山东临朐红丝砚石的发墨机理探讨

采用薄片观察、X射线粉晶衍射、显微硬度实验等测试手段,对山东临朐红丝砚石的矿物学特征和砚石发墨机理进行了研究;模仿人工研磨的特点,设计了发墨对比实验,并开创性地利用薄片观察法对砚石发墨优劣进行了定量评价。结果显示,石英是红丝砚石发墨的主要功能矿物,石英的磨圆度、粒度差异、含量是影响砚石发墨快慢的主要因素。     

河北易水砚石的矿物岩石学特征研究

采用薄片观察、电子探针分析、X射线粉晶衍射分析等方法对2种易水砚石的矿物学、岩石学特征进行了研究。结果显示,易水砚的两个品种紫翠石和玉黛石均属碎屑岩,其中玉黛石主要的碎屑组成矿物有石英、长石、赤铁矿、沸石,胶结物为泥质矿物伊利石,可占玉黛石的30%~40%;紫翠石主要的碎屑组成矿物有石英、长石、赤铁矿、方解石、沸石,胶结物为泥质矿物伊利石、蒙脱石、绿泥石、高岭石和蛭石,可占紫翠石的30%~50%。     

三种浙江青田石的宝石矿物学特征研究

采用显微分析、电子探针、X射线粉末衍射实验、红外光谱等测试方法,对＂山炮绿＂种、＂蓝花钉＂种、＂夹板冻＂种青田石样品进行了研究。结果表明,＂山炮绿＂种样品的主要矿物为白云母,次要矿物为石英;＂蓝花钉＂种样品主要由叶腊石和刚玉组成;＂夹板冻＂种样品的主要矿物为白云母,还含有石英、钠长石、钠云母和少量的赤铁矿。同时,还对其颜色成因进行了探讨。     

几种具有代表性青田石的矿物学特征初探

对封门矿区七个不同品种的青田石（＂封门青＂＂金玉冻＂＂黄金耀＂＂朱砂＂＂水草＂＂紫罗兰＂＂三彩＂）样品进行X射线粉末衍射、红外光谱、激光诱导离解光谱仪等测试,对其主要矿物组成,矿物组合及颜色成因进行了分析探讨。结果显示,＂封门青＂和＂金玉冻＂均为成分较纯的叶蜡石,属于叶蜡石型青田石;＂黄金耀＂的矿物组合为伊利石＋少量叶蜡石,属于伊利石型青田石;＂朱砂＂的矿物组合为叶蜡石＋石英＋赤铁矿＋高岭石,属于叶蜡石型青田石;＂紫罗兰＂的主要矿物组成是叶蜡石,属于叶蜡石型青田石,其紫色花星成分可能为贫铁蓝线石;＂三彩＂的主要矿物组成为叶蜡石,但其三个不同颜色（灰色,土黄色,黄绿色）部分的矿物组合不同,石英的质量分数较高且结晶较好是＂三彩＂显颗粒感的主要原因。     

贵州威宁沉积型赤铁矿矿石工艺矿物学研究

对贵州威宁沉积型赤铁矿石进行了工艺矿物学研究,重点研究了该矿石的矿物组成、主要矿物嵌布特征和主要含铁矿物赤铁矿的单体解离情况。研究表明,该矿石属于低磷、低硫、微细粒嵌布的赤铁矿石;矿石中主要铁矿物以赤铁矿为主,其次为磁铁矿和褐铁矿,主要脉石矿物以石英为主,其次为绿泥石、云母、高岭石等粘土矿物;赤铁矿嵌布粒度极细,平均粒度0.015mm,且赤铁矿与脉石矿物嵌布关系复杂。本研究为该矿石的开发利用提供基础资料。     

云南昭通南红的宝石矿物学特征

永善县黑甲乡产出的昭通南红多为浅棕褐色—深红色,皮壳较薄且光滑,断口呈油脂光泽,透明-微透明,玉质细密,部分玉石中有"夹白"或"乌石"现象。放大观察可见玉石为粒状结构和纤维状结构,不透明的褐色-黑色的铁质矿物分布在石英颗粒的边缘,有大量红色-橙红色、颗粒极小的铁质胶体呈细分散浸染状分布;在环带状结构中,铁质矿物主要分布在层与层过渡的间隙中,与环带或条带平行排列,反映出昭通南红形成条件的韵律性变化。昭通南红的主要组成矿物为石英,含有少量的赤铁矿、磁铁矿等。石英的化学成分主要为SiO_2,平均质量分数98.75%以上,含有少量的Fe,Cr,Al,K,Na,Ca等杂质元素;暗色颗粒主要为赤铁矿,FeO的质量分数高达88.9%,其次为Ti,Al,Cr等元素。激光拉曼光谱和红外光谱特征表明昭通南红属于蛋白石与玉髓、玛瑙之间的过渡品种。     

