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31	Petrology, geochronometry and economic geology : the Zeta tin-silver prospect, Arsenic Ridge, west-central Yukon (115P/14 and 116A/03) Abercrombie, Shirley May January 1990 (has links) Arsenic Ridge is located in the northwestern part of the Lost Horses batholith, Syenite Range, Yukon Territory. This area is within the Omineca Crystalline Belt of the Canadian Cordillera. North American miogeoclinal rocks of the upper Precambrian to Lower Cambrian Grit Unit were northwardly thrust onto Ordovician to Silurian Road River Formation during the Late Triassic to Early Jurassic arc-continent collision. Small mid-Cretaceous (83 to 100 Ma, K-Ar on biotite), epizonal felsic intrusions were emplaced in radiogenic Sr-enriched metasedimentary rocks of the ancient continental margin (pericratonic sedimentary prism). The mid-Cretaceous (syenite phase, 87+3 Ma, K-Ar on biotite; granite phase, 95+3 Ma, K-Ar on biotite) Lost Horses batholith is a circular, S-type, composite pluton within the Selwyn Basin. The Selwyn Basin is an epicontinental trough partially bounded on the west by the Cassiar Platform and on the east and northeast by carbonate rocks of the MacKenzie Platform. S-type plutons are a product of Hercynotype arc-continental collisional tectonics. The zoned intrusive rocks along Arsenic Ridge, from core to rim, have been classified as tourmaline orbicular granite, granite, quartz syenite and syenite. With increasing SiO₂ : (1) the major elements--Al₂O₃ , FeO, MgO, CaO, TiO₂, MnO and P₂O₅--tend to decrease,(2) trace elements--Zr, V, Sr, Ni, and Ba--are characterized by extreme depletions, and (3) the trace element, Rb, is slightly enriched. The syenite is alkaline whereas the quartz syenite, granite, granite dyke, and tourmaline orbicular granite are sub-alkaline. Magmatic differentiation of the pluton is demonstrated by a decreasing trend of (Na₂O + K₂O) and TiO₂ with increasing SiO₂, and by an increasing Rb content with a decrease in Ba and Sr. The estimated partial pressure of water during formation of the Lost Horses granite melt is broadly estimated as >10 kbar. Electron microprobe traverses across orthoclase megacryst cores and rims identified a concentration of albite lamellae in the rim and barium, strontium and calcite rich cores. The latter is indicative of a melt undergoing progressive depletion of barium by fractional crystallization. The age of the batholith is early Late Cretaceous, approximately 97 Ma. This was determined from early Late Cretaceous dates of 95+3 Ma from K-Ar on biotite and 88+4 Ma from K-Ar on a hornblende, and a late Early Cretaceous date of 101+6 Ma from a whole rock-mineral (biotite, hornblende, total feldspar) Rb-Sr isochron. Initial strontium ratios for the granitic rocks along Arsenic Ridge are about 0.712 suggesting that radiogenic strontium was derived mainly from melting and/or assimilation of old sialic crust during magma genesis. The model Rb-Sr age, TUR, for the granitic rocks on Arsenic Ridge is 238 Ma. This indicates that a dominantly upper mantle source is unlikely. Pb-Pb isotope ratios for the zoned plutonic rocks, the surrounding sediments and the ore