Chloritization of the hydrothermally altered bedrock at the Igarapé Bahia gold deposit,Carajás,Brazil

The Igarapé Bahia gold deposit has developed from weathering of a near-vertical hydrothermal Cu (Au) mineralization zone. The unweathered bedrock composed of chlorite schists is mainly metamorphosed basalts, pyroclastic and clastic sedimentary rocks and iron formation. Contents and Fe/(Fe + Mg) ratios of chlorites increase from distal country rock towards the mineralization zone, which can be attributed to different water/rock ratios and locations in a hydrothermal system. In the hydrothermal system high salinity fluids convected through basin-floor rocks, stripping metals from the recharge zones with precipitation in discharge zones. The chlorite with lower Fe/(Fe + Mg) ratios indicates alteration by relatively unreacted Mg-rich fluids, occurring within recharge zones. By contrast, the chlorite with higher Fe/(Fe + Mg) ratios in the mineralization zone formed from solutions rich in Fe, Mn, Au, Cu, H₂S and SiO₂ within a discharge zone. The iron formation could also be formed within the discharge zone or on the basin floor from the Fe-rich fluids. The distal country rock with less chlorite content is a hydrothermal product at low water/rock ratios whereas the proximal country rock and the host rock with more chlorite content formed at high water/rock ratio conditions. The Al(IV) contents of chlorites indicate that the formation temperatures of these rocks range from 204 to 266 °C, with temperatures slightly increasing from distal country rock towards the mineralization zone.     

Mobilities of alkalis, alkaline earths and halogens during weathering

Concentrations of alkali metals, alkaline earths and halogens were monitored in an Australian weathering profile and in Brazilian soils and bauxite. The materials analysed are considered to represent a range of chemical weathering histories, which are distinguished with respect to their degree of leaching by the dominant aluminosilicate assemblages. During initial weathering concentrations of alkalis and alkaline earths are similar or enriched relative to average crustal abundances. As weathering proceeds depletion is attenuated by the capacity of a particular element to participate in adsorption and ion-exchange processes. Strong depletion of alkalis and alkaline earths is common as weathering advances, and clay minerals are replaced by Al-oxide phases (e.g., gibbsite), with much lower capacities for exchanging and incorporating ions. Halogen concentration trends are more variable. F retention during weathering is likely due to substitution in mineral phases for hydroxyl groups. Cl and I are commonly observed to accumulate as weathering advances and some of these accumulations may be due to atmospheric additions.     

Uranium-thorium systematics of two Canadian coals

A detailed study of U-Th distribution in two Lower Cretaceous coals in Canada shows that for these coals formed in a continental fluvial and deltaic environment with no marine influence, the U contents are in the range 0.07–7.5 ppm with Th in the range 0.3–11.0 ppm. Average Th/U ratios are near 2 which indicates slight uranium enrichment. The environments of the two coals show different degrees of weathering (montmorillonite-illite and kaolin-gibbsite) and U values are lowest in the more weathered environment In sedimentary profiles associated with the coals, the maximum uranium values are not in the coals but in carbonaceoss clay sediments above and below coal seams. Uranium distribution patterns can be correlated cith Ni, Cu, Rb, Pb, Sr, and Zr, indicating contributions from heavy minerals plus more mobile species (possibly simple organic compounds) which are adsorbed or bonded onto claysor organic matter.     

Al,Si ordering on cordierite using “magic angle spinning” NMR

Silicon-29 “magic angle spinning” nuclear magnetic resonance (NMR) spectroscopy has been used to study the changes in local Si environment during Al, Si ordering in synthetic cordierite, Mg₂Al₄Si₅O₁₈. In the most disordered form, crystallized from a glass, eight distinct tetrahedral sites for silicon can be identified and assigned, while there are only two distinguishable Si sites in the well-annealed ordered form. This allows the changes in the Si site environments to be determined as a function of annealing time for the transformation from the disordered to the ordered form. The first crystallized state has a considerable degree of partitioning between T₁ and T₂ sites with the following site occupancies: T₁ ? Al:Si=0.80:0.20, T₂?Al:Si=0.27:0.73 The changes in Si environment are approximately linear with log time. The measured values of ²⁹Si isotropic chemical shift do not fit well to previously determined correlations of shift with various structural parameters.     