淄博市大气降尘矿物微形貌及其来源判识

用场发射扫描电子显微镜及能谱仪和X射线衍射仪,对淄博市中心城区大气降尘的矿物组成、微形貌和微区成分进行了分析.结果表明,淄博市大气降尘的矿物组成有石英、长石、石膏、方解石、赤铁矿、白云母、伊利石和非晶质等.矿物微形貌特点和矿物组成揭示了降尘组分主要来源于3种途径:与高温过程有关的工业活动排放的产物,自然成因和大气化学反应的产物.球形赤铁矿、板状方解石和絮状石膏是本研究中观察到的3种典型矿物微形貌.     

桂林鸡血玉的致色机理研究

借助偏光显微镜和X射线粉晶衍射仪、电子探针、紫外-可见-近红外分光光度计等现代仪器设备,对桂林鸡血玉的显微结构、矿物组成及致色机理进行分析和探讨。桂林鸡血玉的颜色多样,包括红色、"红血黑地"、黄色、紫色和绿色5大系列。玉石主要为他形等粒变晶结构,部分区域可见变斑晶结构,主要矿物为微晶质—隐晶质石英,次要矿物主要为赤铁矿,部分玉石中还有少量的绿泥石、滑石甚至白云石等,w(SiO2_)介于94.92%到99.65%之间。不同形态的赤铁矿及其他矿物杂质是引起玉石颜色多样性的主要原因,[FeO_4]~(4-)空穴色心对可见光的选择性吸收使玉石呈现紫色。鸡血玉的红色与细尘状赤铁矿密切相关,细尘状赤铁矿越密集玉石的颜色越深,细尘状赤铁矿含水时鸡血玉的红色较为鲜艳;不同色调的黑色鸡血玉主要由鳞片状赤铁矿或集合体磁铁矿致色;黄色主要由氧化铁的含水矿物——针铁矿所引起,且随着鳞片状赤铁矿含量的增加,颜色逐渐偏向于橙黄色;不同色调的鳞片状绿泥石是玉石呈绿色的根本原因,滑石和白云石对玉石的颜色没有直接的影响,但它们的存在使玉石的光泽变暗、透明度降低。     

冀东司家营铁矿尾矿特征及综合利用建议

通过对冀东司家营铁矿尾矿的化学成分、矿物组成、矿物粒度、解离度以及矿物连生关系等测定,分析了该尾矿综合利用的途径,为同类型沉积变质型铁矿(BIF型铁矿)尾矿综合利用提供参考.分析结果表明,司家营铁尾矿属高硅高铁低铝尾矿;矿物组成以石英、阳起石、透辉石和长石为主,含少量赤铁矿、铁白云石、大隅石及云母等矿物;尾矿粒度以细砂...     

磁性硫酸烧渣结构和物性特征及应用潜力

通过X射线荧光光谱、X射线粉末衍射分别对某公司磁性硫酸烧渣的化学和物相组成进行了鉴别,采用场发射扫描电镜观察微形貌和微结构特征,测定了烧渣的磁化率和磁滞回线。结果表明,硫精矿粉沸腾炉焙烧所得磁性硫酸烧渣,铁品位达到64.78%,杂质组分主要是硅、铝和硫;主要物相为磁铁矿、磁赤铁矿和赤铁矿,含少量石英;比表面积为2.83 m2/g,磁化率为18 000×10-8 m3/kg;原始微米粒径的黄铁矿粉体在脱硫、氧化相变为磁赤铁矿、磁铁矿和赤铁矿的过程中多晶化、纳米化,转变为纳米亚微米晶体,颗粒表现为多孔特征。这种较高比表面积、强磁性的磁性烧渣有望在吸附和磁分离领域作为功能材料发挥作用。研究结果也为利用铁硫化物热分解相变进行矿物纳米材料加工提供了新的思路。     

