A Report of the Newly Discovered Cu–Ni Ore Deposit in the West of East Tianshan, North Xinjiang, China

正Objective The Early Permian mafic–ultramafic intrusions(298–270 Ma,Mao et al.,2008),which are widely distributed in different tectonic domains in North Xinjiang,host magmatic sulfide ore deposits,making North Xinjiang the second most important region for Ni resources in China.The bulk of Cu–Ni ore deposits in East Tianshan,making up a large portion of Ni resources in North Xinjiang,were     

The Norfolk oil-shale rush, 1916–1921

Oil shales are one of those naturally occurring resources that require so much costly treatment to convert them into useful products that they are only worked on a large scale at times when the availability of cheaper alternatives is restricted. The need to find secure UK supplies during the First World War led to attempts to exploit the potential oil reserves contained in the more organic-rich parts of the Jurassic Kimmeridge Clay Formation. The most costly of these was that carried out in west Norfolk by the privately funded English Oilfields Ltd. (EOL) in 1916–1921 under the direction of Dr. William Forbes-Leslie M.D., FGS. Extensive treatment works were constructed on the Kimmeridge Clay outcrop at Setchey, five miles south of King's Lynn, but very little oil shale was worked or retorted. An extensive drilling programme claimed to have proved sulphur-free oil shales, hundreds of millions of tons of free oil, a 21-m thick seam of natural paraffin wax (ozokerite), and an abundance of metalliferous minerals. At its peak in 1920, the stock-market value of the company was several hundred million pounds at present-day prices. The turning point came in 1921 when samples of shale oil from Setchey and the products derived from them by distillation were shown to have no commercial value because of their high sulphur contents. There was, at that time, no commercially viable method of reducing the sulphur contents to an acceptable level. The free oil, ozokerite and metalliferous minerals only existed in the reports to the shareholders.     

Mechanism of Rupture Formation of the Hanshin–Awaji Earthquake (Kobe,Japan) January 17, 1995, M 6.9

Doklady Earth Sciences - The paper presents the results of modeling the stress–strain state of the epicentral zone of the strong crustal Hanshin–Awaji earthquake, which occurred in the...     

New Data on the Age of the Tonalite–Trondhjemite Orthogneisses of the Olekma Complex of the Central Part of the Chara–Olekma Geoblock,Aldan Shield

New U–Pb zircon (TIMS) results allow dating of protoliths of tonalite–trondhjemite orthogneisses of the Olekma Complex in the central part of the Chara–Olekma Geoblock (Aldan Shield) to 2825 ± 3 Ma and 2994 ± 3 Ma. Together with the results of previous geochronological studies, this proves that the Olekma Complex comprises heterochronous igneous rocks intensively reworked under amphibolite facies conditions and formed during different stages of geological evolution of the Aldan Shield.     

Radiolarians,foraminifers, and biostratigraphy of the Coniacian–Campanian deposits of the Alan-Kyr Section,Crimean Mountains

Data on the distribution of radiolarians and planktonic and benthic foraminifers are obtained for the first time from the Alan-Kyr Section (Coniacian–Campanian), in the central regions of the Crimean Mountains. Radiolarian biostrata, previously established from Ak-Kaya Mountain (central regions of the Crimean Mountains) were traced: Alievium praegallowayi–Crucella plana (upper Coniacian–lower Santonian), Alievium gallowayi–Crucella espartoensis (upper Santonian without the topmost part), and Dictyocephalus (Dictyocryphalus) (?) legumen–Spongosaturninus parvulus (upper part of the upper Santonian). Radiolarians from the Santonian–Campanian boundary beds of the Crimean Mountains are studied for the first time, and Prunobrachium sp. ex gr. crassum–Diacanthocapsa acanthica Beds (uppermost Santonian–lower Campanian) are recognized. Bolivinoides strigillatus Beds (upper Santonian) and Stensioeina pommerana–Anomalinoides (?) insignis Beds (upper part of the upper Santonian–lower part of the lower Campanian) are recognized. Eouvigerina aspera denticulocarinata Beds (middle and upper parts of the lower Campanian) and Angulogavelinella gracilis Beds (upper part of the upper Campanian are recognized on the basis of benthic foraminifers. These beds correspond to the synchronous biostrata of the East European Platform and Mangyshlak. Marginotruncana coronata-Concavatotruncana concavata Beds (Coniacian–upper Santonian), Globotruncanita elevata Beds (terminal Santonian), and Globotruncana arca Beds (lower Campanian) are recognized on the basis of planktonic foraminifers. Radiolarian and planktonic and benthic foraminiferal data agree with one another. The position of the Santonian–Campanian boundary in the Alan-Kyr Section, which is located stratigraphically above the levels of the latest occurrence of Concavatotruncana concavata and representatives of the genus Marginotruncana, is refined, i.e., at the level of the first appearance of Globotruncana arca. A gap in the Middle Campanian–lower part of the upper Campanian is established on the basis of planktonic and benthic foraminifers. The Santonian–Campanian beds of the Alan-Kyr Section, on the basis of planktonic foraminifers and radiolarians, positively correlate with synchronous beds of the Crimean-Caucasian region, and beyond. Benthic foraminifers suggest a connection with the basins of the East European Platform.     

Irreversible water–rock mass transfer accompanying the generation of the neutral,Mg–HCO3 and high-pH,Ca–OH spring waters of the Genova province,Italy

In a recent survey of the spring waters of the Genova province, many neutral Mg–HCO₃ waters and some high-pH, Ca–OH waters were found in association with serpentinites. All the springs are of meteoric origin as indicated by the stable isotopes of water and dissolved N₂ and Ar. Interaction of these meteoric waters with serpentinites determines a progressive evolution in the chemistry of the aqueous phase from an immature Mg-rich, SO₄–Cl facies of low salinity to an intermediate Mg–HCO₃ facies (pH 7.0–8.5, P_CO210^−3.5–10^−2.5 bar, Eh 150–250 mV), and to a mature Ca–OH facies (pH 10–12, P_CO2 10^−9.4−10^−10.6 bar, Eh-390 to-516 mV). The irreversible water–rock mass transfer leading to these chemical changes in the aqueous phase was simulated through reaction path modeling, assuming bulk dissolution of a local serpentinite, and the precipitation of gibbsite, goethite, calcite, hydromagnesite, kaolinite, a montmorillonite solid mixture, a saponite solid mixture, sepiolite, and serpentine. The simulation was carried out in two steps, under open-system and closed-system conditions with respect to CO₂, respectively. The calculated concentrations agree with analytical data, indicating that the computed water-rock mass transfer is a realistic simulation of the natural process. Moreover, the simulation elucidates the role of calcite precipitation during closed-system serpentinite dissolution in depleting the aqueous solution of C species, allowing the concurrent increment in Ca and the acquisition of a Ca–OH composition. Calcium–OH waters, due to their high pH, tend to absorb CO₂, precipitating calcite. Therefore, these waters might be used to sequester anthropogenic CO₂, locally preventing environmental impact to the atmosphere.