Research on zircon U-Pb, S-Pb isotopes and trace elements of pyrite from the Dongji Au(Ag) deposit in Zhenghe County, Fujian Province
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摘要:
东际金(银)矿床赋存于燕山晚期南园组火山岩中,是东南沿海地区一个隐爆角砾岩型贵金属矿床,已探明金资源量达12.5 t,银资源量135.9 t。通过开展主要金属硫化物黄铁矿电子探针和硫-铅同位素分析,讨论了成矿作用和成矿物质来源等问题。研究表明,东际金(银)矿床黄铁矿Co/Ni值3~94(平均值23)且Co含量为500×10-6~1070×10-6(均值799×10-6),Fe/(S+As)值0.827~0.871(均值0.860),Au/Ag值0.9~5.5(均值2.6),反映该矿床是与陆相火山作用有关的浅成中低温热液型矿床。黄铁矿δ34S在-6.6‰~-0.7‰,206Pb/204Pb为17.9801~18.4303,207Pb/204Pb为15.2689~15.9397,208Pb/204Pb为37.9052~38.7871,指示成矿物质主要来源于具有壳幔混源性质的花岗质岩浆,此外含矿热液也活化萃取了部分基底变质岩和火山岩围岩的金属元素。通过锆石U-Pb年代学研究和区域成矿资料对比,东际金(银)矿床成矿时代可被限定于早白垩世晚期。
Abstract:The Dongji Au(Ag) deposit is a cryptoexplosive breccia deposit in the southeastern coastal area, with reserves of 12.5 tons Au and 135.9 tons Ag, and hosted in late Yanshanian Nanyuan Formation. To discuss metallogenic and metal material source of the Dongji deposit, the authors carried out multiple isotope (S-Pb) and electron microprobe analysis (EPMA). Pyrite Co/Ni ratio is 3-94 (averaging 23), Co is 500×10-6-1070×10-6 (averaging 799×10-6), Fe/(S+As) is 0.827-0.871 (averaging 0.860), Au/Ag is 0.9-5.5 (averaging 2.6), which suggests that the Dongji Au(Ag) deposit is an epithermal deposit resulting from volcanism. δ34S of pyrite ranges from -0.7‰ to -6.6‰, 206Pb/204Pb is 17.9801-18.4303, 207Pb/204Pb is 15.2689-15.9397, and 208Pb/204Pb is 37.9052-38.7871, which suggests that metal materials were mainly derived from crust-mantle granite magma and partly from metamorphic basement and volcanic wall rocks. Based on zircon U-Pb ages of crystal tuff and granite porphyry combined with regional mineralizaton in the Zhenghe-Jianou area, the authors hold that the metallogenic epoch of the Dongji deposit should be late early Cretaceous.