mineral separates plot between the pericratonic and Bluebell curves (from 0 Ma to 140 Ma mixing lines) indicating that the lead is a mix of upper crust and lower crust sources. Lead sulphide analyses from the Zeta prospect, Tombstone Range and the Keno-Galena Hill areas are indistinguishable from the feldspar rock lead. This shows that the lead source for these vein deposits is the surrounding plutons and not the surrounding sedimentary rocks. The least radiogenic lead has a model age of about 100 Ma. Nd/Sm and Nd analyses indicate that Arsenic Ridge granitic rocks were derived from, or assimilated, old crustal rocks whose Sm/Nd had been lowered at the time of separation from CHUR. Nd ratios for the granite and the feldspar megacrysts are all very close to 0.51210. The model Sm-Nd age, TDM , for a granite along Arsenic Ridge is 1.26 Ga. Approximate percentages of continental crust and mantle incorporated in the melt were calculated. If the contamination is upper crustal in origin then there was a maximum of 30% mantle incorporated in the melt. No mantle component is needed if the contamination source is lower crust. However, since granite ¹⁴³Sm/¹⁴⁴Nd ratios are close to the average continental crust ratio, the origin is upper crust with a small mantle component. ¹⁴³Nd/¹⁴⁴Nd and ⁸⁷Sr/⁸⁶Sr ratios for the granitic rocks from the Lost Horses batholith plot in the Phanerozoic quadrant of Faure (1986) and are similar to values from the Sierra Nevada batholith. Epsilon values of Nd and Sr suggest the granite is S-type which agrees with the field, petrographic and chemical evidence. The granite plots within the field for miogeoclines as determined by Farmer and DePaolo (1983 ). The Zeta tin - silver greisen vein prospects lie in both the Ordovician - Silurian metasediments of the Road River Group at the northeastern contact, and in the zoned, mid-Cretaceous Lost Horses batholith. Mineralization on the property occurs in two forms: (1) cassiterite bearing greisen veins in hornfelsed quartzite, and (2) greisen veins (sulphide and quartz with minor tourmaline, and tourmaline and quartz with minor sulphide in granitic rocks). K-Ar muscovite dating of the sericitic cassiterite greisen (87.0+3.0 Ma), indistinguishable from the K-Ar biotite date for the syenite phase of the batholith (86.8+2.7 Ma), establishes a genetic relationship between the two. The following four-stage model describes the evolution of the Lost Horses batholith: stage 1, initial melting, stage II, melt accumulations and assimilation, stage III, diapiric rise and chemical differentiation (fractional crystallization), and stage IV, magmatic hydrothermal. This last stage generated tin-silver vein and greisen mineralization. The source for this lithophile mineralization and associated S-type granitic rock is dominantly from a sialic clastic wedge with upper crustal geochemical characteristics. / Science, Faculty of / Earth, Ocean and Atmospheric Sciences, Department of / Graduate Petrology -- Yukon Territory Geochronometry -- Yukon Territory Geology, Economic -- Yukon Territory
32	Optimization of delineation investment in mineral exploration Bilodeau, Michel L., 1948- January 1978 (has links) No description available.
