950–2015 is...     

Mineralogy and chemistry of ferromanganese crusts from the Atlantic Ocean

The mineral and chemical compositions of a set of crust samples collected from the North, Central and South Atlantic were examined by means of analytical electron microscopy and ICP-MS, chemical, and microchemical elemental analysis. The dominant mineral phases of the crusts are vernadite, asbolane, and goethite, with minor ferrihydrite, and rare hematite and feroxyhyte. The samples show wide variability in major and trace elements; however, their characteristic geochemical signatures indicate hydrogenetic origin. A comparison between the compositions of oceanic hydrogenetic and hydrothermal crusts and metalliferous hydrothermal sediments from different ocean areas suggests that the geochemical approach may be insufficient in some cases and fail to identify a hydrothermal input in ferromanganese crusts of a mixed composition.     

Paleogeography and paleobathymetry of the Mesozoic and Cenozoic North Atlantic Ocean

The history of the North Atlantic Ocean has been traced quantitatively back in time using age and subsidence of the oceanic crust in an attempt to reconstruct the vertical and horizontal elements of its physiographic evolution. Special emphasis has been paid to the history of the Iceland-Faeroe Ridge and of the epicontinental seas around this young basin. The implications of this evolution for changes in the hydrographic regime and for temporal as well as spatial contraints of the surface and bottom water circulation of the North Atlantic are enormous. During its early history this part of the world ocean was connected to the circum-equatorial Tethys Ocean (Late Jurassic to mid-Cretaceous). However, the formation of a deep water pathway to the South Atlantic towards the end of the Mesozoic and the opening of the Norwegian-Greenland Seas during the Early Cenozoic caused the North Atlantic to become part a longitudinal basin allowing an exchange between the Artic and Antarctic polar water masses.Dedicated to Professor Dr. E. Seibold, President of the German Research Society, on the occasion of his 60th birthday.