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1.
《Applied Geochemistry》1997,12(2):119-131
Only small, low grade occurrences of bauxite are known in Nigeria, associated with ferricretes on the Jos Plateau. Widespread bauxite has been discovered on the Mambilla Plateau. Laterite is developed on gneisses and basalt, while on trachytic parent rocks low-silica bauxite occurs with a thickness of more than 5 m and covering an area of at least 1 km2. This bauxite consists of gibbsite and goethite.In contrast to the ferricretes of the Jos Plateau, weathering on the Mambilla Plateau led to the formation of stone line profiles. Ferricretes were developed on the Upper Jurassic Gondwana surface under contrasting climate and are preserved as relicts in the southern part of the Mambilla Plateau where weathered Precambrian basement occurs in a highly uplifted position. Dismantling of these ferricretes is attributed to a gradual change of paleoclimate towards more humid conditions. After the extrusion of volcanic rocks in the northern part of the plateau, presumably during Lower to Mid Miocene, these volcanics underwent intense chemical weathering. Bauxite and laterite formed depending on the type of parent rock. Weathering profiles are mostly truncated and overlain by reworked material. Allochthonous components occur both within and also below the stone-line. This is shown by mineralogical indicators such as ilmenite or quartz and by a shift in the Zr/Ti-ratio. Similar profiles are missing further north on the Jos plateau, where ferricretes formed instead. This is attributed to regional differences in paleoclimatic conditions which were more humid at Mambilla while Jos was under the influence of dryer conditions.The widespread formation of laterite on different parent rocks on the Mambilla Plateau could be related to a global Mid-Miocene climatic optimum, which led to a general intensification of chemical weathering processes. 相似文献
2.
Thair Al-Ani 《Arabian Journal of Geosciences》2017,10(3):72
Nuwaifa Formation is a part of sequence stratigraphy that belongs to the Jurassic system exposed in the western desert of Iraq. The Jurassic system consists of Ubaid, Hussainiyat, Amij, Muhaiwir, and Najmah formations. Each formation is composed of basal clastic unit overlain by upper carbonate unit. Nuwaifa karst bauxite was developed in fossil karsts within the Ubaid Formation in areas where maximum intersection of fractures and faults exist. This bauxitization process affected the upper surface of the Ubaid limestone formation, which directly underlies the Nuwaifa bauxite Formation. Nuwaifa Formation represents karst-filling deposit that consists of a mixture of allochthonous (sandstone, claystone, and mudstone) and autochthonous lithofacies (bauxite kaolinite, kaolinitic bauxite, iron-rich bauxite, and flint clay). Most bauxite bodies occur within the autochthonous lithofacies and are lenticular in shape with maximum thickness ranges from few meters to 35 m and in some place up to 100 m. Petrographically, the bauxite deposit exhibits collomorphic-fluidal, pisolitic, oolitic, nodular, brecciated, and skeletal textures indicative of authigenic origin. Mineralogy boehmite and gibbsite are the only bauxite minerals; the former is dominant in the upper parts of the bauxite profiles, whereas the latter is dominant throughout the lower and middle part of the bauxite. Kaolinite, hematite, goethite, calcite, and anatase occur to a lesser extent. The study bauxites are mainly composed of Al2O3 (33–69.6 wt.%), SiO2 (8.4–42 wt.%), Fe2O3 (0.5–15.9 wt.%), and TiO2 (0.7–6.1 wt.%) with LOI ranging from 13.5 to 19.1 wt.%. Geochemical investigations indicate that the immobile elements like Al2O3, TiO2, Cr, Zr, and Ni were obviously enriched, while SiO2, Fe2O3, CaO, MgO, Zn, Co, Ba, Mn, Cu, and Sr were depleted during bauxitization process. The results of this study strongly suggest that the bauxite deposits of the Nuwaifa Formation are derived from the kaolinite of the Lower Hussainiyat Formation. 相似文献
3.
