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1.
王留海 《矿物岩石》1991,11(4):51-56
本文分析了大洪山区钾镁煌班岩中的矿物特征,利用造岩矿物和副矿物的电子探针分析结果与西溴含金刚石钾镁煌斑岩中相应矿物进行对比。并用特征副矿物镁铝榴石、铬铁矿的化学成分作Cr_2O_3—CaO图,Cr_2O_3-MgO图,利用Cr/(Cr+Al)的比值参数,判别岩体的含矿性。认为该区钾镁煌斑岩目前虽然尚未发现金刚石,但成矿有利因素较多。  相似文献   

2.
金伯利岩中的镁铝榴石是寻找金刚石的重要指示矿物。镁铝榴石的Cr2O3、CaO等氧化物含量及其颜色、折光率等物理光学性质可作为这种石榴石的标型特征。 本文将山东、辽宁等地金伯利岩中的石榴石的电子探针分析结果按分子数配分的方法计算了端员分子百分数及其他化学参数。用MPV—1显微光度仪测定了石榴石的透射率色散值,通过计算求得颜色指数。按Dawson等人的分类,本次研究样品以铬镁铝榴石为主,其次是低钙-铬镁铝榴石、钙铬-镁铝榴石和镁铬-钙铬-镁铝榴石;钛镁铝榴石和钙镁铝-铁铝榴石等少量。作者用铬、钙、镁三组份数绘制了石榴石与金刚石关系判别图解,分为五个区(A、B、C、D、E)、落入A区的低钙-铬镁铝榴石、铬镁铝榴石和钙铬-镁铝榴石等与金刚石的形成关系最密切。  相似文献   

3.
在红外光谱有关镁铝榴石中微量结构水的研究基础上,运用质子探针分析方法系统研究了辽宁50号金伯利岩管中粗晶镁铝榴石Ni、Zn、Ga、Sr、Y、Zr、Pb等微量元素的含量。根据镁铝榴石中微量元素Ni含量地质温度计,计算该岩管中镁铝榴石粗晶的形成温度,对比研究了不同含矿性的金伯利岩中粗晶镁铝榴石形成温度范围的异同,并探讨了该方法运用于金刚石找矿勘查的可能性;讨论了含结构水镁铝榴石的形成温度范围及其意义,并结合其它微量元素分析资料,探讨了镁铝榴石中微量结构水与地幔交代作用之间的成因联系。  相似文献   

4.
镁铝榴石是金伯利岩中最重要的标型矿物,在金刚石矿床普查中具有重大意义.文中利用了钛分异系数,对镁铝榴石氧化物成分作了对应分析.同时按其颜色成分作了聚类分析,划分了各种石榴石成分及镁铝榴石颜色系列.研究了镁铝榴石结晶机制及岩浆分异作用,结合金伯利岩的判别分析及地质构造特征的分析,作出了镇远施秉金伯利岩群含矿性很差,远景不大的结论.  相似文献   

5.
金刚石中的矿物包裹体   总被引:1,自引:0,他引:1  
董振信 《矿物岩石》1991,11(3):64-71
山东、辽宁金伯利岩区金刚石中的矿物包裹体是单晶相及多晶相的。大部分原生矿物包裹体为橄榄石,也有铬尖晶石、镁铝榴石、单斜辉石、斜方辉石、自然铁、针镍矿、柯石英、方解石及石墨。云母为后生包裹体矿物。橄榄石包裹体矿物富含Fo及Cr_2O_3。镁铝榴石矿物包裹体为紫红色,含Cr_2O_3,MgO及镁铬榴石分子高,形成压力为7.5GPa。单斜辉石包裹体矿物为绿色,形成温度和压力分别为:1531℃和4.5GPa。铬尖晶石包裹体矿物含Cr_2O_3及Cr/(Cr+Al)比值高,而含Al_2O_3低。柯石英的SiO_2含量为99.15%。自然铁含有少量的Co,Ni。针镍矿在金刚石中较常见。在橄榄石矿物包裹体内,见有方解石产出,其为同生矿物包裹体。  相似文献   

6.
我国金伯利岩及其他岩类中的镁铝榴石   总被引:1,自引:0,他引:1  
镁铝榴石是金伯利岩的副矿物,也常产于橄榄岩、榴辉岩、偏碱性玄武岩、超基性煌斑岩中。因此,确定金伯利岩中镁铝榴石的标型特征,是金刚石找矿和评价工作中的一个重要课题。 本文研究了我国常马庄、头道沟、马坪、彭家榜、土门等地区金伯利岩中镁铝榴石的物理性质和化学特征,并与其他岩类中的镁铝榴石作了对比,探讨了镁铝榴石的标型特征及其与含矿性的关系。  相似文献   

