河南镇平秋树湾矿区铜、钼矿床地质特征及深部找矿潜力分析

秋树湾矿区是一座中型规模的铜、钼矿床。在水平方向上矿区具北铜南钼的分布特征,即北山铜矿床和南山钼矿床;从垂向上看,北山铜矿床深部赋存有规模较大的钼矿体,并具垂直分带现象,即上铜下钼。这主要是矿区成矿后,构造活动使南山赋矿区向上逆冲,使其上部的铜矿体被剥蚀,而北山赋矿区上部的矿体则保存了下来。因此,研究认为,在北山铜矿区的下部及南山钼矿区中深部寻找隐伏钼矿床具有较大潜力。     

河南汝阳付店-带铅锌矿床综合信息找矿模型

汝阳付店一带铅锌矿赋存于中元古界熊耳群地层中,赋矿地层主要为熊耳群鸡蛋坪组,矿体严格受断裂破碎带控制,含矿断裂带产出有三种方式。总结出区内8种找矿信息。在系统研究成矿地质条件、地球化学及地球物理综合信息的基础上,归纳并提取了控矿地质因素和物化探找矿标志,从而建立了该地区铅锌矿的地质-地球物理-地球化学找矿模型。     

辽宁小塔子沟金矿地质特征及成矿控制因素

小塔子沟金矿床位于凌源一北票金矿成矿带的中部,为受区域断裂构造、燕山期石英二长岩和太古界小塔子沟组变质杂岩所控制的含金石英脉型和蚀变岩型金矿,通过对矿床地质特征的分析,进一步总结该区成矿控制因素,认为区域上找矿前景广阔。     

甘肃东沟金矿床地质矿化特征及找矿方向

东沟构造蚀变岩-石英脉型金矿床,位于关子镇-元家坪和娘娘坝-舒家坝两条韧性剪切带与天子山和磨扇沟花岗岩体的夹持区,金矿化严格受其次级近EW向断裂控制,后期断裂构造对矿体具一定破坏作用。矿石类型地表以构造蚀变岩型为主,向深部过渡为石英脉型,褐铁矿、黄铁矿、毒砂是主要载金矿物。围岩蚀变以硅化、褐铁矿化、黄铁矿化、绢云母化为特征。中基性火山岩、韧脆性断裂构造、中酸性岩浆侵入“三位一体”是控制矿床形成的基本条件,近EW向断裂蚀变带及延伸部位是找矿有利地段。     

四川稻城竹鸡顶铜矿地质特征及成矿特点

竹鸡顶斑岩型铜矿位于西南三江成矿带内,热液蚀变以青磐岩化、泥化为特征。区内现已圈出1个矿带和2个矿化带,并有幅频激电异常、土壤铜异常与之套合。该区具有较好的找矿前景。     

牟平邓格庄金矿地质特征及找矿方向

邓格庄金矿成因类型为中温热液充填式富硫含金黄铁矿石英脉型金矿床。通过对邓格庄金矿床的地质特征、控矿因素及矿床成因的系统研究,认为矿区NNE向断裂与其他方向断裂交汇部位为金矿的有利成矿部位,在分析找矿标志的基础上,提出应加大矿区深部及外围的找矿力度,进一步查证地球物理、化学异常,以期发现新的金矿远景区,进而指出了深部找矿的方向。     

河南石板沟金矿矿床地质特征及成因探讨

在总结石板沟金矿床矿化地质特征的基础上,通过对矿石氢氧同位素测试和矿石微量元素相关分析,认为成矿热液主要来源于变质水,矿床成矿环境应属低温环境,矿床成因类型属受构造剪切带控制的低温变质热液蚀变型金矿床。     

济宁颜店铁矿地质特征及济宁岩群含矿性研究

伏于济宁滋阳山一带千米盖层之下的古元古代济宁岩群是一套低绿片岩相变质含铁岩系,主要岩石组合为千枚岩、板岩、磁铁石英岩等,其原岩为海相含灰质泥岩、砂岩类中酸性火山岩、硅铁岩等,该套岩系最大控制厚度达580m。其中赋存的条带状磁铁石英岩呈层状、似层状埋深在1612．89～1796．54m之间,共有5层铁矿,总厚度85．53m。估算预测的铁矿资源量（334）9．76亿t,mFe平均品位22．37％;低品位矿体预测的资源量（334）2．64亿t,mFe平均品位16．99％。     

邹平火山岩盆地铜矿地质成因地球物理特征探讨

邹平铜矿处于齐河-广饶深大断裂带南部的邹平火山岩盆地中,形成于破火山口火山通道充填的石英正长闪长岩岩颈中央上部,包括伟晶岩型铜矿和细脉浸染状斑铜矿床两种类型。前者矿体较小,但品位高;后者品位较低,但规模中等。含矿石英正长闪长岩等密度小、磁性弱,故在火山岩系中呈现高背景重力场上的重力低和杂乱高磁场背景中的低负异常,即“重磁同低”,且高极化。重磁同低异常区和高极化率异常带,是本区寻找铜矿的有利部位。     

New data on the correlation of skarn and gold mineralization at the Tardan deposit (northeastern Tuva)

Gold mineralization of the Tardan deposit is of different spatial occurrences and is related to different hydrothermal-metasomatic formations, the main ones being skarn-magnetite bodies, metasomatites of mineralized crush zones, and metasomatites of argillizitic-rock association. The formation of gold mineralization was a multistage process related to the repeated magmatism of the Tannu-Ola complex. It took place in a wide temperature range (400–150 °C), which determined the diversity of produced mineral assemblages. The gold mineralization associated with magnetite bodies shows a spatial correlation with magnesian and calcareous skarns and is localized in plagiogranites and gabbro-diorites of the Tannu-Ola complex intruded in the Late Ordovician. Gold mineralization that occurs in crush zones and along the fault sutures in moderate- and low-temperature hydrothermal-metasomatic rocks (propylites, beresites, serpentinites, and argillizites) formed somewhat later than skarns as a result of the intrusion of granite dike bodies. Comparative analysis of different types of gold mineralization showed both a change of mineral assemblages of the gold mineralization during the ore formation and some geochemical difference between gold and gold-bearing ores. In passing from early to late occurrences of native gold, its fineness decreases, the contents of admixtures correspondingly increase, and the gold composition changes. Gold of high-temperature rocks is rich in Cu (up to 17%), and gold of low-temperatures rocks has higher contents of Ag and Hg.