Abstract. The Dholkata bauxite deposit of Keonjhar district, Orissa, has developed on the metavolcanics of tholeiitic basalt composition. The weathered profile reveals five distinct altered zones, such as topsoil, laterite, bauxite, lithomarge and altered metavolcanics. The mineralogy of different zones studied in a representative pit shows the association of major mineral constituents like gibbsite, goethite, hematite, kaolinite, limonite and quartz. Gibbsite is the most dominant one followed by goethite and hematite in the bauxite zone. The geochemical study of all weathering zones indicates the geochemical affinity of the elements Ni, Th and U for laterites and Cr, Zr and Hf for bauxites to occur in high quantities. Trend surface maps predict the bauxite zones in the different levels of the deposit. If the zones having A12 O3 35–40 % are blended with high grade ores, the deposit may prove to be a potential one. 相似文献
4.
《International Geology Review》2012,54(2):179-193
The Chadobets uplift is located in the southwestern part of the Siberian platform (Lat. 59° 10′ N, Long. 99°29′–100° 11′ E). It is a brachyanticline with two domes, the Terinovskiy (19 × 16 km) and the Chuktukon (7 × 6 km). The Central and Chuktukon deposits situated on the domes were derived from laterized Proterozoic quartz-mica-feldspar slates and sandstones and Triassic alkaline ultramafic rocks (picrite, pyroxenite, kimberlite, and carbonatite). The laterite profiles attain a thickness of 600 m on slates, 300 m on carbonatites, and 80 km on kimberlites. The final weathering products are bauxites, Al-Ti-Fe laterites, and Fe-Mn ochres enriched in REE (up to 50% Ln2O3 and 1% Y2O3), Nb (up to 5% Nb2O5), Ti (up to 32% TiO2), Th (0.1–0.4% ThO2), as well as Ba, P., Zn, and V. The laterites contain gibbsite; goethite; hematite; anatase after perovskite; oxyhydroxides of Mn; supergene monazite; rhabdophane; florencite; churchite; Ce-, Ba-, and Sr-pyrochlores; cerianite; barite; francolite; etc. Cretaceous-Paleogene sedimentary bauxites accumulated all these minerals, plus boehmite, diaspore, corundum, berthierine, siderite, calcite, marcasite, and pyrite. The bauxites contain 9.5% TiO2, up to 4% TR2O3 (LREE), 0.8% Nb2O5, and 0.31% ThO2. Because of their geologic setting, number of parent rocks, and mineral and chemical composition, the Central and Chuktukon deposits are unique complex deposits of bauxite, rare elements, and rare-earth elements. 相似文献
5.
The Minim-Martap plateau bauxite deposit, located between the Minim and the Martap villages, is one of the 11 plateaus within the Minim-Martap bauxite region. The plateau has an elevation of 1294 m above sea level, with three to more 30 m thickness of bauxite horizon. These plateaus were formed as result of supergene weathering of volcanic rocks occurring as dissected flow basalt landscapes that form relatively flat plateau rising steeply from the surrounding granites. The bauxite deposit of the plateau is lateritic, with the surface of the plateau been completely covered by indurated caps. Seventeen bauxite samples were collected from the plateau and prepared for geochemical analysis. Whole rock analysis was carried out using the X-ray Fluorescence technique and ICP-MS was used for trace elements investigation. Statistical analysis reveals that average values of Al2O3 (54.87%), Fe2O3 (7.17%), SiO2 (2.44%), and TiO2 (4.54%) indicate the plateau bauxite deposit is an of a world class standard with very little impurities compared to the standard major element contents of bauxite (>?40% A12O3, less than <?20% Fe2O3, and less than <?8% combined SiO2). Abundant trace elements include Zr, Ce, Sr, V, Ba, La, Nd, Ga, and Nb. Weathering due to chemical alteration indices using the Ruxton ratio and CIA approaches revealed the plateau have undergone intense weathering process that formed the bauxite deposit. Three different classification systems indicate it as a low iron-rich bauxite deposit. Precursor rock investigation indicates the origin of the bauxite is mafic, basaltic andesite igneous rocks with intermediate pH (basic–acidic characteristic). 相似文献
6.