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1. 引言
潮汕坳陷位于南海北部大陆边缘珠江口盆地东南部(图 1)。许多专家学者认为华南大陆边缘陆区出露的中生代晚三叠—早侏罗世的海相沉积是由海区延伸到陆区的,因而推断在南海东北部存在着中生代晚三叠—早侏罗世的海相地层(杨少坤等,2002;周蒂等,2007;钟广见等,2008)。2003年9月中国海洋石油总公司在潮汕坳陷北坡构造带上钻探的LF35-1-1井,该井的钻探直接证实了潮汕坳陷中生界残留地层的存在(郝沪军等,2009;何家雄等,2009)。由于潮汕坳陷侏罗纪地层埋藏较深且离岸距离远,全区的海水深度较大,由西北向东南逐渐加深,平均水深超过350 m。导致采集和处理的地震反射资料品质较差,信噪比低,有效波能量弱,造成潮汕坳陷侏罗系分布范围不清,其残留厚度无法确定等问题,直接影响了潮汕坳陷侏罗系沉积和储层方面的研究工作。
本文采用新近采集和重处理的最新地震资料,展开了潮汕坳陷侏罗系沉积特征研究,通过对井资料、地震资料精细解释、地震相参数的对比分析研究,结合地层厚度图编制成果,恢复了侏罗纪地层不同时期的沉积相类型及其分布特征,重塑了潮汕坳陷侏罗系沉积演化史,充分揭示了潮汕坳陷侏罗系沉积充填过程,为该区油气资源进一步勘探提供了可靠依据。
2. 区域地质概况
潮汕坳陷位于南海东北部,珠江口盆地的东南缘, 是珠江口盆地油气勘探的新领域。珠江口盆地处于华南大陆的南缘呈NE走向,它是华南大陆的水下延伸部分。潮汕坳陷西北侧和西南侧与东沙隆起相接,东南侧紧邻南部隆起带, 西边为白云凹陷,南边为兴宁凹陷。潮汕坳陷总面积约为1.38万km2,沉积岩最大厚度超过5000 m(图 1,图 2)。中国海油钻探的LF35-1-1井钻探证实,潮汕坳陷内沉积有白垩纪的陆相沉积和侏罗纪海相沉积,其中,侏罗纪海相沉积具有良好的石油地质条件(杨树春等,2008)。
3. 地震地层格架特征及地震相类型
3.1 潮汕坳陷侏罗纪地层确定
由于测井曲线纵向的连续性,利用测井曲线进行层序地层划分最为有效。在各类测井曲线中,自然伽玛(GR)和声波时差(AC)曲线对岩性、沉积物的泥质含量、分选性和粒度的反应最为敏感,曲线值变化可提供沉积环境的水动力状况、物源供给条件、沉积作用方式(进积、加积、退积)、剖面结构和沉积相演化序列等诸多方面的信息(郑荣才等,2004)。潮汕坳陷侏罗纪地层界面在LF35-1-1井测井曲线上(图 2)表现为突变面和沉积结构转换面,通过测井曲线可以清晰地划分出侏罗系层序格架,下侏罗统在测井线上主要表现为自然伽马(GR)曲线呈现指形齿化渐变反射特征,包络线以退积式为主,反映出早侏罗世沉积时期,LF35-1-1井附近是一套以泥岩为主,夹杂部分砂岩和灰岩的海相沉积地层;中侏罗统在测井线上主要表现为GR曲线呈现指形齿化突变的反射特征,包络线以前积-加积式为主,反映出中侏罗世沉积时期,LF35-1-1井下部是一套以泥岩和泥质灰岩并夹杂砂岩海相沉积地层,LF35-1-1井上部是一套以泥岩和泥-灰岩为主的海相沉积地层;上侏罗统在测井线上主要表现为GR曲线呈现指形微齿化突变反射特征,包络线以前积式为主,反映出晚侏罗世沉积时期,LF35-1-1井附近是一套以泥岩为主,夹杂部分粉砂-细砂岩及灰岩及泥质灰岩的海相沉积地层。过LF35-1-1井地震剖面(图 3)中潮汕坳陷地震反射层以Tg不整合面为界,可划分为上、下两大构造层。Tg不整合面以上为新生代地层,主要是新生界构造层沉积,Tg不整合面以下为中生界下构造层,属坳陷内沉积,在坳陷四周与上构造层呈角度不整合接触;根据地质资料、反射波终止形式和地震波阻变化特征,在侏罗系构造层序内,可以识别出4个地震层序界面,自下而上分别命名为Tj0、Tj1、Tj2和Tk0(图 3)。Tj0界面为下侏罗统与基底的分界面,界面由两个平行的强振幅反射构成,界面之上清晰的地震反射同相轴,中-低频强振幅,连续性好,界面之下为杂乱反射或空白反射不连续特征。