Controlling factors of volumetrically important marine carbonate cementation in deep slope settings

The controlling parameters of early marine carbonate cementation in shoal water and hemipelagic to pelagic domains are well‐studied. In contrast, the mechanisms driving the precipitation of early marine carbonate cements at deeper slope settings have received less attention, despite the fact that considerable volumes of early marine cement are present at recent and fossil carbonate slopes in water depths of several hundreds of metres. In order to better understand the controlling factors of pervasive early marine cementation at greater water depths, marine carbonate cements observed along time‐parallel platform to basin transects of two intact Pennsylvanian carbonate slopes are compared with those present in the slope deposits of the Permian Capitan Reef and Neogene Mururoa Atoll. In all four settings, significant amounts of marine cements occlude primary pore spaces downslope into thermoclinal water depths, i.e. in a bathymetric range between some tens and several hundreds of metres. Radial, radiaxial and fascicular optic fibrous calcites, and radiaxial prismatic calcites are associated with re‐deposited facies, boundstones and rudstones. Botryoidal (formerly) aragonitic precipitates are common in microbially induced limestones. From these case studies, it is tentatively concluded that sea water circulation in an extensive, near‐sea floor pore system is a first‐order control on carbonate ion supply and marine cementation. Coastal upwelling and internal or tidal currents are the most probable mechanisms driving pore water circulation at these depths. Carbonate cements precipitated under conditions of normal to elevated alkalinity, locally elevated nutrient levels and variable sea water temperatures. The implications of these findings and suggestions for future work are discussed.     

On the relationship between flow and suspended sediment transport over the crest of a sand dune, Río Paraná, Argentina

The links between large‐scale turbulence and the suspension of sediment over alluvial bedforms have generated considerable interest in the last few decades, with past studies illustrating the origin of such turbulence and its influence on flow resistance, sediment transport and bedform morphology. In this study of turbulence and sediment suspension over large sand dunes in the Río Paraná, Argentina, time series of three‐dimensional velocity, and at‐a‐point suspended sediment concentration and particle‐size, were measured with an acoustic Doppler current profiler and laser in situ scattering transmissometer, respectively. These time series were decomposed using wavelet analysis to investigate the scales of covariation of flow velocity and suspended sediment. The analysis reveals an inverse relationship between streamwise and vertical velocities over the dune crest, where streamwise flow deceleration is linked to the vertical flux of fluid towards the water surface in the form of large turbulent fluid ejections. Regions of high suspended sediment concentration are found to correlate well with such events. The frequencies of these turbulent events have been assessed from wavelet analysis and found to concentrate in two zones that closely match predictions from empirical equations. Such a finding suggests that a combination and interaction of vortex shedding and wake flapping/changing length of the lee‐side separation zone are the principal contributors to the turbulent flow field associated with such large alluvial sand dunes. Wavelet analysis provides insight upon the temporal and spatial evolution of these coherent flow structures, including information on the topology of dune‐related turbulent flow structures. At the flow stage investigated, the turbulent flow events, and their associated high suspended sediment concentrations, are seen to grow with height above the bed until a threshold height (ca 0·45 flow depth) is reached, above which they begin to decay and dissipate.     

Petrology and Thermal History of Highly Deformed Mantle Xenoliths from the Montferrier Basanites, Languedoc, Southern France: A Comparison with Ultramafic Complexes from the North Pyrenean Zone

The Oligocene basanites from Montferrier near Montpellier containvarious ultramafic xenoliths, predominantly spinel-lherzoliteslocally rich in amphibole, and a unique garnet-clinopyroxenite.The sulfide content of spinel-lherzolites is unusually highfor xenoliths and approaches that of MORB mantle sources. Thegarnet-clinopyroxenite, now consisting of recrystallized cpx+ garnet + opx + sp assemblage, results from subsolidus evolutionof a primary subcalcic clinopyroxene (plus minor spinel) compositionallysimilar to those experimentally obtained during high-pressurecrystallization of MORB; such an origin is also attested bythe Ni/Cu ratio of the coexisting sulfide component which isclose to 1. The spinel lherzolites display generally fine-grained porphyroclastictextures with varying proportions of porphyroclasts and neoblasts,and more rarely granuloblastic textures. Within each singlesample, the cores of the pyroxene and spinel porphyroclastshave nearly constant compositions. Significantly inhomogeneouschemical changes appear at the extreme edges of some large crystals,as well as in the fine-grained pyroxenes and spinel, whereasolivine composition is invariable. Such compositional variationsresult from the superimposed effects of two episodes of deformationand recrystallization. Geothermometric determinations show that all the spinel lherzolitesand the garnet-pyroxenite attained an equilibrium state around950?C. From a discussion on the origin of relict opx–cpx–spclusters and relatively high sulfide contents in peridotites,on the reconstructed primary paragenesis of the garnet-pyroxenite,and from a comparison with the North Pyrenean ultramafic associations,it is inferred that this equilibration occurred at the end ofan episode involving partial melting, crystallization, and subsolidusrecrystallization consequent on plastic deformation. Sulfideswere probably retained as sulfide melt early in this episodewhile metasomatism responsible for the crystallization of amphiboleoccurred late. This event is ascribed to a diapiric uplift upto a 45–50 km depth in relation with Oligocene riftingwhich started 35–40 m.y. ago in the Languedoc area. The compositional disequilibrium observed in a number of lherzolitesis related to a second episode of shearing deformation responsiblefor generating porphyroclastic textures, grading locally intomylonites. As a consequence of a concomitant cooling, Al andCr contents decrease in both pyroxenes, and Na content alsodecreases in clinopyroxene. The main chemical change of spinelconsists of a systematic substitution of MgAl₂O₄ by FeCr₂O₄,linked to the development of a porphyroclastic texture, i.e.to the degree of shearing deformations imposed upon the peridotites.The temperature decrease down to 750?C resulted from the ascentof previously equilibrated mantle blocks into colder parts nearthe Moho. This event occurred a few millions years before thecollection of xenoliths by the Montferrier basanites, probablyas the Cevennes fault zone below Oligocene grabens was reactivedat depth.     