《Journal of South American Earth Sciences》2000,13(1-2):47-65
Chemical, mineralogical, and petrographic data from the Los Pijiguaos bauxite deposit, together with the water chemistry of the streams draining the area, were used to study the problem of lateritic bauxite formation at this location. The Los Pijiguaos bauxite, located at the northwestern edge of the Guayana Shield in Venezuela, is a lateritic bauxite developed on a Precambrian Rapakivi Granite Batholith, the Parguaza Granite. This deposit is situated on a planation surface at elevations between 600 and 700 m; it is believed to have originated during an erosional event that took place during Late Cretaceous-early Tertiary times.The weathering profile is composed of an upper bauxite zone, followed by a saprolite, and merging gradually to the fresh granite. The upper bauxitic zone contains gibbsite, quartz, hematite, and goethite. The saprolite contains kaolinite, quartz, and goethite and is characterized by a relict granitic texture that indicates little bulk volume change associated with the weathering process. The upper bauxitic zone has lost any textural resemblance with the parent granite, consistent with extensive volume loss.Bauxite and saprolite are separated by a transition zone where gibbsite and kaolinite coexist. Textures indicating the replacement of kaolinite by gibbsite point to the dynamic nature of the weathering profile, characterized by advancing reaction fronts.The chemical composition of the deposit defines trends that can be traced back to the composition of the parent granite and shows enrichment of Al2O3, Fe2O3, and TiO2, and depletion of SiO2, relative to the parent granite. The uppermost part of the profile is characterized by a further enrichment of Fe2O3 with respect to the other components of the bauxite. Important volume and mass losses in the bauxite have also been calculated, based on chemical composition and density measurements. The calculated losses are consistent with the textural observations in the bauxite.The chemical composition of the waters of streams draining the area shows strong seasonal patterns, consistent with the seasonal nature of the local climate (one dry and one rainy season per year, both about six months long). The balance between dissolved and suspended loads in these streams indicates that the magnitudes of chemical and physical denudation are similar, leading to approximately constant thicknesses of the weathering profiles. These observations are consistent with model calculations based on current climatic conditions and suggest that the bauxitization process is still active. 相似文献
7.
Xuefei Liu Qingfei Wang Jun Deng Qizuan Zhang Silei Sun Jianyin Meng 《Journal of Geochemical Exploration》2010
The Dajia Salento-type bauxite deposit in western Guangxi is hosted within the Quaternary ferrallitic soil profile, and it formed via breaking up, weathering and oxidizing of Permian bauxite orebodies occurring as a semi-continuous layer in the upper Permian. Mineralogical analyses reveal that diaspore, hematite and kaolinite are the major minerals in bauxite ores with small amounts of anatase, chamosite, gibbsite, goethite, illite, zircon, quartz and pyrite. The ore texture and mineral assemblage reveal that the depositional/diagenetic environment of the Dajia bauxite was much close to phreatic environment. Both the ore texture and the morphology of zircon grains also indicate that most of the bauxitic soils were transported a short distance. Diaspore is suggested to be non-metamorphic in origin and mainly formed in a reducing condition of diagenetic environment, while kaolinite is the product of the in situ epigenetic replacement of alumina in diaspore by dissolved silica. Geochemical analyses indicate that Al2O3, Fe2O3, SiO2 and TiO2 are the main components of the bauxite ores and trace elements such as Zr, Hf, Nb, Ta, Th and U were enriched during the bauxitization process. Simultaneously, Zr vs. Hf and Nb vs. Ta show a high correlation. Geochemical indices such as Zr/Hf, Nb/Ta and Eu/Eu* (among others) denote that the magmatic rocks related to the Emeishan plume in western Guangxi and the carbonates in the underlying Maokou Formation provided the main sources of material for the bauxite ores. 相似文献
8.
H. E. Zeissink 《Mineralium Deposita》1969,4(2):132-152
A laterite profile on serpentinite at Greenvale, Australia, has been investigated in order to elucidate the formation of the secondary minerals and the trace element behaviour during tropical weathering. Mineralogical and chemical studies indicate that the serpentine alters to montmorillonite, aluminous goethite, and quartz. Chromiferous chlorite, a stable component, becomes concentrated in the weathering profile. No members of the kaolin group or bauxite group were identified, and the alumina occurs chiefly in solid solution with the goethite. In the upper levels of the profile serpentine and mont-morillonite disappear completely, and the amount of alumina substituting in the goethite increases. With increasing depth the Fe2O3 and Al2O3 content falls, whereas SiO2 and MgO increase. This is in accordance with the usual trends of lateritic weathering. The trace elements Ni, Co, Mn, Cu and Cr are all concentrated during the weathering process. Evidence suggests that Ni is associated with goethite, and possibly is incorporated in the lattice of this mineral. No appreciable nickel is associated with the manganese minerals. The concentration of Cr takes place mainly through the increase of the stable chromiferous chlorite.
