共查询到20条相似文献,搜索用时 203 毫秒
1.
玄武岩中铜矿的含矿岩系是指上二叠统峨眉山玄武岩组(P2e)上部~宣威组(P2x)底部的一套含铜背景值较高、且有明显铜矿化及铜矿层存在的含矿火山地层组合。依据容矿主岩,可分为三种类型:玄武岩型铜矿、玄武岩含碳沉积岩夹层型铜矿及沉积间断面上铝土质泥岩铜矿。 相似文献
2.
3.
赞比亚是世界著名的铜产地之一,其铜矿类型可分为层控型、沉积型、变质改造型及热液型,以沉积型为主。据现有大中型矿床铜资源量统计,沉积型矿产铜资源量占赞比亚铜总资源量的79%。各类型铜矿床总体受卢弗里安(Luflian)弧控制,层控型铜矿主要分布在穹窿核部边缘,含矿岩系为莫瓦(Muva)超群的黑云母片岩、二云石英片岩;沉积型铜矿主要分布在背斜或穹窿外缘周围,含矿岩系主要是加丹加(Katanga)超群下部的砂页岩层。 相似文献
4.
5.
牟定郝家河铜矿含矿浅色层明显受构造控制,常见与紫色层穿层接触关系,二者在物质成分和粒度成分上大致相似,说明含矿浅色层和矿床为沉积─改造成因。 相似文献
6.
7.
东川铜矿床是我国重要的沉积岩容矿的层状铜矿床(SSC),具有显著的多层位成矿特征和典型的铜硫化物分带。本研究以不同层位铜矿体的流体包裹体为研究对象,通过岩相学观察、显微测温和激光拉曼成分分析,发现东川群多层位铜矿体存在浅色和深色包裹体2种类型:浅色包裹体成分以H2O为主,含丰富的石盐子晶和少量钾盐、硬石膏子晶,代表了氧化型含矿卤水,具中低温(140~300 ℃)、中高盐度(12%~44%)的特征,属于Na +、K +、Ca 2+-Cl -(SO4 2-)型盆地卤水,主要来源于海相蒸发岩的溶解和层间建造水;深色的含有机质包裹体代表了还原型流体,来源于黑山组碳质板岩和落雪组中的藻类生物分解。东川铜矿床以落雪组的含叠层石砂质白云岩作为主要沉淀系统,黑山组碳质板岩为隔挡层,形成一个流体封闭的物理化学圈闭,氧化含矿卤水通过供给系统运移到具还原性质的沉淀系统中,与还原型富硫流体和含有机质的地层发生混合反应,形成多层位的层状铜矿体和层控脉状铜矿体。 相似文献
8.
9.
本区铜矿床赋存于震旦系昆阳群中,严格地受地层控制。主要矿体均赋存于紫色层与白云岩之间的过渡层(泥、砂质白云岩)以及其上的底部含藻白云岩中。铜的硫化物主要为斑铜矿及黄铜矿,次为辉铜矿、铜蓝及硫砷铜矿;脉石矿物主要为白云石、方解石和石英,次为黄铁矿、绿泥石和绢云母等。 相似文献
10.
11.
12.
矿区金、铜、钼矿化与碱性斑岩相关,向阳组碎屑岩是主要矿源层及赋矿地层,北东向响水断裂控矿,近东西向次级断裂及层间断裂为储(容)矿构造。多种条件耦合成矿。 相似文献
13.
云南牟定县高家铜矿地质特征及找矿标志 总被引:1,自引:0,他引:1
云南省牟定县高家铜矿属楚雄盆地砂岩型铜矿,矿体赋存于白垩系马头山组郝家河段地层中,矿体呈似层状、透镜状,矿石矿物以辉铜矿、斑铜矿、黄铜矿为主;在含矿地层中,尤其是其第一亚段中出现紫红色砂岩与灰色砂岩相互交替出现时,为重要的找矿标志. 相似文献
14.
15.
地苏嘎铜多金属矿位于三江成矿域中甸斑岩型铅锌铜多金属成矿带.含矿岩石主要为白云岩、砂质绢云板岩或石英脉等,矿床属中—低温热液充填交代与变质岩层状矿床等复合的铜多金属矿床. 相似文献
16.
石炭系阿羌岩组为本区的矿源层.灰绿色糜棱岩化强蚀变安山岩、英安岩夹中层状大理岩的绿岩组合是本区的主要含矿层位,矿体在空间分布上有明显的层控特点,是本区最具找矿意义的地层.从矿区地层岩性、变质作用、岩浆作用、脆-韧性变形作用等主要控矿因素综合分析,成矿物质来源于火山活动和沉积作用,后经变质作用和岩浆作用的改造,形成绿岩带中与火山-沉积作用有关的沉积变质型金、铜、铁矿床,同时经脆-韧性变形,具有构造蚀变岩型金铜和磁铁矿型金铁铜共生的特征,区域变质、岩浆热液、韧性剪切共同作用促使了本矿床的形成.认为本矿床属于多型共生的多元矿床. 相似文献
17.
18.
《Resource Geology》2018,68(3):258-274
The Dabaoshan deposit in Northern Guangdong Province, South China, is a Cu–Mo–W–Pb–Zn polymetallic deposit, located in the southern part of the Qin–Hang porphyry–skarn Cu–Mo ore belt. The deposit mainly comprises porphyry Mo and stratiform skarn Cu ore deposits. The genesis of the Cu ore deposit has been ascribed to a typical skarn ore deposit formed by the metasomatism of Devonian carbonate rock layers or to a volcanic rock‐hosted massive sulfide deposit formed by marine exhalation. In this paper, we report on the homogenization temperatures and salinities of fluid inclusions and C, H, O, S, and Pb isotopic compositions of fluids and minerals in this deposit. Homogenization temperatures and salinities of fluid inclusions in garnet, diopside, quartz, and calcite provide information on the skarnification, mineralization, and postmineralization stages. The data show that ore‐forming fluids experienced a continuous transition from high temperatures and salinities to low temperatures and salinities over the entire period of mineralization. C, H, and O isotopic compositions indicate that ore‐forming fluids were derived mainly from magmatic water. O isotopic compositions indicate that ore‐forming fluids mingled with atmospheric water during the last stage of mineralization. Sulfur in the ore came mainly from deep magmatic sources. Pb isotopic compositions in the orebody show that almost all the lead in the ore was derived from magma with a crustal source. Combined geological, geophysical, and geochemical data were achieved before we proposed that the Dabaoshan porphyry–skarn Cu–Mo–W–Pb–Zn deposit, as one member of the Qin–Hang porphyry–skarn Cu–Mo ore belt, formed during the Jurassic subduction of the paleo‐Pacific plate beneath the Eurasian continent at quite low angle. NE‐ and EW‐trending structures controlled the emplacement of magmatic rocks in the South China region. In the mining area, the Xiangguanping Fault and its branches were the main conduits for magmatic crystallization and mineralization. The many subfaults, folds, and interlayer fracture zones on both sides of the main fault provided the requisite space for the ore and, together, were the controlling structures of the orebody. 相似文献
19.
20.
研究区浅部以断裂破碎带控制的热液脉型Cu、Au、Pb、Ag矿床为主,深部形成斑岩型Cu、Mo矿床。矿体受地层及断裂构造双重控制。硅化、黄(褐)铁矿化与矿化关系最为密切,是主要的围岩蚀变,亦为主要的找矿标志。 相似文献