7.
镁铝榴石是金刚石的常见伴生矿物,由于经常在自然重砂中出现,因此利用重砂法来寻找金刚石原生矿是一种有效的方法。但是镁铝榴石不仅在金伯利岩中,而且往往在某些基性、超基性、以及某些高级变质岩中出现,使找矿工作复杂化。为此,探寻与金刚石有成因联系的镁铝榴石和其他镁铝榴石之区别是很必要的。  相似文献   

8.
我国金伯利岩中镁铝榴石的化学成分特征及找矿意义   总被引:1,自引:0,他引:1  
镁铝榴石是金刚石的重要伴生矿物,而在许多非金伯利岩中也含有镁铝榴石,因此深入研究金伯利岩中与非金伯利岩中镁铝榴石的物理、化学特征,找出它们之间的差异进而确立金伯利岩中镁铝榴石的标型特征,对利用重砂法寻找金刚石原生矿具有重要意义。本文仅对我国已发现的金伯利岩中镁铝榴石的化学成分特征及与非金伯利岩中镁铝  相似文献   

9.
隋延辉  戚长谋 《世界地质》2003,22(4):373-375,403
对华北地台金伯利岩地球化学找矿信息提取表明:铬是判别岩体含矿与否的重要指示元素。铬的相态分属尖晶石、镁铝榴石和镁钛铁矿三类矿物族。研究得出,各矿物指示含矿的化学成分标型为:铬尖晶石Cr2O3>53%,Al2O3<11%,MgO<12%,Cr#值大于0 7。镁铝榴石Cr2O3>5%,Al2O3<19%,Cr#值大于0 2。镁钛铁矿Cr2O3>1%,MgO>11%。由于铬尖晶石相对稳定,其化学组成为提取金伯利岩找矿信息的首选对象。  相似文献   

10.
辽宁瓦房店金刚石矿区金伯利岩中的石榴石一直被当作镁铝榴石。为了确定矿区颜色复杂的石榴石种类,本文对矿区的石榴石进行了系统的采样分析,测定了112件石榴石样品的晶胞参数、50件样品的微区化学成分和40件样品的红外光谱。利用石榴石晶胞参数、红外光谱、化学成分和化学分子式方法对矿区石榴石进行分类,结果显示:晶胞参数分类法误差大,容易得出错误结论;红外图谱分类法准确度不高,只能作为参考方法;化学成分分类法太过笼统,达不到详细划分石榴石种类的目的;化学分子式分类法可把矿区的石榴石详细划分6个矿种:镁钙铁-铝铬铁榴石、镁铁钙-铝铬铁榴石、镁钙铁-铝铬榴石、镁钙-铝铬铁镁榴石、镁铁钙-铝铬榴石、镁铁钙-铝铁铬榴石,每种石榴石都充分反映了A、B离子的种类及占位特征,是4种分类方法中最为科学的方法。研究认为瓦房店金刚石矿区金伯利岩中石榴石A端元成分以Mg2+离子占位为主;B端元成分以Al3+离子占位为主。由于阳离子替代普遍,A、B端元成分复杂,瓦房店金伯利岩中不存在单纯意义上的镁铝榴石。  相似文献   

11.
中国金伯利岩中的钛铁矿   总被引:2,自引:0,他引:2  
董振信 《矿物学报》1991,11(2):141-147
本文研究了金伯利岩中,作为巨晶和粗晶,基质相矿物,与金云母、镁铝榴石、铬尖晶石等矿物的连生体,金刚石中包裹体矿物及金伯利岩地幔岩包裹体矿物产出的钛铁矿的大小,形态、皮壳及化学成分、端元组分、环带及成分变异趋势。并与其他岩类中的钛铁矿作了对比。探讨了不同产状、共生组合类型的钛铁矿的成因。指出了与金刚石紧密伴生的钛铁矿的标型特征及找矿意义。  相似文献   