Ein Lateritprofil des Serpenitis von Greenvale, Australien, wurde hinsichtlich seines Mineral- und Spurengehaltes untersucht. Ausschlaggebend waren die durch die tropische Verwitterung entstandenen Sekundärmineralien. Mineralogische und chemische Untersuchungen lassen erkennen, daß aufgrund der Verwitterung die Serpentingesteine Umwandlungen in Montmorillonit, aluminiumhaltigen Goethit und Quarz zeigen. Minerale der Kaolin- oder Bauxitgruppen ließen sich nicht feststellen, da Aluminiumgehalte in Form fester Lösung im Goethit gebunden wurden; in höher gelegenen Profilen kommen Serpentine und Montmorillonit zum völligen Verschwinden. Mit zunehmender Tiefe nehmen Fe2O3- und Al2O3-Gehalte ab, während SiO2 und MgO ansteigen, analog zu Beobachtungen an bekannten lateritischen Verwitterungsprofilen. Im Zuge der Entstehung neuer Verwitterungsmineralien erfahren Elemente wie Nickel, Kobalt, Mangan, Kupfer und Chrom eine partielle Anreicherung. Z. B. wird Nickel in Eisenmineralien gebunden (Goethit), während chromhaltige Chlorite sich als stabil erweisen und sich bei der Verwitterung anreichern.相似文献
9.
Bauxite deposits in the Usambara Mountains of north eastern Tanzania occur as remnants of residual deposits on two geomorphologically related plateaus of Mabughai-Mlomboza and Kidundai at Magamba in Lushoto, Usambara Mountains. The parent rocks for the deposits are mainly granulites and feldspathic gneisses of Neoproterozoic Mozambique belt. The plateaus represent a preserved Late Cretaceous–Lower Tertiary old land surface (African surface). Other parts of the Usambara Mountains and the neighbouring Pare Mountains are covered mostly by red–brown lateritic soils and impure reddish-brown kaolinitic clays. The bauxite deposits contain mainly Al2O3 (40–69 wt.%), Fe2O3 (3–10 wt.%), SiO2 (0.16–7 wt.%) and other elements occur in quantities not substantial to affect the quality or processing of the bauxite, and are attributed to the presence of relic minerals. Gibbsite makes up to 98 vol.% of the bauxite ore in special cases. Gibbsite is accompanied by goethite in the ore. Boehmite occurs in small amounts and is usually accompanied by hematite. Impurities include goethite, hematite, kaolinite, and minor relic quartz and microcline. Kaolinite is the sole clay mineral encountered in the bauxite ore, suggesting mature soil profiles and a development of the bauxite deposits on a well-drained peneplanation. Ore reserve estimates from the drilling data and surface geological mapping of the deposits yielded bauxite reserves of about 37 million tonnes. 相似文献
10.
Mineralogical and geochemical characteristics of two bauxitic profiles, Fria, Guinea Republic 总被引:1,自引:0,他引:1
Bauxite deposits of the Fria district, Guinea, have been exploited since 1960. These lateritic bauxites, located on the upper
parts of plateaus, result from weathering of paleozoic schists. The ores are composed of gibbsite associated with pyrophyllite,
Al-substituted gœthite, and kaolinite. Pyrophyllite and Al-substituted gœthite may contain up to 9% of the total Al2O3 content of the bauxite; this cannot be recovered through the Bayer process because these phases are insoluble in the leaching
solutions. Kaolinite is soluble under Bayer leaching but this dissolution induces precipitation of sodium aluminosilicates,
which apart from loss of further alumina results in decreasing efficiency of the process through scale formation. Detailed
knowledge of the distribution of the different ore types and their mineralogical composition is necessary for efficient processing. 相似文献
11.