一种红色砭石的矿物学特征研究

采用X射线粉末衍射（XRD）、扫描电子显微镜（SEM）、热重分析（TG-DTG）及激光诱导离解光谱（LIBS）等分析方法对一种红色砭石的矿物学特征进行了深入的研究。XRD分析表明,红色砭石主要由白云石组成,并含有少量石英和方解石及微量云母、正长石和赤铁矿。SEM结果显示,砭石中的矿物颗粒大多为集合体,粒径大多集中在1～5μm之间,表面光滑程度有所不同。红色砭石在650-850℃范围内出现一个单失重峰,为白云石的分解形成,类质同象或者杂质矿物的存在导致白云石两阶段的分解同步完成。红色砭石的颜色可能与赤铁矿和正长石微晶在砭石中的均匀分布有关。     

应用X射线衍射-激光拉曼光谱-电子探针等分析测试技术研究旬阳朱砂玉的矿物学特征

近年来外观形似鸡血石的红色朱砂玉备受关注,其中吉林、贵州、青海等地这种红色岩石已有矿物成分、岩性等相关方面的研究。本文利用常规宝石常数测定手段、偏光显微镜、X射线粉晶衍射仪、激光拉曼光谱仪、电子探针等分析测试技术,对陕西旬阳朱砂玉的矿物学和宝石学特征进行了研究。结果表明,该产地朱砂玉的矿物成分以石英、辰砂为主,含有少量的方解石、白云石、重晶石、黄铁矿;其中主要矿物成分辰砂的颜色随铁含量的增加而逐渐加深;矿物结构以碎屑结构、粒状变晶结构、穿插交代结构为主。根据矿物成分以及矿床成因的研究分析,初步认为陕西旬阳朱砂玉属于沉积-热液-强烈改造型矿床。该地区的朱砂玉与鸡血石的相似之处在于矿物的主要成分都含有辰砂,致使外观品质上具有一定的相似性,但具体矿床成因以及矿物成分有着明显的差别:旬阳朱砂玉产于沉积-热液-强烈改造型矿床中,其“地”主要矿物成分为石英岩,“血”为辰砂;而浙江昌化和内蒙古巴林鸡血石均产于中生代交代蚀变酸性火山岩的次级断裂小构造中,其“地”主要为地开石、高岭石、叶腊石,“血”为辰砂。此次研究采用多种分析测试手段为旬阳朱砂玉与鸡血石的鉴别提供了可靠的依据。     

鄂尔多斯盆地古隆起东北侧马五41储层膏模孔类型及充填过程分析

利用岩芯和薄片资料,通过薄片孔隙描述、铸体薄片图像分析等方法,在对研究区马五₄1储层孔隙类型划分的基础上,详细划分了膏模孔充填类型,并对其充填过程进行了阐述。研究结果表明,研究区马五₄1储层主要发育溶蚀孔（膏模孔和其他溶孔）、晶间孔、晶间溶孔、微裂缝4种类型的孔隙,且以膏模孔为主。通过镜下薄片对膏模孔内不同充填物观察发现,充填物主要为白云石、方解石、硬石膏,其中半充填的膏模孔中主要充填物为白云岩粉砂、白云岩粉砂+石英、白云岩粉砂+铁白云石3种类型,而全充填的膏模孔中主要充填物为白云岩粉砂+方解石、白云岩粉砂+石英+方解石、白云岩粉砂+硬石膏3种类型。综合分析认为膏模孔是含膏云岩中石膏等易溶晶体溶蚀后,晶体轮廓保留而形成的,首先裸露风化壳期先充填白云岩粉砂和深灰色方解石,其次深埋藏期充填自生石英、白色亮晶方解石、铁白云石及硬石膏。     

Tremolite–calcite veins in the footwall of the Simplon Fault,Antigorio Valley,Lepontine Alps (Italy)