33	元朗地區的土地分析及評估. / Yuanlang di qu de tu di fen xi ji ping gu. January 1987 (has links) 嚴南海. / 複寫本. / 附錄: Geotechnical area study: north west. / Thesis (M.A.)--香港中文大學硏究院地理系. / Fu xie ben. / Fu lu: Geotechnical area study: north west. / New Territories: terrain classification map. / Yan Nanhai. / Thesis (M.A.)--Xianggang Zhong wen da xue yan jiu yuan di li xi. / Chapter 第一章 --- 緒論 / Chapter 1.1 --- 理論依據 / Chapter 1.1.1 --- 土地分析的性質 / Chapter 1.1.2 --- 土地分析的概念 / Chapter 1.1.3 --- 土地分析的發展 / Chapter 1.1.4 --- 土地分類的方向 / Chapter 1.1.5 --- 土地分析的方法 / Chapter 1.1.6 --- 土地評估的性質 / Chapter 1.1.7 --- 土地評估的方法 / Chapter 1.2 --- 研究目的 / Chapter 1.3 --- 研究意義 / Chapter 第二章 --- 研究區域與研究方法 / Chapter 2.1 --- 研究區自然環境概況 / Chapter 2.1.1 --- 位置 / Chapter 2.1.2 --- 地質 / Chapter 2.1.3 --- 氣候 / Chapter 2.1.4 --- 土壤 / Chapter 2.1.5 --- 植被 / Chapter 2.2 --- 研究方法 / Chapter 2.2.1 --- 資料搜集及處理 / Chapter 2.2.2 --- 統計分析 / Chapter 2.3 --- 研究限制 / Chapter 第三章 --- 元朗地區的土地特徵 / Chapter 3.1 --- 土地條件 / Chapter 3.1.1 --- 坡度 / Chapter 3.1.2 --- 土地要素 / Chapter 3.1.3 --- 侵蝕不穩性 / Chapter 3.1.4 --- 地表物質 / Chapter 3.2 --- 土地特徵的相互關係 / Chapter 3.2.1 --- 土地要素與坡度 / Chapter 3.2.2 --- 土地要素與侵蝕不穩性 / Chapter 3.2.3 --- 土地要素與地表物質 / Chapter 3.2.4 --- 坡度與侵蝕不穩性 / Chapter 3.2.5 --- 坡度與地表物質 / Chapter 3.2.6 --- 地表物質與侵蝕不穩性 / Chapter 3.3 --- 岩性與土地特徵 / Chapter 3.3.1 --- 岩性與坡度的關係 / Chapter 3.3.2 --- 岩性與侵蝕不穩性的關係 / Chapter 3.3.3 --- 岩性與地表物質的關係 / Chapter 3.4 --- 小結 / Chapter 第四章 --- 土地利用與土地特徵的關係 / Chapter 4.1 --- 土地利用分佈概況 / Chapter 4.2 --- 各土地特徵對土地利用的影響 / Chapter 4.2.1 --- 土地利用與坡度 / Chapter 4.2.2 --- 土地利用與土地要素 / Chapter 4.2.3 --- 土地利用與侵蝕不穩性 / Chapter 4.2.4 --- 土地利用與地表物質 / Chapter 4.2.5 --- 小結──農業用地與城市用地的土地條件差異 / Chapter 第五章 --- 元朗地區的土地分區與評估 / Chapter 5.1 --- 元朗地區的土地分區 / Chapter 5.1.1 --- 聚類分析結果 / Chapter 5.1.2 --- 判別分析結果 / Chapter 5.2 --- 元朗地區七個土地分區的土地利用潛力評估 / Chapter 5.2.1 --- 土地利用潛力分類 / Chapter 5.2.2 --- 各分區的土地利用潛力及發展方向 / Chapter 5.3 --- 元朗地區社區發展的土地潛力 / Chapter 5.3.1 --- 社區發展上的地貌限制 / Chapter 5.3.2 --- 元朗地區社區發展的空間取向 / Chapter 5.4 --- 小結 / Chapter 第六章 --- 結論 / 參考文獻 / Chapter 附錄： --- Geotechnical Area Study──North West New Territories: Terrain Classification Map Geology Geology--China--Hong Kong Geology, Economic Geology, Economic--China--Hong Kong Soils Soils--China--Hong Kong Land use Land use--China--Hong Kong
34	The development and some practical applications of a statistical value distribution theory for the Witwatersrand auriferous deposits Ross, F. W. J. January 2015 (has links) No description available. Gold ores--South Africa--Witwatersrand. Ores--Sampling and estimation. Geology, Economic.
35	An economic, metamorphic, structural and geochemical study of the Isle aux Morts prospect, southwest Newfoundland / O'Neill, Patrick P., January 1985 (has links) Thesis (M.Sc.) -- Memorial University of Newfoundland. / Typescript. Bibliography : leaves 198-210. Also available online.
36	Geology, geochemistry, geochronology and genesis of granitoid clasts in breccia-conglomerates, MacLean extension orebody, Buchans, Newfoundland / Stewart, Peter William, January 1985 (has links) Thesis (M.Sc.) -- Memorial University of Newfoundland. / Typescript. Bibliography : leaves 266-289. Also available online.
