我国东部碱性岩中长石研究

我国东部六个碱性岩体的长石以碱性长石为主,包括了正长石、微斜长石和钠长石;斜长石有中长石和奥长石。它们具有三种组合,即正长石-斜长石;正长石-微斜长石;钠长石-微斜长石组成的条纹长石。各组合长石在组分或结构态方面都有某些共同之处,某些岩体还体现了长石成分演化的一致趋势。本文根据长石结构态,以及二长石和长石-霞石地质温度计的应用,对岩体形成温度作了一些探讨。     

长石—造岩矿物中最常见的宝石矿物

长石是一族矿物的名称,从组分说有四种:钾长石、钠长石、钙长石、和钡长石。长石族有三个亚族:钾钠长石亚族,又名正长石亚族,由于阳离子是K、Na故又名碱性长石亚族,斜长石亚族和钡长石亚族。钾长石与钠长石,高温时可以形成完全类质同象,低温是不完全类质同象,它们的类质同象称碱性长石系列;钠长石和钙长石也可以形成类质同象,称斜长石系列,通常仍不正确     

松辽盆地白垩系砂岩长石碎屑的钠长石化作用

松辽盆地白垩系砂岩以长石岩屑砂岩和岩屑长石砂岩为特征。砂岩中发育长石碎屑、岩屑等不稳定组分，而且随着埋藏深度加深（成岩作用加强）钾长石逐渐减少并最终在2700m以下消失。斜长石碎屑中钠长石组分逐渐增多，钙长石组分逐渐减少，最终形成纯钠端元的钠长石。在成岩过程中长石碎屑的钠长石化主要有3种方式：①由离子交代作用导致长石碎屑的钠长石化；②长石碎屑边缘钠长石次生生长；③与长石碎屑溶解伴生的新生钠长石作用。结合热动力学平衡原理分析，斜长石的钠长石化基本不受成岩温度和压力的制约，而钾长石的钠长石化需要较高的成岩温度和压力作用才能进行。因此，斜长石的钠长石化可见于成岩早期，而钾长石的钠长石化只发生于成岩晚期。     

山东五莲碱性三元长石的微结构研究

笔者对产于山东五莲县七宝山辉石二长岩中的碱性长石进行了电子探针,Ｘ射线衍射,透射电子显微镜以及＾２９ＳｉＭＡＳＮＭＲ谱研究,确定五莲碱性三元长石（Ｏｒ５０．３,Ａｂ４４．３Ａｎ５．４）为钾长石和钠长石共格出溶连晶,其基体钾长石为单斜对称,在透射电子显微镜下未见其呈现任何微结构,而在钠长石中见到宽度为１０．４ｎｍ（钠长石的８ｂ０）的片晶相互形成周期钠长石律双晶,钠长石叶片的宽度平均为３９ｎｍ（ｎ＝４     

偏光显微镜下鉴定长石的几种方法

长石是主要的造岩矿物,现在最常用的火成岩分类法即以长石为标准,因此不论在野外或室内,鉴定岩石必先认清长石。长石按其化学成份,一般分为钾系长石 KAlSi_3O_8与钠钙系长石NaAlSi_3O_8,CaAlSi_3O_8 两大类;而钾系长石常含有微量的钠长石分子,钠长石中也常含有微量的钾长石分子。钾长石与钠长石又可彼此包裹成为     

火山岩储层斜长石选择性溶蚀的岩石学及热力学研究

长石溶孔是火山岩中重要的孔隙类型之一,火山岩的主要孔隙类型中长石溶孔所占的比例在1.24%～60.61％之间,在储层中占有重要地位。从岩相学、岩石化学CIPW标准矿物成分、热力学等方面论证了斜长石的选择性溶蚀。岩相学特征表现出斜长石选择性溶蚀的特征,即钙长石溶蚀时钠长石没有溶蚀,同时出现斜长石选择性溶蚀时钠长石和钾长石生长的现象。斜长石选择性溶蚀得到了CIPW标准矿物成分的支持,在CIPW标准矿物成分中长石的端元组分主要为钠长石和钾长石,而钙长石绝大多数为0或接近0。热力学研究表明,在同样的温度、压力和地层水成分的条件下,在斜长石中优先溶解钙长石组分。当地层水中Na+和K+浓度达到饱和时发生钠长石和钾长石沉淀,出现斜长石选择性溶蚀的同时发生钠长石和钾长石生长的现象。     