The lowermost units of the nappe pile of the Lepontine Alps crop out in the Antigorio valley in the footwall of the Simplon Fault. The whole orthogneiss section of the Antigorio Unit is exposed on both sides of the valley, sandwiched between the Mesozoic metasedimentary sequences of the Baceno unit below and the Tèggiolo unit above. The petrography and mineral composition of tremolite–calcite veins occurring in dolomite marble in both metasedimentary sequences were investigated. Tremolite–calcite (with lesser talc and minor phlogopite) veins have rhythmic banded texture. Banding is due to cyclic differences in modal abundances and fabric of tremolite and calcite. These veins are very similar to those occurring in dolomite rafts within the Bergell granite and it is inferred that they formed by the same “fracture-reaction-seal” mechanism. Veins formed by reaction of a silica-rich aqueous fluid with the host dolomite marble along fractures. According to thermo-barometric calculations, based on electron microprobe analyses, reaction occurred at temperatures between 450 and 490°C and minimum pressure of 2–3 kbar. Such temperature conditions occurred in this footwall region of the Simplon Fault Zone around 15 Ma, during exhumation and cooling of the nappe pile and a transition to brittle behaviour. Aqueous, silica-rich fluids concentrated along fractures, forming tremolite–calcite veins in the dolomite marbles and quartz veins in the orthogneiss.     

X射线粉晶衍射仪在大理岩鉴定与分类中的应用

大理岩主要有方解石大理岩、白云石大理岩和菱镁矿大理岩三种。以往大理岩是依据偏光显微镜下观察岩石结构构造及矿物成分进行分类定名,由于方解石、白云石、菱镁矿都属于三方晶系,具有闪突起、高级白干涉色、一轴晶负光性和菱形解理等相同晶体光学特征,偏光显微镜下区分十分困难。为了准确鉴定大理岩中碳酸盐矿物种类及其相对含量,本文利用岩石薄片偏光显微镜和X射线粉晶衍射技术对32件大理岩岩石样品进行分析测试。岩石薄片鉴定结果表明:大理岩造岩矿物主要有方解石、白云石、菱镁矿、石英、斜长石、白云母、黑云母、绿泥石、黏土和金属矿物。根据岩石结构构造及矿物组分特征,可把32件大理岩样品划分为方解石大理岩、长英质方解石大理岩、石英绿泥白云石大理岩、白云石大理岩、云英质白云石大理岩和菱镁矿大理岩等15个类型。X射线粉晶衍射分析表明:大理岩造岩矿物主要有方解石、白云石、菱镁矿、石英、斜长石、钾长石、云母、绿泥石、滑石和蒙脱石。综合分析认为:岩石薄片偏光显微镜鉴定技术很难区分方解石、白云石和菱镁矿等碳酸盐矿物,以及细小的石英、钾长石和斜长石、滑石和白云母等鳞片状硅酸盐矿物;X射线粉晶衍射分析技术不仅能准确检测出大理岩中方解石、白云石和菱镁矿等碳酸盐矿物种类及相对含量(方解石、白云石和菱镁矿的X射线衍射主峰有明显差异,d值分别为0.303 nm、0.288 nm和0.274 nm),而且能够有效鉴别岩石中粉砂级斜长石、钾长石与石英(三种矿物的X射线衍射主峰d值分别为0.319 nm、0.324 nm、0.334 nm);且能区分蒙脱石、绿泥石、云母和滑石等层状硅酸盐矿物(四种硅酸盐矿物的X射线衍射主峰d值分别为1.400 nm、0.705 nm、0.989 nm、0.938 nm)。综合岩石薄片偏光显微镜鉴定和X射线粉晶衍射分析结果,最终确定32件大理岩样品划分为22个岩石类型。研究认为:仅根据岩石薄片偏光显微镜鉴定或X射线粉晶衍射技术其中一种方法不能准确鉴定大理岩岩石,应将大理岩岩石野外观察、岩石薄片鉴定和X射线粉晶衍射技术结合起来,才能准确确定大理岩岩石类型。     

