硅岩的Rb-Sr同位素组成特点及其地质意义

通过对扬子地台和东昆仑山地区的不同时代、不同成因、成分上差异较大的硅岩Rb-Sr同位素组成的对比研究，探讨其物源和形成环境，利用所测Rb-Sr等时线年龄，有效的解决硅岩的地层年代，开创硅岩测年的应用前景。     

论斑岩铜矿的成因

较系统地论述了国内外学者对斑岩铜矿成因的不同学术观点 ,包括“岩浆热液说”(岩浆结晶分异说 )、“板块构造成矿说”(含Cu洋壳重熔说 )、“活动转移说”及“变岩浆成矿说” ;分别对它们的立论依据及不足之处进行了较详细的分析 ,并根据作者对斑岩铜矿的时空分布、物质组分、结构构造及矿物中各种包裹体等特征的深入研究 ,提出斑岩铜矿主要是由深源 (地幔或下地壳 )富碱 (K、Na)、硅的热流体 (或与地壳岩石中的裂隙水、地下水混合 )交代或局部熔融上部地壳含Cu岩石而成     

北祁连山早古生代硅质岩稀土元素特征及构造环境意义

通过对北祁连山不同地质环境中的与火山岩相伴生的硅质岩稀土元素特征的分析,证明产于不同地质环境硅质岩的稀土元素特征,特别是稀土元素总量w( REE)、w(Ce)/w(Ce*)、w(LaN)/w(YbN)具有特定的规律性变化:从洋中脊→弧后盆地→岛弧→裂隙式火山作用大陆裂谷→中心式火山作用大陆裂谷,硅质岩的w( REE)、w(Ce)/w(Ce*)、w(LaN)/w(YbN)基本呈由小到大的规律性变化,w( REE)由7.64×10-6→8.20×10-6→23.74×10-6→28.40×10-6→69.41×10-6;w(Ce)/w(Ce*)由0.63→0.68→0.72→0.75→0.95;w(LaN)/w(YbN)由0.37→0.41→0.59→0.76→1.08。该研究成果为利用硅质岩稀土元素特征判定古老造山带的构造环境提供了参考标准。     

青海南部金沙江缝合带二叠纪硅质岩地球化学特征及沉积环境

青海省南部扎河地区金沙江缝合带中出露的通天河蛇绿混杂岩由不同时代、不同岩性的地层断片组成.对其中的二叠纪硅质岩进行地球化学研究后发现,该地区的硅质岩SiO2含量在71.56%～88.24%之间,Al/(Al Fe Mn)平均值为0.64,MnO/TiO2平均值为0.74,ΣREE平均为138.51×10-6,稀土元素配分曲线呈平坦型,δCe为0.97～1.49,平均为1.14,无明显异常;(La/Yb)N平均值为1.85,(La/Ce)N平均值为1.08,与已知大地构造背景的硅质岩地球化学特征对比,表明其形成环境为陆间洋盆环境.因此,金沙江带不能作为古特提斯域的主缝合带.     

硅质岩沉积地球化学研究现状

硅质岩是造山带中分布最为广泛的岩石类型之一,硅质岩沉积环境的确定对深海沉积作用、大陆边缘地质学及大地构造格架的厘定具有重要意义。目前,在硅质岩沉积地球化学研究方面有以下主要进展：①硅质岩沉积地球化学研究;②与蛇绿岩有关的硅质岩沉积地球化学研究;③物质来源研究;④古氧化还原条件研究;⑤硅质岩构造环境判别     

Silicon Isotope Geochemistry of Micro—Fine Disseminated Gold Deposits in SW Guizhou and NW Guangxi,China

Quartz was studied with respect to its silicon isotopic composition and cathodoluminescence in micro-fine disseminated gold deposits in SW Guizhou and NW Guangxi.The results showed that quartz in wall rocks.ores and that in association with hydrothermal silicification are distinctive in silicon isotopes and cathodoluminescence characters.Quartz in association with primary silicification is non-luminescent while that in wall rocks and associated with secondary silicification exhibits striking luminescence.Based on the dynamic fractionation of silicon isotopes,it is suggested that the mineralization was accompanied by rapid transport of aprimary siliceous fluid along the major deep fault system into subordinate faults before ore components deposited in favorable strata via penetration and metasomatism.Therefore,a deep origin is implicit for gold deposits of this type.     

塔里木盆地寒武系层状硅质岩与硅化岩的元素、δ30Si、δ18O地球化学研究

塔里木盆地寒武系发育层状硅质岩和硅化岩,层状硅质岩主要发育于塔东下寒武统深水沉积相区;硅化岩发育于塔东上寒武统斜坡沉积区与西部台地区寒武系白云岩中。根据显微结构特征,可将硅化岩分为放射状硅化岩与交代残余结构硅化岩两种。分析结果表明,层状硅质岩在Al—Fe-Mn三元图中位于正常海水沉积硅质岩区内,在微量元素平均地壳标准化图解上显示平缓右倾的特征;层状硅质岩Si同位素组成护。δ30Si为0．99‰～1．4‰,O同位素组成δ18O为21．4‰～24．4‰,与沉积型硅质岩相吻合,指示了正常海水沉积成因。硅化岩区别于层状硅质岩的典型特征是具有高U异常的特征;罗西斜坡放射状硅化岩具有较高的微量元素和稀土元素含量（∑REE为18．8～96．9μg／g）与较低的Si、O同位素值（δ18O和δ30Si值分别为15．8‰和1．7‰）;西部台地区交代残余结构硅化岩具有较低微量元素和稀土元素含量（∑REE为0．58～2．61μg／g）与较高的δ30Si（1．0‰～3．8‰）、δ18O（21．6‰～27．0‰）值特征。盆地东西部硅化岩的地球化学差异可能与硅化流体的温度差异有关,罗西斜坡放射状硅化岩硅化温度相对更高;另一方面,硅化过程对h430SiO4选择性较高,因而形成的交代石英具有较高的铲勘值。根据古城4井硅化岩包裹体均一温度与交代石英的O同位素值计算得到交代流体的δ18O值为9．1‰,该值与酸性岩浆水的δ18O值相似,指示了硅化流体可能来自于岩浆或变质水;以δ18O值（9．1‰）作为西部台地区硅化流体的O同位素值,计算得到西部台地区硅化岩硅化流体温度为101．3～158．5℃。根据石英O同位素温度计计算的硅化流体温度呈东高西低的趋势,指示了硅化流体可能来自台地东部。     