火山岩储层斜长石选择性溶蚀的岩石学特征和热力学条件

长石溶孔是火山岩中重要的孔隙类型之一,火山岩的主要孔隙类型中长石溶孔所占的比例在1.24%～60.61%之间,在储层中占有重要地位.从岩相学、岩石化学CIPW标准矿物成分、热力学等方面论证了斜长石的选择性溶蚀.岩相学特征表现出斜长石选择性溶蚀的特征,即钙长石溶蚀时钠长石没有溶蚀,同时出现斜长石选择性溶蚀时钠长石和钾长石生长的现象.斜长石选择性溶蚀得到了CIPW标准矿物成分的支持,在CIPW标准矿物成分中长石的端元组分主要为钠长石和钾长石,而钙长石绝大多数为0或接近0.热力学研究表明,在同样的温度、压力和地层水成分的条件下,在斜长石中优先溶解钙长石组分.当地层水中Na+和K+浓度达到饱和时发生钠长石和钾长石沉淀,出现斜长石选择性溶蚀的同时发生钠长石和钾长石生长的现象.     

长石溶解模拟实验研究综述

在综合分析前人研究成果基础上,对长石溶解模拟实验研究进行了综述.研究表明,长石溶解与其成分、结构、反应的温压条件以及流体性质等有关.在相同的温压条件下,3种长石的稳定性依次为:钾长石>钠长石>钙长石,且温度升高可加强长石的溶解能力,促进长石的溶解,而压力的变化对长石的溶解影响不大.长石的溶解速率在酸性区域随pH值增大而减小、在中性区域溶解速率低且受影响小、在碱性区域随pH值增大而增大.有机酸通过提供H+、络合金属元素来提高长石的溶解度.长石的溶蚀速率与颗粒的总表面积大小以及颗粒表面粗糙度有关,总表面积越大,表面越粗糙,则反应速率越快,而且溶液的矿化度越低越有利于长石的溶解.长石的溶解过程由表面反应和扩散反应所控制,描述长石溶蚀机理的模型主要包括:表面反应模型和淋滤层扩散模型.     

江西雅山花岗岩长石中磷的分布及意义

雅山富氟高磷花岗岩具较高的全岩磷含量（０．１５％～０．５５％）,长石是磷的主要赋存矿物,磷以ＰＡｌＳｉ－２替换方式进入长石结构中。各种结晶习性的长石的磷含量各不相同。早世代钠长石和雪球结构中钠长石包裹体的结晶较早,平均磷含量分别为０．１８％和０．１９％,而晚世代钠长石和环带钾长石中钠长石嵌晶的结晶稍晚,具较高的平均磷含量（分别为０．２５％和０．２３％）。钾长石的磷含量相对于钠长石总体上较低,早期结晶的雪球结构主晶钾长石和环带钾长石的磷含量最低,分别为０．０４％和０．０２％,晚期细粒钾长石的平均磷含量略高（０．１９％）。长石对全岩磷的贡献率还与磷锂铝石等磷酸盐副矿物是否达到饱和有关,当无磷锂铝石结晶时,长石磷的贡献率约为７６％,反之则约为３１％。     

云南个旧卡房锡-铜矿床碱长花岗岩厘定及意义

卡房矿床位于个旧矿田东南部,矿区花岗岩为致矿岩体,以往对花岗岩的研究也较多,对花岗岩的定名为:黑云母花岗岩、黑云母二长花岗岩或者黑云母斜长花岗岩等等。通过对卡房花岗岩进行系统的岩矿鉴定和电子探针分析,发现长石为碱性长石(钾长石和钠长石),钠长石的An值均小于等于5。因此最终确定卡房岩体花岗岩为碱长花岗岩。而这种碱长花岗岩由富挥发分的岩浆形成,液态不混溶作用广泛发育于岩体顶部附近,是锡多金属矿富集成矿的主要分异方式,钠长石的An值可部分作为花岗岩成矿属性的评价标识之一。     

Définition d'une limite multicritère ; stratigraphie du passage Campanien–Maastrichtien du site géologique de Tercis (Landes,SW France)Definition of a multi-criteria boundary; stratigraphy of the Campanian–Maastrichtian interval of the geological site at Tercis (Landes,SW France)

Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414.     