Controls and predictability of carbonate facies architecture in a Lower Jurassic three-dimensional barrier-shoal complex (Djebel Bou Dahar, High Atlas, Morocco)

Spatial information on lithofacies from outcrops is paramount for understanding the internal dynamics, external controls and degree of predictability of the facies architecture of shallow‐water carbonate‐platform tops. To quantify the spatial distribution and vertical stacking of lithofacies within an outer‐platform shoal‐barrier complex, integrated facies analysis and digital field technologies have been applied to a high‐relief carbonate platform exposed in the Djebel Bou Dahar (Lower Jurassic, High Atlas, Morocco). The outer platform is characterized by subtidal, cross‐bedded, coarse grainstone to rudstone grading into supratidal, pisoidal packstone‐rudstone with tepees that together formed a 350 to 420 m wide shoal‐barrier belt parallel to the margin. This belt acted as a topographic high separating a restricted lagoon from the subtidal, open marine region. Low‐energy tidal flats developed on the protected flank of the barrier facing the lagoon. Lithofacies patterns were captured quantitatively from outcrop and integrated into a digital outcrop model. The outcrop model enabled rapid visualization of field data and efficient extraction of quantitative data such as widths of facies belts. In addition, the spatial heterogeneity was captured in multiple time slices, i.e. during different phases of cyclic base‐level fluctuations. In general, the lateral continuity of lithofacies is highest when relative water depth increased during flooding of the platform top, establishing low‐energy subtidal conditions across the whole platform, and when the accommodation space was filled with tidal flat facies. Heterogeneity increased during deposition of the relief‐building bar facies that promoted spatial diversification of depositional environments during the initial phases of accommodation space creation. Cycles commonly are composed of a thin transgressive tidal flat unit, followed by coated‐grain rudstone bar facies. Lateral to the bar facies, pisoidal‐grainstone beach deposits accumulated. These bar and beach deposits were overlain by subtidal lagoonal facies or would grow through the maximum flooding and highstand. There the bars either graded into supratidal pisoidal facies with tepees (when accommodation space was filled) or were capped by subaerial exposure (due to a sea‐level fall). Modified embedded Markov analysis was used to test the presence of common ordering in vertical lithofacies stacking in a stationary interval (constant depositional mode). Analysis of individual sections did not reveal any ordering, which may be related to the limited thickness of these sections. Composite sections, however, rejected the null hypothesis of randomness. The addition of stratigraphically significant information to the Markov analysis, such as exposure surfaces and lateral dimensions of facies bodies, strengthens the verdict of unambiguous preferential ordering. Through careful quantitative reconstruction of stratal geometry and facies relationships in fully integrated digital outcrop models, accurate depositional models could be established that enhanced the predictability of carbonate sediment accumulation.     

THE ODYSSEY OF JAPANESE COLONISTS IN THE DOMINICAN REPUBLIC*

ABSTRACT. In an agreement formalized with the Japanese government in 1956, Generalissimo Rafael Leónidas Trujillo Molina of the Dominican Republic extended an offer of refuge for Japanese immigrants seeking to improve their fortunes in the late 1950s by taking up residence in Trujillo's vaunted “Paradise of the Caribbean.” The provision of sites ultimately unfavorable for colonization, lack of infrastructure, failure of the Japanese government to address the complaints of the colonists, and political instability within the Dominican Republic led to the abandonment of five of the eight colonies. By 1962 only 276 of the 1,319 original colonists remained; the rest had either returned to Japan or sought refuge in South America. Although the fortunes of these Japanese families fell far short of their expectations, Trujillo could hardly have envisioned the contributions to Dominican society to be made by their descendants. The experiences of this relatively small number of migrants reflect the difficulties encountered when racial and geopolitical concerns take precedence over judicious plans for colonization.