江西省莲花县江下垅粉石英矿地质特征及找矿方向

江西省莲花县江下垅粉石英矿,赋存于二叠系上统狮子形组,系硅质灰岩、硅质岩风化而成。矿体严格受地层控制,岩石硅质成分是成矿的先决条件,温暖湿润的气候是成矿的后天条件。     

地层中的硅岩: 研究进展及展望*

硅岩是由自生石英形成的化学沉积岩,通常以层状或非层状(结核状、条带状)独自出现、与其他岩性互层出现及赋存于其他岩性地层中。硅岩不仅记录了大量盆地古地理、古海洋、古气候的地质信息,而且对于岩石大地构造学研究具有重要意义。前人对硅岩的研究取得了丰富的成果,近年来关于硅岩的新观点为硅岩的研究提供了新的思考途径和研究线索。通过调研近年来关于硅岩的岩石学特征、地球化学特征及沉积环境的研究,分析总结了不同地质历史时期、不同沉积环境、不同产状硅岩的形成模式、成因类型以及判别方式,认为硅岩的沉积不是单一因素控制的结果,而是地质构造活动强度、生物类型及活动性、沉积古环境的综合结果。常规地球化学元素结合岩石组构与微区分析、包裹体分析、新同位素(Rb-Sr和Sm-Nd)分析,以及新的地球化学判定标准(Ge/Si)是硅岩研究的必备手段和方法。     

Geochemical Characteristics of Wuyang Siliceous Rocks in the Southern Margin of North China Craton and its Constraint on the Formation Environment of BIF of Tieshanmiao Formation

Precambrian banded iron formation(BIF) is one of the most important mineral resources in China, mostly abundant in the North China Craton(NCC) with relatively less common in South China. Since the BIF and siliceous rocks both originated from chemical deposition, the syngenetic BIF and Siliceous rocks can help evaluate their environment of formation. We examine here the mineralogy and geochemistry of siliceous rocks associated with the Tieshanmiao Formation BIF, aiming to decipher the conditions of formation of both BIF and Siliceous rocks in the Wuyang area in the NCC. Analysis of the geochemical characteristics of whole rock shows that the Si O2 content of the siliceous rock ranges from 90.11% to 94.85% and is relatively high overall. Trace element contents of Ba and U are also high, the Ba/Sr ratio ranges from 3.89 to 25.28 and the U/Th ratio ranges from 0.09 to 0.20. Finally, the ΣREE value of rare earth elements ranges from 57.03 ppm to 152.59 ppm, and these indexes all indicate that siliceous rock resulted from hydrothermal deposition. Plots of Al2 O3-Si O2, Si O2/(K2 O+Na2 O)-Mn O2/Ti O2 and Mn-10×(Cu+Co+Ni)-Fe in discrimination diagrams also verify this interpretation. However, both the Mg O content, ranging from 0.16 to 0.32, and the Fe/Ti ratio, ranging from 2.50 to 9.72, suggest that terrigenous material was added during the depositional process. Major and trace element parameters of siliceous rock, such as the Al/(A1+Fe+Mn) ratio(from 0.81 to 0.93), Mn O/Ti O2(from 0.00 to 0.17), Al/(Al+Fe)(from 0.82 to 0.93), Sc/Th ratio(from 0.21 to 0.50), U/Th(from 0.09 to 0.20),(La/Yb)N(from 0.83 to 3.04), and the(La/Ce)N(from 0.01 to 0.02) all imply that the siliceous rock formed in a continental margin. In addition, the Sr/Ba ratio from 0.08 to 0.26, the δCe value from 0.31 to 0.90, and the δEu value from 0.14 to 0.58, all indicate that the siliceous rock was formed at a relatively deeper water depth and under weak hydrodynamic conditions. Siliceous rock and BIF formed in the same geological setting, with the Si O2/(K2 O+Na2 O) ratio of siliceous rock ranging from 28.61 to 47.43, the Si O2/Al2 O3 ratio from 16.53 to 32.37, and the Si O2/Mg O ratio from 287.28 to 592.81, which are all in agreement with chemical deposition associated with volcanic eruptions. The Al2 O3/Ti O2 ratio from 37.82 to 50.30 indicates that the magma source of siliceous rock was of slightly intermediate composition. During the Late Archean in the Wuyang area, the high concentration and high purity Si O2 quickly precipitated from hydrothermal fluids to finally result in the accumulation of siliceous rock in a marginal sea, while the input corresponding to iron formation components was deposited to form iron formation layers, and limestone was only the product formed during the deposition intervals of siliceous rock and iron formations. In this study, the synsedimentary siliceous rocks of BIF act as a new way to provide direct evidence to understand the formation environment of BIF due to its high geochemical stability.