12.
Based on the measurements of refractive index,specific gravity,unit cell parameter,and mineral chemistry and infrared absorption spectrum analyses of pyropes in kimberlites from China,systematic studies of the Physical properties and compositional variations of pyropes of different colors and diverse paragenetic types,within and between kimberlite provinces have been undertaken,The origin of pyropes in the Kimberlites and the depth of their formation have been discussed.Pyropes of the purple series are different from those of the orange series in physical and chemical properties,for exaple,pyropes of the puple series are higher in α0,RI,SG,Cr2O3,MgO,Cr/(Cr Al),Mg/(Mg Fe),and Mg/(Mg Ca),and lower in Al2O3,Fe2O3 FeO than those of the orange series.The classification of garnets in kimberlites from china by the Dawson and Stephens‘ method(1975) has been undertaken and clearly demonstrates that pyropes of diamond-rich kimberlites contain much more groups than those of diamond-poor,especially diamond-free kimberlites.The higher in α0,RI,SG,Cr2O(3.Cr/(Cr Al),knorringite and Cr-component the pyropes are ,the richer in diamond the kimberlites will be.The infrared absorption spectrum patterns of pyropes change with their chemical composition regularly,as reflected in the shape and position of infrared absorption peaks.Two absortpion bands at 862-901 cm^-1 will grade into degeneration from splitting and the absorption band positions of pyropes shift toward lower frequency with increasing Cr2O3 content and Cr/(Cr Al) ratio of pyropes,LREE contents of orange pyrope megacrysts are similar to those of porple pyrope macrocrysts,but the former is higher in HREE than the latter,showing their different chondrite-normalized patterns.The formation pressures of pyropes calculated by Cr-component,Ca-component,knorringite molecules of pyropes show that some pyropes of the purple series in diamondiferous kimberlites fall into the diamond stability field.but all pyropes of diamond-free kimberlites lie outside the diamond stability field.The megacrysts were formed through early crystallization of kimberlites magma at high pressure condition,the majority of the purple pyrope macrocrysts have been derived from disaggregated xenoliths but the minoirty of them appear to be fragments of the discrete megacryst pyropes,or phenocrysts.  相似文献   

13.
The Buffalo Hills kimberlites define a province of kimberlite magmatism occurring within and adjacent to Proterozoic crystalline basement termed the Buffalo Head Terrane in north-central Alberta, Canada. The kimberlites are distinguished by a diverse xenocryst suite and most contain some quantity of diamond. The xenocryst assemblage in the province is atypical for diamondiferous kimberlite, including an overall paucity of mantle indicator minerals and the near-absence of compositionally subcalcic peridotitic garnet (G10). The most diamond-rich bodies are distinguished by the presence of slightly subcalcic, chromium-rich garnet and the general absence of picroilmenite, with the majority forming a small cluster in the northwestern part of the province. Barren and near-barren pipes tend to occur to the south, with increasing proximity to the basement structure known as the Peace River Arch. Niobian picroilmenite, compositionally restricted low-to moderate-Cr peridotitic garnet, and megacrystal titanian pyrope occur in kimberlites closest to the arch. Major element data for clinopyroxene and trace element data for garnet from diamond-rich and diamond-poor kimberlites suggests that metasomatism of lithospheric peridotite within the diamond stability field may have caused destruction of diamond, and diamond source rocks proximal to the arch were the most affected.  相似文献   

14.
The author studied the grain size, shape, colour, altered coat, mineral species, chemical composition,end- member components and infrared spectra of clinopyroxenes occurring as megacryst, macrocryst andgroundmass minerals, intergrowths with pyrope and ilmenite and minerals in deep-seated xenoliths and inclu-sions in diamonds in kimberlites of China. The clinopyroxenes under study were compared with megacrystclinopyroxenes in basalts and minerals in their deep-seated xenoliths and clinopyroxenes in lamproites andminettes. The coexisting clinopyroxene-pyrope pair was studied. Besides the author also studied the origin ofclinopyroxenes in kimberlites, P-T conditions for their formation and their reflected tectonic environments ofthe kimberlite formation. He suggests that this mineral is an indicator for diamond exploration.  相似文献   

15.
《International Geology Review》2012,54(11):1680-1683
Pseudocubical convex-faceted grains of pyrope are often found in upper parts of weathered crust, in sedimentary rocks and in modern alluvium, inside and outside the Yakutian diamond fields. They are never in the diamond pipes or in dense kimberlites where pyrope maintains its normal shape. The “cuboid” shape of pyrope grains is probably due to diagenetic and solubility effects, inasmuch as their optical properties and impurities are the same as those of the “normal” pyrope.  相似文献   

