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61.
Chicgoua Noubactep 《洁净——土壤、空气、水》2013,41(7):702-710
Water treatment with metallic iron (Fe0) is still based on the premise that Fe0 is a reducing agent. An alternative concept stipulates that contaminants are removed by adsorption, co‐precipitation, and size‐exclusion in a reactive filtration process. This article underlines the universal validity of the alternative concept. It is shown that admixing non‐expansive material to Fe0 as a pre‐requisite for sustainable Fe0‐based filtration systems. Fe0‐based filters are demonstrated an affordable, appropriate, and efficient decentralized water treatment technology. 相似文献
62.
巴哟磁铁矿矿化露头多,矿床小而散,属风化残坡积型,原生矿成因类型较复杂,成矿地质条件良好,铁矿找矿潜力较大,具大型富铁矿找矿远景。 相似文献
63.
《International Geology Review》2012,54(7):737-764
The Tonglushan Cu–Fe deposit (1.12 Mt at 1.61% Cu, 5.68 Mt at 41% Fe) is located in the westernmost district of the Middle–Lower Yangtze River metallogenic belt. As a typical polymetal skarn metallogenic region, it consists of 13 skarn orebodies, mainly hosted in the contact zone between the Tonglushan quartz-diorite pluton (140 Ma) and Lower Triassic marine carbonate rocks of the Daye Formation. Four stages of mineralization and alterations can be identified: i.e. prograde skarn formation, retrograde hydrothermal alteration, quartz-sulphide followed by carbonate vein formation. Electron microprobe analysis (EMPA) indicates garnets vary from grossular (Ad20.2–41.6Gr49.7–74.1) to pure andradite (Ad47.4–70.7Gr23.9–45.9) in composition, and pyroxenes are represented by diopsides. Fluid inclusions identify three major types of fluids involved during formation of the deposit within the H2O–NaCl system, i.e. liquid-rich inclusions (Type I), halite-bearing inclusions (Type II), and vapour-rich inclusions (Type III). Measurements of fluid inclusions reveal that the prograde skarn minerals formed at high temperatures (>550°C) in equilibrium with high-saline fluids (>66.57 wt.% NaCl equivalent). Oxygen and hydrogen stable isotopes of fluid inclusions from garnets and pyroxenes indicate that ore-formation fluids are mainly of magmatic-hydrothermal origin (δ18O = 6.68‰ to 9.67‰, δD = –67‰ to –92‰), whereas some meteoric water was incorporated into fluids of the retrograde alteration stage judging from compositions of epidote (δ18O = 2.26‰ to 3.74‰, δD= –31‰ to –73‰). Continuing depressurization and cooling to 405–567°C may have resulted in both a decrease in salinity (to 48.43–55.36 wt.% NaCl equivalent) and the deposition of abundant magnetite. During the quartz-sulphide stage, boiling produced sulphide assemblage precipitated from primary magmatic-hydrothermal fluids (δ18O = 4.98‰, δD = –66‰, δ34S values of sulphides: 0.71–3.8‰) with an extensive range of salinities (4.96–50.75 wt.% NaCl equivalent), temperatures (240–350°C), and pressures (11.6–22.2 MPa). Carbonate veins formed at relatively low temperatures (174–284°C) from fluids of low salinity (1.57–4.03 wt.% NaCl equivalent), possibly reflecting the mixing of early magmatic fluids with abundant meteoric water. Boiling and fluid mixing played important roles for Cu precipitation in the Tonglushan deposit. 相似文献