Paola Mameli Giovanni Mongelli Giacomo Oggiano Enrico Dinelli 《International Journal of Earth Sciences》2007,96(5):887-902
Bauxite deposits are widespread in NW Sardinia. They formed during the middle Cretaceous, in consequence of a period of emergence of the Mesozoic carbonate shelf. In the Nurra area the geometries derived by the Middle Cretaceous tectonic phases controlled the ore typologies. Two bauxite profiles, laying on different bedrocks, were sampled. The bauxitization proceeded from the surface downward, with the accumulation of Al2O3 and residual ‘immobile’ elements (Al, Ti, HFSE), and corresponding mobility and loss of SiO2 and Fe2O3. Epigenetic kaolinite formed close to faults and joints, probably as a result of silicification, introduced by low temperature hydrothermal solutions. Rare earth elements, especially LREE, are concentrated in Fe-rich bauxite horizons, probably due to scavenging by goethite. REE-enrichment is not observed in the boehmite-rich horizons. Very high REE contents are observed in a Fe-depleted horizon due to the occurrence of REE accessory minerals, probably of the bastnäsite group. Conservative indices, including TiO2/Al2O3 and Ti/Cr ratios, and Eu anomalies (Eu/Eu*), suggest that the deposits formed by weathering of sediments derived from mafic rocks of the Hercynian basement. This, in turn, implies that the basement was exposed during middle Cretaceous. 相似文献
12.
Geochemical and mineralogical investigations have been carried out on laterite profiles developed in the Lake Sonfon Au district of northern Sierra Leone. The area is underlain by Archean metavolcanics and constitutes part of the Sula Mountains greenstone belt, which is mineralized in Au. Extensive lateritization has affected the rocks of this region, resulting in a profile which from bottom to top consists typically of a decomposed bedrock zone, a pisolitic laterite layer and a duricrust layer. Both the pisolitic and duricrust layers of the laterite are sometimes punctuated by lenses of ironstones containing high amounts of Cu, Zn, Ni, Co and Ce. Gold occurs as small grains within the heavy mineral fraction recovered from the decomposed rock zones and pisolitic layers of the profiles and also in gravels of streams draining the area. The mineralogy of the duricrust and pisolitic layers is dominated by goethite, gibbsite and quartz, with minor amounts (<5% by volume) of ilmenite, magnetite, haematite, rutile and kaolinite. The kaolinite content increases towards the decomposed rock zone, where talc, vermiculite and other layer lattice silicates become abundant. The heavy-mineral fraction of stream sediments is composed essentially of ilmenite, magnetite, haematite, and traces of rutile, zircon, tourmaline and Au. The Au grains are often characterized by a 10–200-μm-wide rim having a much lower content of Ag (0.3 wt.% or lower) than the grain interior (about 5 wt.% on average). Dissolution effects are also observed on the grain surfaces. It is considered that Au derived from the amphibolite parent rock is dissolved, transported, and redeposited during laterization.The duricrust cover of the laterite profiles is characterized by high contents of Fe2O3 (ca. 60 wt.%) and Al2O3 (ca. 32wt.%) and low content of SiO2 (ca. 9 wt.%). In comparison, the pisolitic layer is higher in SiO2 (ca. 18 wt.%) as well as a slightly higher in Al2O3 (ca. 34 wt.%). Lateritic weathering has resulted in the removal of CaO, Na2O, MgO and SiO2, with relative enrichment of Fe2O3 and Al2O3. The geochemical distribution of the trace elements in the laterite profiles can be related to the occurrence of the auriferous mineralization. The significance of these observations is discussed in relation to the origin of the lateritic Au and the role of the associated trace elements as indicators of the mineralization. 相似文献
13.