37	The economic geology of the Okiep copper deposits, Namaqualand, South Africa Gadd-Claxton, D L 04 April 2013 (has links) The Okiep Copper District situated in the north-western Cape Province, covers some 3 000 km and is the oldest mining area in the Republic of South Africa. The O'okiep Copper Company Limited commenced production in 1940 with a proven ore reserve of 9 million tons at 2,45 % cu. Production since 1940 and present ore reserves total some 93 million tonnes at 1,08 % Cu. The rocks comprising the Okiep Copper District are of Proterozoic age and have been subdivided into a meta-volcanosedimentary succession, intruded by various sub-horizontally emplaced granitoid intrusions. The various intrusions occurred at different stages relative to the main structural and metamorphic events. The copper deposits are confined to basic rocks which are the youngest major group of intrusives in the District. They occur as swarms of generally easterly-trending, steep northdipping, irregular dyke-like bodies consisting of diorite, anorthosite and norite. The dominant silicate constituents are andesite ranging to labradorite, hypersthene, biotite and phlogopite. Copper sulphides are preferentially associated with the more basic varieties. The copper sulphides are mainly chalcopyrite, bornite and subsidiary chalcocite. The copper content of the basic rocks is erratic ranging over small distances from a mere trace to several percent. Emplacement of the cupriferous basic rocks is predisposed to a large extent by enigmatic structural features locally referred to as steep structures. The most common manifestation of steep structure deformation is typically a narrow antiformal linear feature along which continuity of the country rocks has been interrupted by piercement folding and shearing. In places, pipelike bodies of megabreccia occur along steep structures, and also act as hosts to the basic rock. Areas of steep structure are thus prime exploration targets, due to their close spatial association with the cupriferous basic rocks. Exploration techiques employed in the Okiep Copper District in~ elude regional and detailed geological mapping, geophysical surveys utilizing magnetic, gravimetric and electrical methods, as well as limited application of soil and stream-sediment geochemistry. Final evaluation is by surface and underground diamond drilling. Exploration has to date discovered 18 new mines with individual ore reserves ranging from 200 000 to 37 000 000 tonnes. All are underground operations, and the sub-level open stoping method of mining is standard. Copper ores -- South Africa -- Okiep Okiep (South Africa)
38	Geological and mineral economic evaluation and assessment of the Permian Karoo Supergroup coal assets owned by Eyesizwe Coal (Pty) Ltd, a Black empowerment company, South Africa Wakerman, Boguslaw Wojciech 23 April 2014 (has links) D.Phil. (Geology) / Please refer to full text to view abstract Coal - Geology - South Africa Coal mines and mining - South Africa Geology, Economic - South Africa
39	The Lumwana Copper Prospect in Zambia McGregor, James Archibald January 1965 (has links) The Lumwana copper orebody is situated 170 miles west of the Copperbelt. It is stratiform and occurs in schists regarded as part of the Katanga System older than the lower-most Copperbelt quartzite. The discovery of copper at the Lumwana Prospect was a text book example of the success of the R.S.T. Mines Services Limited prospecting techniques. These include partial geochemical analyses of soil and drainage samples, pitting, drilling and radiometric, self potential, magnetic, resistivity and induced polarization methods of geophysical exploration. The copper-bearing formations at the Lumwana Prospect occur in the inverted limb of a great recumbent fold within the Mombezhi Dome. Three periods of folding are recognized from the study of regional foliations and lineation, and the attitude of fold elements in individual folds. Each period of folding is regarded as a major pulse in the Lufilian Orogeny. The first-formed folds are isoclinal and have axial planes which strike at 160°, and dip southwest at 15°; the plunge is 11° in a direction 212° . The formation of first folds was accompanied by thrust faulting and the development of nappe structures including the great Lumwana recumbent fold. The second folds have axial planes which strike at 170° and dip west at 44°, the plunge is 12° in a direction of 192°, and the folds tend to be overturned. The third folds cut across the earlier folds at variable angles, they are overturned to the north and have axial planes which dip gently to the south. The formation of third folds was such that northward-acting