Comparison of sediment energy-texture relationships in marine and lacustrine environments

Sediments in the marine environment are generally subject to higher energy levels than those of lake systems, and lakes are virtually unaffected by tidal range which modifies beach structures formed in response to wave effects. However, despite different energy levels, the textural characteristics of both marine and lacustrine sediments are very similar. The main difference between marine and lacustrine facies is the depth range over which these characteristics remain consistent. In lakes, depth limitation may influence the development of surface waves and restrict textural distributions.Simple textural relationships can be used to describe comparable marine and lacustrine sedimentary conditions. Sediments which have been altered by post-depositional erosion, such as lag deposits, or by ice-drop or wind blown settlement, show comparable textural modifications.The settlement of silt and clay size particulates, in the marine environment and lakes, may differ slightly because of the chemical differences between salt and fresh water.     

The role of the terrestrial biosphere in Holocene carbon cycle dynamics

Measurements of atmospheric CO₂ concentration, and its stable carbon isotope composition, from gas samples trapped in ice at Taylor Dome, Antarctica, indicate that the global carbon cycle has not been in steady state during the Holocene epoch. Inverse carbon cycle modelling has led to the hypothesized cumulative release from the terrestrial biosphere of 195 Gt C between 7 and 1 kyr before present (bp ). Here, three independent lines of evidence testing this hypothesis are critically examined: global reconstructions of terrestrial carbon reservoirs, vegetation–climate modelling, and high latitude subfossil plant stable carbon isotope records. Despite inherent uncertainties associated with each approach, it emerges that none strongly upholds the suggestion that terrestrial ecosystems released large amounts of carbon between 7 and 1 kyr bp . Consequently, our understanding of the processes involved in the exchange of CO₂ between the atmosphere, oceans and land biota continues to remain incomplete and to require further investigation.     

Energy metabolism among eukaryotic anaerobes in light of Proterozoic ocean chemistry

Recent years have witnessed major upheavals in views about early eukaryotic evolution. One very significant finding was that mitochondria, including hydrogenosomes and the newly discovered mitosomes, are just as ubiquitous and defining among eukaryotes as the nucleus itself. A second important advance concerns the readjustment, still in progress, about phylogenetic relationships among eukaryotic groups and the roughly six new eukaryotic supergroups that are currently at the focus of much attention. From the standpoint of energy metabolism (the biochemical means through which eukaryotes gain their ATP, thereby enabling any and all evolution of other traits), understanding of mitochondria among eukaryotic anaerobes has improved. The mainstream formulations of endosymbiotic theory did not predict the ubiquity of mitochondria among anaerobic eukaryotes, while an alternative hypothesis that specifically addressed the evolutionary origin of energy metabolism among eukaryotic anaerobes did. Those developments in biology have been paralleled by a similar upheaval in the Earth sciences regarding views about the prevalence of oxygen in the oceans during the Proterozoic (the time from ca 2.5 to 0.6 Ga ago). The new model of Proterozoic ocean chemistry indicates that the oceans were anoxic and sulphidic during most of the Proterozoic. Its proponents suggest the underlying geochemical mechanism to entail the weathering of continental sulphides by atmospheric oxygen to sulphate, which was carried into the oceans as sulphate, fueling marine sulphate reducers (anaerobic, hydrogen sulphide-producing prokaryotes) on a global scale. Taken together, these two mutually compatible developments in biology and geology underscore the evolutionary significance of oxygen-independent ATP-generating pathways in mitochondria, including those of various metazoan groups, as a watermark of the environments within which eukaryotes arose and diversified into their major lineages.     

Can we detect oceanic biodiversity hotspots from space?

Understanding the variability of marine biodiversity is a central issue in microbiology. Current observational programs are based on in situ studies, but their implementation at the global scale is particularly challenging, owing to the ocean extent, its temporal variability and the heterogeneity of the data sources on which compilations are built. Here, we explore the possibility of identifying phytoplanktonic biodiversity hotspots from satellite. We define a Shannon entropy index based on patchiness in ocean color bio-optical anomalies. This index provides a high resolution (1 degree) global coverage. It shows a relation to temperature and mid-latitude maxima in accordance with those previously evidenced in microbiological biodiversity model and observational studies. Regional maxima are in remarkable agreement with several known biodiversity hotspots for plankton organisms and even for higher levels of the marine trophic chain, as well as with some in situ planktonic biodiversity estimates (from Atlantic Meridional Transect cruise). These results encourage to explore marine biodiversity with a coordinated effort of the molecular, ecological and remote sensing communities.     

Regional differences in pelagic productivity in the late Eocene to early Oligocene—a comparison of southern high latitudes and lower latitudes

Paleoproductivity patterns at the Eocene-Oligocene boundary in southern high latitudes and in the equatorial oceans were synthesized from the literature. Three ODP/DSDP sites from the Southern Ocean (Sites 689, 748 and 511) were compared with three DSDP/ODP sites from the equatorial oceans (Sites 574, 462 and 959). Paleoproductivity was estimated by multiple sedimentological, biological and geochemical proxies. Changes in paleoproductivity at the Eocene-Oligocene boundary mainly took place in the southern high latitudes. At Site 689, the benthic foraminiferal fauna also indicates an increase in seasonality. In equatorial oceans, there are no indications for a shift to higher paleoproductivity at the Eocene-Oligocene boundary. On the contrary at Site 959, sedimentology documents decreasing paleoproductivity in the Oligocene. Major changes in temperature and ocean circulation in southern high latitudes versus only minor changes in the lower latitudes were probably responsible for the geographically different changes in paleoproductivity.     

NUTRIENT CYCLING IN MARINE ECOSYSTEMS

SUMMARY

The overall cycles of nitrogen, phosphorus and silicon in the sea are described and compared. Data on the fluxes and rates of change between various pools of each nutrient are given, where available, and gaps in knowledge are pointed out. The various methods used to determine such fluxes are reviewed, and differences between coastal and offshore systems are discussed.     

NUTRIENTS IN AQUATIC ECOSYSTEMS: AN INTRODUCTION TO SIMILARITIES BETWEEN FRESHWATER AND MARINE ECOSYSTEMS

Summary

Biologists in the aquatic sciences are often guilty of numerous errors in the presentation of their chemical data. This paper reviews the use of units in the representation of the inorganic constituents of aquatic solutions for their benefit. It explains the relationship between salinity, total dissolved solids and conductivity, and between the amount of substance and concentration, and specifies conditions in which each can be used. Methods for the mathematical verification of analytical results are briefly discussed. Tables of recommended units, conversion factors and molar conductivities are provided. It is concluded that chemical data can easily be reported correctly and that both authors and referees have a duty to ensure that this is done.