Karstic bauxite deposits are widespread in Central Guizhou Province, SW China, and high-grade ores are frequently sandwiched with overlying coal and underlying iron-rich layers and form a special “coal–bauxite–iron” structure. The Lindai deposit, which is one of the most representative karstic bauxite deposits in Central Guizhou Province, was selected as a case study. Based on textural features and iron abundances, bauxite ores in the Lindai deposit are divided into three types of ores, i.e., clastic, compact, and high-iron. The bauxite ores primarily comprise diaspore, boehmite, kaolinite, illite, and hematite with minor quartz, smectite, pyrite, zircon, rutile, anatase, and feldspar. The Al2O3 (53–76.8 wt.%) is the main chemical contents of the bauxite ore samples in the Lindai district, followed by SiO2, Fe2O3, TiO2, CaO, MgO, S, and P etc. Our geological data on the Lindai deposit indicated that the ore-bearing rock series and its underlying stratum have similar rare earth elements distribution pattern and similar Y/Ho, Zr/Hf, and Eu/Eu1 values; additionally, all ore-bearing rock samples are rich in MgO (range from 0.16 wt.% to 0.68 wt.%), and the plots of the dolomites and laterites lie almost on or close to the weathering line fit by the Al-bearing rocks in Zr vs. Hf and Nb vs. Ta diagrams; suggesting that the underlying Middle Cambrian Shilengshui Formation dolomite is the parent rock of bauxite resources in the Lindai district.Simulated weathering experiments on the modern laterite from the Shilengshui Formation dolomite in the Lindai bauxite deposit show that hydrogeological conditions are important for karstic bauxite formation: Si is most likely to migrate, its migration rate is several magnitudes higher than those of Al and Fe under natural conditions; the reducing inorganic acid condition is the most conducive to Al enrichment and Si removal; Fe does not migrate easily in groundwater, Al enrichment and Fe removal can occur only in acidic and reducing conditions with the presence of organic matter.The geological and experimental studies show that “coal–bauxite–iron” structure in Lindai deposit is formed under certain hydrogeological conditions, i.e., since lateritic bauxite or Al-rich laterite deposited upon the semi-closed karst depressions, Si can be continuously removed out under neutral/acidic groundwater conditions; the coal/carbonaceous rock overlying the bauxitic materials were easily oxidized to produce acidic (H2S, H2SO4, etc.) and reductant groundwater with organic materials that percolated downward, resulting in enrichment of Al in underlying bauxite; it also reduced Fe3+ to its easily migrating form Fe2+, moving downward to near the basal carbonate culminated in precipitating of ferruginous (FeS2, FeCO3, etc.) strata of the “coal–bauxite–iron” structure. Thus, the bauxitic materials experienced Al enrichment and Si and Fe removal under above certain hydrogeological conditions forming the high-quality bauxite. 相似文献
14.
Iron–nickel-laterite deposits in the Balkan Peninsula and Turkey, located in the Mirdita–Sub-Pelagonian and Pelagonian geotectonic zones, extending into the Anatolides zone are a major source of nickel. Repeated marine transgression and regression, and the multistage development of allochthonous laterite deposits by re-working and re-deposition in a shallow sea environment are demonstrated by the alternation of Fe–Ni-laterite layers within marine sequences.Geochemical study of these Fe–Ni laterite deposits shows that arsenic contents are generally low, ranging from less than 2 to a few tens of ppm. However, in the Aghios Ioannis deposit, Lokris, Central Greece As varies significantly and attains values up to 0.26 wt.% As and in the Gordes deposit of W. Turkey, the As content ranges from 0.004 to 1.07 wt.% As (average 0.34), reaching values up to 1.94 in the hematite zone. Investigation of the mineral chemistry (SEM-EDS) shows that goethite is the main host of As, ranging between 0.5 and 1.2 wt.% As2O3 in the Aghios Ioannis deposit, and between 1.2 to 6.9 wt.% As2O3 in the Gordes deposit, whereas, in co-existing calcite As was not detectable. Goethite occurs in fine-grained porous and concretionary, concentric textures. As values are higher in concretionary goethite. Positive correlation (r > 0.74) between As and Al2O3, TiO2 and ∑ REE contents in the laterite deposits of Greece, coupled with the As-enrichment only in certain laterite deposits points to post depositional As-enrichment.Assuming that high pH facilitates the adsorption of As by goethite, due to its high surface area and low values of the activation energy of adsorption (literature data) As-adsorption by goethite is considered to play an important role in its retention. Elevated As-contents in goethite (Fe-oxides) in Fe–Ni-laterites of Greece and Turkey, due to its absorption capacity, are considered to be of particular significance in the remediation of aquifer and soil contamination rather than being a source of environmental risk. 相似文献
15.