stress was rotated from southeast to southwest, and relaxation of this stress resulted in the development in competent strata of joints which strike at 120° and dip steeply. At the Lumwana Prospect the northward-acting Lufilian stress is thought to have been resolved into eastward acting stress during first and second folding as a result of compression near the centre of the Lufilian Arc. The third folds are the normal Lufilian folds sub-parallel to the Lufilian Arc. Normal faulting and intrusion of gabbro along planes of these faults and the earlier thrust faults eccurred in a post-Lufilian tensional phase. In recent times warping of the formations at Lumwana has occurred on east-west axes. Statistical examination of chemical data on fifty-four composite samples of mineralized rock from drill-holes reveals that the distribution of copper, iron and sulphur is related to that of potash and soda. These relationships can be explained on sedimentological grounds since the examination of the distribution of soda and potash in these and other horizons yields no evidence of metasomatism in the mineralized horizon. Intrusive into the mineralized schists, though not found in the ore, are thin amphibolites and a large serpentinite which contains relict olivine and bronzite. This is the first recorded occurrence of ultrabasic rocks in the Lower Roan Group of the Katanga System in this part of Zambia. Study of all formations at the Lumwana Prospect reveals that they have been metamorphosed in the epidote-amphibolite facies of regional metamorphism. Mineral assemblages indicative of the amphibolite facies are found in sheared rocks, and metamorphism in competent parts of the Upper Roan-Mwashia has been confined to the greenschist facies. Temperatures of metamorphism are estimated to have been between 250° and 280°C, and pressures are likely to have exceeded 6 kilobars. Evidence of metasomatism, absent in the Lower Roan, is found in the examination of the Upper Roan-Mwashia formations. Metasomatism includes scapolitization and albitization and is related to the intrusion of gabbro into these sediments, but does not necessarily involve exogenous material. The sulphide minerals identified are bornite, chalcocite, digenite, covellite, chalcopyrite, cubanite, valleriite, carrollite, pyrite and pyrrhotite. Intergrowths of these minerals have resulted from metamorphism at temperatures slightly in excess of 235°C. The copper sulphides are distributed zonally in the orebody with chalcocite- bornite ore where the mineralized schist is thin, and chalcopyrite- cubanite-pyrite ore where it is thick. Vertically the body contains horizons with sulphides relatively rich in copper at the top and bottom, and an intermediate zone with sulphides leaner in copper. This zonal distribution is considered to be evidence for syngenetic deposition of copper during successive cycles of transgression and regression. Ore genesis at Lumwana is closely related to genesis of the Copperbelt and Katanga orebodies. The Zambia-Katanga province is considered to have been enriched in copper epigenetically prior to the formation of the present-day orebodies. Reworking of these cupriferous rocks and some early-formed syngenetic deposits of which Lumwana is one, is considered to have played a major role in producing the present-day copper orebodies. Copper -- Zambia Copper ores -- Zambia -- Analysis Copper mines and mining -- Zambia Mineralogy -- Zambia Geology, Economic -- Zambia
40	Risk analysis assessment of the influence of geological factors on exploration and mining investment alternatives : development of a microcomputer simulation model Mallinson, Clyde A January 1987 (has links) A microcomputer risk analysis model is developed and used in an exploration - delineation simulation to analyse in particular the effects of geological factors on exploration mining investment alternatives. Analysis of results indicate that geological parameters can have profound effects on such investment alternatives and that the role of the geologist in determining and evaluating the significance of the various geological factors is critical. Simulation examples highlight some of the key geological parameters and show how changes in these parameters influence both the expected mean results and the standard deviations of such means. The risk analysis model provides an ideal means of conveying the importance of the different geoiogical factors on exploration - delineation - mining investment alternatives and may be used as a geological education aid Geology, Economic Risk assessment -- Computer simulation Prospecting -- Computer simulation

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