Density constraints on the formation of the continental Moho and crust

The densities of mantle magmas such as MORB-like tholeiites, picrites, and komatiites at 10 kilobars are greater than densities for diorites, quartz diorites, granodiorites, and granites which dominate the continental crust. Because of these density relations primary magmas from the mantle will tend to underplate the base of the continental crust. Magmas ranging in composition from tholeiites which are more evolved than MORB to andesite can have densities which are less than rocks of the continental crust at 10 kilobars, particularly if they have high water contents. The continental crust can thus be a density filter through which only evolved magmas containing H₂O may pass. This explains why primary magmas from the mantle such as the picrites are so rare. Both the over-accretion (i.e., Moho penetration) and the under-accretion (i.e., Moho underplating) of magmas can readily explain complexities in the lithological characteristics of the continental Moho and lower crust. Underplating of the continental crust by dense magmas may perturb the geotherm to values which are characteristic of those in granulite to greenschist facies metamorphic sequences in orogenic belts. An Archean continental crust floating on top of a magma flood or ocean of tholeiite to komatiite could have undergone a major cleansing process; dense blocks of peridotite, greenstone, and high density sediments such as iron formation could have been returned to the mantle, granites sweated to high crustal levels, and a high grade felsic basement residue established.     

Subduction and the geochemical cycle

The present balance of crust creation at ocean ridges and above subduction zones appears to be similar to crust removal processes at subduction zones. Almost 10% of the mass of the upper mantle has been influenced by surface hydrosphere, atmosphere and crustal component contamination. As long as surface components are subducted, then in a slowly cooling planet it is difficult to see how the mass of continents and hydrosphere can increase with time.     

Northern Hemisphere circulation regimes: observed, simulated and predicted

Nonlinear principal component analysis provides evidence that the Northern Hemisphere extratropical atmosphere supports three distinct circulation regimes with an average residence time of about 7 days. The role of high- and low-frequency dynamics is studied and results indicate that they are both involved in the formation, maintenance and decay of the regimes. A global coupled climate model also supports three distinct circulation regimes with strikingly similar spatial structures, residence times and linked high- and low-frequency dynamics to those observed. The issue related to how long a data record is required to properly resolve the regime structures is addressed by exploiting the model output. Regime residence times and spatial structures are predicted to change over the next century given increasing concentrations of atmospheric greenhouse gases.     

On the response of the oceanic wind-driven circulation to atmospheric CO2 increase

A global, flux-corrected climate model is employed to predict the surface wind stress and associated wind-driven oceanic circulation for climate states corresponding to a doubling and quadrupling of the atmospheric CO₂ concentration in a simple 1% per year CO₂ increase scenario. The model indicates that in response to CO₂ increase, the position of zero wind stress curl in the mid-latitudes of the Southern Hemisphere shifts poleward. In addition, the wind stress intensifies significantly in the mid-latitudes of the Southern Hemisphere. As a result, the rate of water circulation in the subpolar meridional overturning cell in the Southern Ocean increases by about 6 Sv (1 Sv=10⁶ m³ s⁻¹) for doubled CO₂ and by 12 Sv for quadrupled CO₂, implying an increase of deep water upwelling south of the circumpolar flow and an increase of Ekman pumping north of it. In addition, the changes in the wind stress and wind stress curl translate into changes in the horizontal mass transport, leading to a poleward expansion of the subtropical gyres in both hemispheres, and to strengthening of the Antarctic Circumpolar Current. Finally, the intensified near-surface winds over the Southern Ocean result in a substantial increase of mechanical energy supply to the ocean general circulation.