16.
In the late 1990s, the Fazenda Largo kimberlite cluster was discovered in the Piauí State of Brazil. As with earlier known kimberlites in this area – Redondão, Santa Filomena-Bom Jesus (Gilbues) and Picos – this cluster is located within the Palaeozoic Parnaiba Sedimentary Basin that separates the São Francisco and the Amazonian Precambrian cratons. Locations of kimberlites are controlled by the ‘Transbrasiliano Lineament’. The Fazenda Largo kimberlites are intensely weathered, almost completely altered rocks with a fine-grained clastic structure, and contain variable amounts of terrigene admixture (quartz sand). These rocks represent near-surface volcano-sedimentary deposits of the crater parts of kimberlite pipes. By petrographic, mineralogical and chemical features, the Fazenda Largo kimberlites are similar to average kimberlite. The composition of the deep-seated material in the Fazenda Largo kimberlites is quite diverse: among mantle microxenoliths are amphibolitised pyrope peridotites, garnetised spinel peridotites, ilmenite peridotites, chromian spinel + chromian diopside + pyrope intergrowths, and large xenoliths of pyrope dunite. High-pressure minerals are predominantly of the ultramafic suite, Cr-association minerals (purplish-red and violet pyrope, chromian spinel, chromian diopside, Cr-pargasite and orthopyroxene). The Ti-association minerals of the ultramafic suite (picroilmenite and orange pyrope), as well as rare grains of orange pyrope-almandine of the eclogite association, are subordinate. Kimberlites from all four pipes contain rare grains of G10 pyrope of the diamond association, but chromian spinel of the diamond association was not encountered. By their tectonic position, by geochemical characteristics, and by the composition of kimberlite indicator minerals, the Fazenda Largo kimberlites, like the others of such type, are unlikely to be economic.  相似文献   

17.
西村岩管是在苏北地区发现的第一个金伯利岩管,颠覆了苏北地区无金伯利岩的历史。从岩石学、地球化学和伴生矿物等方面分析了西村岩管的地质特征,并进一步探讨其金刚石找矿意义。从区域背景和金刚石形成条件看,西村地区具备了金伯利岩侵位和金刚石矿形成的基本地质条件,而西村岩管为金刚石矿就位提供了母岩条件;西村金伯利岩与山东、辽宁金伯利岩具有相似的地球化学特征,是幔源岩浆低程度部分熔融的产物,且在岩浆上升过程中普遍遭受了壳源物质的混染,后期碳酸盐化现象普遍发育;其相容元素含量与山东金伯利角砾岩相似,均为典型的金伯利岩型配分模式,稀土元素表现为轻、重稀土元素强烈分馏的特征;伴生指示矿物主要为榴辉岩型含铬镁铝榴石、富铬透辉石和富镁铬尖晶石,其特征均表现出含矿金伯利岩的特点。  相似文献   

18.
In Venezuela, kimberlites have so far only been found in the Guaniamo region, where they occur as high diamond grade sheets in massive to steeply foliated Paleoproterozoic granitoid rocks. The emplacement age of the Guaniamo kimberlites is 712±6 Ma, i.e., Neoproterozoic. The Guaniamo kimberlites contain a high abundance of mantle minerals, with greater than 30% olivine macrocrysts. The principal kimberlite indicator minerals found are pyrope garnet and chromian spinel, with the overwhelming majority of the garnets being of the peridotite association. Chrome-diopside is rare, and picroilmenite is uncommon. Chemically, the Guaniamo kimberlites are characterized by high MgO contents, with low Al2O3 and TiO2 contents and higher than average FeO and K2O contents. These rocks have above average Ni, Cr, Co, Th, Nb, Ta, Sr and LREE concentrations and very low P, Y and, particularly, Zr and Hf contents. The Nb/Zr ratio is very distinctive and is similar to that of the Aries, Australia kimberlite. The Guaniamo kimberlites are similar in petrography, mineralogy and mantle mineral content to ilmenite-free Group 2 mica kimberlites of South Africa. The Nd-Sr isotopic characteristics of Guaniamo kimberlites are distinct from both kimberlite Group 1 and Group 2, being more similar to transitional type kimberlites, and in particular to diamondiferous kimberlites of the Arkhangelsk Diamond Province, Russia. The Guaniamo kimberlites form part of a compositional spectrum between other standard kimberlite reference groups. They formed from metasomatised subcontinental lithospheric mantle and it is likely that subduction of oceanic crust was the source of this metasomatised material, and also of the eclogitic component, which is dominant in Guaniamo diamonds.  相似文献   

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