X射线粉晶衍射仪在辽宁瓦房店金伯利岩蚀变矿物鉴定中的应用

瓦房店金伯利岩热液蚀变强烈,原岩矿物组分几乎蚀变殆尽,显微镜下对蚀变矿物鉴定相当困难.利用X射线粉晶衍射技术对蚀变金伯利岩物相进行系统检测,结果显示：42号岩管金伯利岩主要矿物为蛇纹石、金云母和滑石,有少量方解石、锐钛矿、磷灰石、石英、钛铁矿、钙钛矿、榍石、磁铁矿和绿泥石;石灰窑1号无矿金伯利岩岩管主要矿物为蛇纹石、金云母和白云石,有少量方解石、锐钛矿、磷灰石、滑石、磁铁矿和绿泥石;9号无矿金伯利岩岩脉主要矿物为方解石和石英,有少量绿泥石和重晶石;51号贫矿金伯利岩岩管主要矿物为蛇纹石和金云母,方解石化作用不均匀,白云石化作用普遍,有少量锐钛矿、滑石、磁铁矿、绿泥石、磷灰石、钛铁矿、石英;30号贫矿岩管样品风化严重,主要矿物为蒙脱石,有少量方解石、滑石、蛇纹石、榍石、磷灰石.实践证明,采用X射线粉晶衍射仪鉴定金伯利岩蚀变矿物组合是一种非常可行的技术手段.     

Geothermobarometry in metasediments of the southern Grossvenediger area (Tauern Window, Austria)

Metasediments in the southern Grossvenediger area (Tauern Window, Austria) were studied along a cross-section through rocks of increasing metamorphic grade from the margin of the Tauern Window in the south to the base of the Upper Schieferhülle, including the Eclogite Zone, in the north. In the southern part of the cross-section there is no evidence for a pre-late Alpine metamorphic history in the form of high-pressure relics or pseudomorphs. Mineral assemblages are characterized by the stability of tremolite + calcite, biotite + calcite and biotite + chlorite + calcite. In the northern part a more complete Alpine metamorphic evolution is preserved. Primary high-pressure assemblages are dolomite + quartz, tremolite + zoisite, zoisite + dolomite + quartz + phengite I and probably tremolite + dolomite + phengite I. Secondary, post-kinematic assemblages [tremolite + calcite, talc + calcite, phengite II + chlorite + calcite (+ quartz), biotite + chlorite + calcite, biotite + zoisite + calcite] formed as a result of the dominant late Alpine metamorphic overprint. The occurrence of biotite + zoisite + calcite is confined to the northernmost area and defines a biotite–zoisite–calcite isograd. P–T estimates based on standard thermobarometric techniques and on stability relationships of tremolite + calcite + dolomite + quartz and zoisite give consistent results. P–T conditions of the main Tertiary metamorphic overprint were 525° C, P= 7.5 ± 1 kbar in the northern part of the cross-section. The southern part was metamorphosed at lower temperatures of 430–470° C. The Si-content of phengites from this area is almost as high as that of phengites from the Eclogite Zone (Si^max= 3.4 pfu). Pressures > 10 kbar at 420° C are suggested by phengite barometry according to Massone & Schreyer (1987). In the absence of high-pressure relics or pseudomorphs, these phengites, which lack late Alpine re-equilibration, are the only record that rocks of the southern part probably also experienced an early non-eclogitic high-pressure metamorphism.     

Silicification and dolomitization of anhydrite nodules in argillaceous terrestrial deposits: an example of meteoric-dominated diagenesis from the Triassic of central Spain

Cauliflower-shaped nodules are widespread in a single red mudstone bed in the Buntsandstein (Triassic) facies of the Iberian Range. They consist mostly of quartz, dolomite and calcite, but other minerals, such as barite, kaolinite and iron oxyhydroxides, are also present. The nodules are spherical, ovoid or elongate in shape and range from 1 to 8 cm across. The surface of the nodules is irregular, and some show a pedogenic coating of microspar. The sedimentological and petrographic data suggest that the initial anhydrite nodules formed through a progressive increase in the porewater concentration of Ca²⁺ and SO₄^2– in a vadose environment, occasionally under the influence of pedogenic processes. Partial replacement of the anhydrite by megaquartz occurred under more dilute conditions in the same type of setting, as indicated by the presence of organic filaments on the quartz crystal surfaces. In type A nodules, the dissolution of the innermost anhydrite was complete, and different types of quartz cement filled the porosity. Fracturing and meteoric cementation by calcite and minor amounts of kaolinite were the latest processes affecting these nodules. In type B nodules, the dissolution of the anhydrite was incomplete, inhibiting quartz cementation and enabling later dolomitization of the anhydrite. Dolomitization appears to have been driven by sulphate reduction, as indicated by the presence of bacterial bodies within the dolomite crystals. Dedolomitization and precipitation of barite, kaolinite and calcite spar cements occurred later under the influence of meteoric solutions. The nodules may mark the former locations of the water table and provide evidence for an episode of highly evaporitic conditions throughout wide areas of the basin. Their occurrence reveals not only a complex diagenetic history but is also indicative of palaeogeographic and palaeoclimatic conditions.     