Late Wuchiapingian (Late Dzhulfian,early Late Permian) limestone olistolites within the Tertiary flysch of Glypia Unit (Mount Parnon,central–eastern Peloponnesus,Greece)

Some olistolites reworked in a Tertiary flysch of Mount Parnon (Peloponnesus, Greece) exhibit a Late Permian assemblage, dominated by Paradunbarula (Shindella) shindensis, Hemigordiopsis cf. luquensis and Colaniella aff. minima. This association corresponds to the Late Wuchiapingian (=Late Dzhulfian), a substage whose algae and foraminifera are generally little known. Contemporaneous limestones crop out in the middle part of the Episkopi Formation in Hydra, but they are rather commonly reworked in Mesozoic and Cainozoic sequences. The palaeobiogeographical affinities shared by the foraminiferal markers of Greece, southeastern Pamir, and southern China, are very strong (up to the specific level), and are congruent with the Pangea B reconstructions. To cite this article: E. Skourtsos et al., C. R. Geoscience 334 (2002) 925–931.     

PALEONTOLOGY

正20141596 Liu Yunhuan(School of Earth Sciences and Resources,Chang’an University,Xi’an 710054,China);Shao Tiequan Early Cambrian Quadrapyrgites Fossils of Xixiang Boita in Southern Shaanxi Province(Journal of Earth Sciences and Environment,ISSN1672-6561,CN61-1423/P,35(3),2013,p.39-43,3 illus.,20 refs.)     

GEOCHEMICAL EXPLORATION

正20141719 Chen Zhijun(State Key Laboratory of Geological Processes and Mineral Resources,China University of Geosciences,Wuhan 430074,China);Chen Jianguo Automated Batch Mapping Solution for Serial Maps:A Case Study of Exploration Geochemistry Maps(Journal of Geology,ISSN1674-3636,CN32-1796/P,37(3),2013,p.456-464,2 illus.,2 tables,10 refs.)     

MICROPALAEONTOLOGY

正20140962 Chen Fenning(Xi’an Institute of Geology and Mineral Resources,Xi’an710054,China);Chen Ruiming Late Miocene-Early Pleistocene Ostracoda Fauna of Gyirong Basin,Southern Tibet(Acta Geologica Sinica,ISSN0001-5717,CN11-1951/P,87(6),2013,p.872-886,6illus.,56refs.)     

PETROLOGY

正1.IGNEOUS PETROLOGY20142008Cai Jinhui(Wuhan Center,China Geological Survey,Wuhan 430205,China);Liu Wei Zircon U-Pb Geochronology and Mineralization Significance of Granodiorites from Fuzichong Pb-Zn Deposit,Guangxi,South China(Geology and Mineral Resources of South China,ISSN1007-3701,CN42-1417/P,29(4),2013,p.271-281,7illus.,     

ENVIRONMENTAL GEOLOGY

正20141205Cheng Weiming(State Key Laboratory of Resources and Environmental Information System,Institute of Geographic Sciences and Natural Resources Research,CAS,Beijing 100101,China);Xia Yao Regional Hazard Assessment of Disaster Environment for Debris Flows:Taking Jundu Mountain,Beijing as an     

PROSPECTING EXPLORATION

正20141266Fan Chaoyan(Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes,Guangzhou 510275,China);Wang Zhenghai On Error Analysis and Correction Method of Measured Strata Section with Wire Projection Method(Journal of     

OCEANOGRAPHY & MARINE GEOLOGY

正20140582 Fang Xisheng(Key Lab.of Marine Sedimentology and Environmental Geology,First Institute of Oceanography,State Oceanic Administration,Qingdao 266061,China);Shi Xuefa Mineralogy of Surface Sediment in the Eastern Area off the Ryukyu Islands and Its Geological Significance(Marine Geology Quaternary Geology,ISSN0256-1492,CN37     

ENVIRONMENTAL GEOLOGY

正20141810 Bian Yumei(Geological Environmental Monitoring Center of Liaoning Province,Shenyang 110032,China);Zhang Jing Zoning Haicheng,Liaoning Province,by GeoHazard Risk and Geo-Hazard Assessment(Journal of Geological Hazards and Environment Preservation,ISSN1006-4362,CN51-1467/P,24(3),2013,p.5-9,2 illus.,tables,refs.)