以光薄片观察、粉晶X射线衍射分析等多种方法为手段,对靖西县三合铝土矿的硬水铝石和三水铝石的矿物特征进行研究,并探讨其成因机制.分析发现矿石主要由铝矿物、粘土矿物、铁矿物、钛矿物和石英等组成,这些矿物主要以细小微粒或单矿物集合体赋存于矿体中.其中硬水铝石和三水铝石是最主要的铝矿物.硬水铝石主要存在于沉积型铝土矿和堆积型铝土矿矿石中,三水铝石与硬水铝石伴生,主要赋存于堆积铝土矿矿层红土中.研究认为本区三水铝石主要为表生条件下,含铝母岩经红土化风化作用形成,硬水铝石主要为三水铝石经变质作用脱水形成,形成硬水铝石的三水铝石是地质历史上含铝母岩红土化作用形成的. 相似文献
16.
Biotite is a common constituent of silicate bedrock. Its weathering releases plant nutrients and consumes atmospheric CO2. Because of its stoichiometric relationship with its transformational weathering product and sensitivity to botanical activity, calculating biotite weathering rates using watershed mass-balance methods has proven challenging. At Coweeta Hydrologic Laboratory the coupling of biotite to its transformational weathering product is only valid if the stoichiometric relationship for the two phases is known; this relationship is unlikely layer-for-layer. Rates of biotite weathering and transformation of its secondary weathering product at the Coweeta Hydrological Laboratory are comparable with other Appalachian watersheds. The magnitude and sign of the difference between field- and laboratory-determined biotite weathering rates are similar to those of other silicate minerals. The influence of major-cation proportions in biomass on the rates of biotite weathering and transformational weathering product is greatest for watersheds with high biomass aggradation rates. The watershed with the lowest bedrock reactivity and highest flushing rate yielded the highest gibbsite formation rate of ~500 mol ha?1 year?1 and lowest kaolin-group mineral formation rates of 4–78 mol ha?1 year?1. The kaolin-group mineral formation rate increases as bedrock reactivity increases and flushing rate decreases to a maximum of ~300 mol ha?1 year?1, with a similar minimum gibbsite formation rate. The relative differences in bedrock reactivity and flux of water through Coweeta Hydrological Laboratory watersheds studied appear to be invariant over geologic timescales. 相似文献
17.
河南铝土矿矿物成因及其演化序列 总被引:2,自引:0,他引:2
[摘 要]豫西铝土矿是我国喀斯特型铝土矿的典型代表。本文选取豫西典型的喀斯特型铝土矿为研究对象,通过XRD 分析、扫描电镜-能谱分析、电子探针分析和差热分析多种手段,探测铝土矿的物质组成及其赋存状态,并且分析其矿物成因,总结矿物演化序列。研究显示,豫西铝土矿的主要矿物成分包括硬水铝石、伊利石、锐钛矿、高岭石、针铁矿、赤铁矿、金红石等。硬水铝石主体为简单结晶成因。伊利石主体为风化过程中产物,部分为后期硬水铝石硅质交代的结果。锐钛矿和硬水铝石同期结晶形成于还原环境下。大部分高岭石形成于陆源期风化阶段,少部分为后期硬水铝石硅化转变形成。针铁矿和赤铁矿形成于两个阶段,第一阶段为成矿前风化作用形成的铁质风化壳;第二阶段为铝土矿成岩晚期出现了一期铁质流体活动形成了大量的赤铁矿和针铁矿。重砂矿物金红石和锆石等主要是母岩风化作用的残留物。豫西铝土矿中矿物形成演化可归纳为如下五个阶段:陆源期、同生期、成矿期、成矿后期和表生期。 相似文献
18.
M. Nakagawa M. Santosh S. Yoshikura M. Miura T. Fukuda A. Harada 《Gondwana Research》2006,9(4):530-538
The kaolin deposits at Melthonnakkal and Pallipuram mines form part of the Warkalli Formation belonging to the Tertiary sequence in southern Kerala and occur at the boundary between the Tertiary sequence and Precambrian granulite facies metapelites (khondalites). The sedimentary clays are composed mainly of kaolinite, quartz and gibbsite. XRD and SEM studies have revealed that kaolinite is well-crystallized variety and the platy crystals are scarcely broken in the sedimentary clays. These sedimentary kaolins are considered to have been formed by intense tropical weathering of the khondalites, and subsequently transported and deposited with high organic input into lakes near the weathering crust over the basement rock. Besides, the surficial parts of the sedimentary deposits are extensively lateritized with the formation of goethite and hematite by Quaternary tropical weathering processes. 相似文献
19.