Experimentelle Untersuchung der Metamorphose von kieselig dolomitischen Sedimenten

During an experimental investigation of the metamorphism of siliceous dolomites the equilibrium data of the heterogeneous bivariant reaction 1 $$3{\text{ dolomite + 4 quartz + 1 H}}_{\text{2}} O \rightleftharpoons + 3 calcite + 3 CO_2 $$ were determined for the total fluid pressures of 1,000, 3,000 and 5,000 bars. The equilibrium conditions were found by experiments in which dolomite, quartz and water react to form talc, calcite and CO₂, as well as by experiments with reversible reaction direction. Results are shown on the temperature- \(X_{CO_2 } \) -diagram of Fig. 3. The temperature of formation of talc and calcite depends to a considerable extent on the composition of the CO₂-H₂O-gas phase; this can be read straight off the isobaric (P _f =const.) equilibrium curves in Fig. 3. In addition a strong dependence of the equilibrium temperature on the total pressure P _f was established (see Fig. 5). At a total gas pressure of 1,000 bars dolomite and quartz can react, according to the composition of the CO₂-H₂O-gas phase, to talc and calcite over the whole of the temperature range between about 350° and 490° C. This indicates that at low pressures the formation of talc and calcite takes place in the field of the albite-epidote-hornfels facies. At a pressure of 3,000 bars dolomite and quartz are stable up to about 550° C if the fluid phase is rich in carbon dioxide and correspondingly poor in water. Thus, this paragenesis can occur up to the stability field of staurolite [see annotation (5)] if the partial pressure of CO₂ is large. At the higher total gas pressure of 5,000 bars dolomite and quartz react even at medium CO₂-concentrations only at about 580° C to give talc and calcite. Therefore it is expected that in regional metamorphism at about 5,000 bars pressure or more the paragenesis dolomite plus quartz exists up to and within the stability field of staurolite and reacts only here to form talc and calcite after reaction (1) or tremolite and calcite after the following reaction (2)¹: $$5 dolomite + 8 quartz + 1 H_2 O \rightleftharpoons 1 tremolite + 3 calcite + 7 CO_2 $$ . The exact physico-chemical conditions under which dolomite, quartz and water react on the one hand to form talc, calcite and CO₂, and on the other hand to form tremolite, calcite and carbon dioxide, will be discussed later when our experimental investigations on the formation of tremolite are completed. First results were already published in a short note by Metz, Puhan and Winkler (1968).     

Depositional conditions of the coal-bearing Hirka Formation beneath Late Miocene explosive volcanic products in NW central Anatolia,Turkey

This work focuses on the relationship between the coal deposition and explosive volcanism of the Miocene basin, NW central Anatolia, Turkey. The coal-bearing Hirka Formation was deposited over the Galatian Andesitic Complex and/or massive lagoonal environments during the Miocene. The investigated lignite is a high ash (from 32 to 58%) and sulphur (from 1.43 to 3.03%) lignite which is petrographically characterised by a high humunite content. The mineral matter of the studied lignite samples is made up of mainly clay minerals (illite-smectite and kaolinite), plagioclase and quartz in Bolu coal field, clay minerals (illite-smectite, smectite and illite), quartz, calcite, plagioclase and gypsum in Seben coal field, quartz, K-feldspar, plagioclase and clay minerals (kaolinite and illite) in K?br?sc?k, and dolomite, quartz, clinoptilolite, opal CT and gypsum in Çaml?dere coal field. The differences in these four types of lignite with specific mineralogical patterns may be due to the explosive volcanic events and depositional conditions which changed from one coal field to the others. There is a zonation from SW to SE in the studied area for zeolites such as Opal CT+smectite-clinoptilolite-analcime-K-feldspar. Carbonate minerals are commonly calcite in Seben and K?br?sc?k coal fields. In Bolu, coal samples are devoid of calcite and dolomite. These analyses show that there is an increase in the amount of Mg and a decrease in the amount of Na from the northwestern part to the southern part in the study area.