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东天山黑峰山、双峰山及沙泉子(铜)铁矿床的矿物微量和稀土元素地球化学特征 总被引:1,自引:0,他引:1
东天山黑峰山铁矿床、双峰山铁矿床以及沙泉子铜铁矿床位于新疆哈密盆地以南,是东天山阿齐山-雅满苏构造带的重要矿床。文章利用磁铁矿、黄铁矿和方解石的微量元素及稀土元素组成示踪了这些矿床的成矿流体来源和性质,初步探讨了矿床的成因类型。激光剥蚀(LA)-ICP-MS磁铁矿微量元素分析表明,三个矿床的磁铁矿具有非常低的w(V)、w(Cr)和w(Ti)(平均分别为68×10-6、13×10-6和237×10-6),指示磁铁矿形成于热液过程而不是岩浆分异。黄铁矿中较高的Cu含量可能反映了含Cu矿物微颗粒的存在。黄铁矿中较低的Pb、Zn含量可能反映了成矿流体中较低的Pb2+和Zn2+浓度。黄铁矿中的Co/Ni比值表明这些矿床均为火山-热液成因。三个矿床黄铁矿的稀土元素总量都很低(ΣREE为0.58×10-6~3.02×10-6),黑峰山铁矿中的黄铁矿轻、重稀土元素分馏不明显,双峰山铁矿和沙泉子铜铁矿中的黄铁矿均为轻稀土元素富集型,(La/Yb)N分别为3.51~13.4和2.76~17.2。三个矿床略有差别的方解石稀土元素配分模式,反映了其流体组成和形成机制的差别。黑峰山铁矿中的重稀土元素富集型的方解石稀土元素配分模式为方解石Sm-Nd定年提供了依据。三个矿床的黄铁矿和方解石均无Ce异常,黑峰山铁矿中的黄铁矿和方解石表现为负Eu异常,而双峰山铁矿和沙泉子铜铁矿中的黄铁矿和方解石表现为正Eu异常,反映了三个矿床均形成于较高的温度,前者成矿流体可能为碱性,后两者成矿流体为酸性、还原性。结合前人研究成果认为,黑峰山铁矿、双峰山铁矿及沙泉子铜铁矿均为火山热液-充填(交代)矿床。 相似文献
69.
Frédéric Moynier Toshiyuki Fujii Kun Wang Julien Foriel 《Comptes Rendus Geoscience》2013,345(5-6):230-240
Iron is one of the most abundant transition metal in higher plants and variations in its isotopic compositions can be used to trace its utilization. In order to better understand the effect of plant-induced isotopic fractionation on the global Fe cycling, we have estimated by quantum chemical calculations the magnitude of the isotopic fractionation between different Fe species relevant to the transport and storage of Fe in higher plants: Fe(II)-citrate, Fe(III)-citrate, Fe(II)-nicotianamine, and Fe(III)-phytosiderophore. The ab initio calculations show firstly, that Fe(II)-nicotianamine is ~3‰ (56Fe/54Fe) isotopically lighter than Fe(III)-phytosiderophore; secondly, even in the absence of redox changes of Fe, change in the speciation alone can create up to ~1.5‰ isotopic fractionation. For example, Fe(III)-phytosiderophore is up to 1.5‰ heavier than Fe(III)-citrate2 and Fe(II)-nicotianamine is up to 1‰ heavier than Fe(II)-citrate. In addition, in order to better understand the Fe isotopic fractionation between different plant components, we have analyzed the iron isotopic composition of different organs (roots, seeds, germinated seeds, leaves and stems) from six species of higher plants: the dicot lentil (Lens culinaris), and the graminaceous monocots Virginia wild rye (Elymus virginicus), Johnsongrass (Sorghum halepense), Kentucky bluegrass (Poa pratensis), river oat (Uniola latifolia), and Indian goosegrass (Eleusine indica). The calculations may explain that the roots of strategy-II plants (Fe(III)-phytosiderophore) are isotopically heavier (by about 1‰ for the δ56Fe) than the upper parts of the plants (Fe transported as Fe(III)-citrate in the xylem or Fe(II)-nicotianamine in the phloem). In addition, we suggest that the isotopic variations observed between younger and older leaves could be explained by mixing of Fe received from the xylem and the phloem. 相似文献
70.