Genesis of superimposed hypogene and supergene Fe orebodies in BIF at the Madoonga deposit, Yilgarn Craton, Western Australia 总被引:1,自引:0,他引:1
The Madoonga iron ore body hosted by banded iron formation (BIF) in the Weld Range greenstone belt of Western Australia is a blend of four genetically and compositionally distinct types of high-grade (>55 wt% Fe) iron ore that includes: (1) hypogene magnetite–talc veins, (2) hypogene specular hematite–quartz veins, (3) supergene goethite–hematite, and (4) supergene-modified, goethite–hematite-rich detrital ores. The spatial coincidence of these different ore types is a major factor controlling the overall size of the Madoonga ore body, but results in a compositionally heterogeneous ore deposit. Hypogene magnetite–talc veins that are up to 3 m thick and 50 m long formed within mylonite and shear zones located along the limbs of isoclinal, recumbent F1 folds. Relative to least-altered BIF, the magnetite–talc veins are enriched in Fe2O3(total), P2O5, MgO, Sc, Ga, Al2O3, Cl, and Zr; and depleted in SiO2 and MnO2. Mafic igneous countryrocks located within 10 m of the northern contact of the mineralised BIF display the replacement of primary igneous amphibole and plagioclase, and metamorphic chlorite by hypogene ferroan chlorite, talc, and magnetite. Later-forming, hypogene specular hematite–quartz veins and their associated alteration halos partly replace magnetite–talc veins in BIF and formed during, to shortly after, the F2-folding and tilting of the Weld Range tectono-stratigraphy. Supergene goethite–hematite ore zones that are up to 150 m wide, 400 m long, and extend to depths of 300 m replace least-altered BIF and existing hypogene alteration zones. The supergene ore zones formed as a result of the circulation of surface oxidised fluids through late NNW- to NNE-trending, subvertical brittle faults. Flat-lying, supergene goethite–hematite-altered, detrital sediments are concentrated in a paleo-topographic depression along the southern side of the main ENE-trending ridge at Madoonga. Iron ore deposits of the Weld Range greenstone belt record remarkably similar deformation histories, overprinting hypogene alteration events, and high-grade Fe ore types to other Fe ore deposits in the wider Yilgarn Craton (e.g. Koolyanobbing and Windarling deposits) despite these Fe camps being presently located more than 400 km apart and in different tectono-stratigraphic domains. Rather than the existence of a synchronous, Yilgarn-wide, Fe mineralisation event affecting BIF throughout the Yilgarn, it is more likely that these geographically isolated Fe ore districts experienced similar tectonic histories, whereby hypogene fluids were sourced from commonly available fluid reservoirs (e.g. metamorphic, magmatic, or both) and channelled along evolving structures during progressive deformation, resulting in several generations of Fe ore. 相似文献
20.
论我国铝土矿床类型及其红土化风化壳形成机制问题 总被引:3,自引:0,他引:3
中国铝土矿床98%以上为古风化壳型,少量属红土型.前者分六个亚型,即铝硅酸盐岩古风化壳原地残积(Ⅰa);碳酸盐岩古风化壳准原地堆积(Ⅰb)、异地堆积(Ⅰc)以及异地沉积(湖水)(Ⅰd);Ica古风化壳异地沉积(海相);Ⅰf碳酸盐岩古风化壳准原地堆积(或沉积)-现代喀斯特堆积等六个亚型.ⅠⅠb、Ⅰc三亚型矿床在大气条件下就位,就位以后继续红土化,为此矿层很少层理;矿石中常有渗流管、渗流凝胶.Ⅰd、Ⅰe亚型在水体中沉积,有层理,无渗流管、渗流凝胶.所有铝土矿床的矿物组成及矿石结构、构造都是含铝岩石红土化风化作用易溶物淋失,难溶的钛、铝、铁质残留的风化壳铝土物质;无水体中结构、构造特征;δ18O‰及δD‰值证为风化物;除Ⅰc外均无动物化石及其碎屑. 相似文献