Tj1界面为似平行整合面,其上为低频强振幅连续反射,其下为中振幅断续反射,在潮汕坳陷北部坡折带,该界面上部普遍发育上超现象,为下侏罗统和中侏罗统的分界面。Tj2界面为假整合面,其上以波状变振幅反射为主,对下伏地层的削截现象十分普遍,早期断层通常截止在这一层面附近,代表了这一时期前后,潮汕坳陷发生过规模较大的构造运动,对整个潮汕坳陷的构造格局产生了较大的影响,为中侏罗统和上侏罗统的分界面。Tk0界面为不整合面,其界面之上以波状振幅反射为主,下部显示中—高频连续反射,显示为该时期曾经较连续沉积,为侏罗系和白垩系的分界面。上述4个地震层序界面,将潮汕坳陷侏罗纪地层划分为3套地震层序,由下至上分别命名为层序MSC1、MSC2和MSC3(图 3),分别对应下侏罗统、中侏罗统和上侏罗统;通过LF35-1-1井资料和过井地震剖面,利用拟合地震记录进行了井震对比,标定了地震层序,确立了研究区侏罗纪地层格架。
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3.2 地震相类型及其与沉积相对应关系
由于潮汕坳陷侏罗系属于南海北部勘探研究的新领域和新层系,仅有位于坳陷西北缘的LF35-1-1井钻遇侏罗系,其测井、录井和岩心等资料相对不全面,因此,需要通过最新的地震资料进行研究。通过区域背景、海平面变化和水动力条件,并结合沉积物供给及构造沉降等因素,可确定不同层序内的地震相类型及其对应的沉积类型(唐武等,2012;马俊明等,2013)。通过地震波的振幅、频率和连续性等物理参数及其内部结构、外部形态等地震相参数,利用地震剖面进行了地震相识别,并进行了平面地震相带的区分,在上述侏罗系地震层序中识别出6种主要的地震相类型(图 4)。
(1)叠瓦状中频中强振幅斜交地震相:主要受物源控制,主要分布在研究区西北部,地震波组倾斜平行排列在其上下的水平地震波组之间,在平行于物源方向表现为多期次叠加的叠瓦状楔形体在扇体内部,地震波反射波形杂乱,能量相对较弱,振幅变化大,不同期次之间由强振幅同相轴隔开,为典型的滨岸三角洲沉积的地震响应特征(图 3),受西北向物源控制作用,整个扇体的前积方向主要为东南向。
(2)高频中强振幅中连续亚平行地震相:主要分布于研究区的北部,地震反射特征与滨岸三角洲相有明显区别,地震反射通常表现为不规则亚平行内部结构高频中强振幅连续的特征,常常在斜坡底部和盆地底部发育,推测对应为深水扇。
(3)高频变振幅席状地震相:该类型地震反射通常表现反射特征为高频,中—强振幅,同相轴连续性好,波组间同相轴近于平行,横向延伸稳定,分布面积较广,推测对应为浅海相。
(4)低频弱振幅中连续似平行地震相:该类型地震反射通常表现反射特征为中—低频,弱振幅,连续性中等—差,弱振幅表明地层内部缺乏强波阻抗界面,以垂向加积沉积为主,分布面积较广泛,推测对应为深海相,岩性以泥岩为主。
(5)中频中-强振幅较连续丘状-透镜状地震相:该类型地震反射通常表现反射特征以中强振幅为主,局部为弱振幅,中-高频率反射,偶尔局部可见低频反射,推测对应为浊积体,岩性以细砂岩为主,分布范围较为有限。
(6)低频弱振幅杂乱反射较连续地震相:该类型地震反射通常表现反射特征以低频弱振幅反射特征为主,整体反射界面呈现杂乱或者空白,内部隐约可见不规则似层状反射,推测对应为喷发熔岩或者火成岩,分布范围受到构造运动的控制。
3.3 地震相-沉积相在地震剖面上的特征
潮汕坳陷唯一探井LF35-1-1井揭示,潮汕坳陷中生界有两套重要的储集层,分别是白垩纪陆相河流-湖泊相砂体和侏罗纪深海和滨海-浅海相砂岩(郝沪军等,2009)。根据潮汕坳陷侏罗系地震剖面层序格架内,潮汕坳陷在侏罗纪整体上主要处于浅海欠补偿沉积环境,沉积速率较低,西北部靠近物缘的LF35-1-1井附近的滨岸三角洲砂体相对发育,其中,滨岸三角洲前缘亚相在地震剖面上显示为丘状杂乱连续的强反射的特征;前三角洲亚相为一套连续的弱反射,倾斜的反射层依次向盆地方向前积,砂体的岩性变化和横向展布都不稳定;深海相反射层呈现平行微波状,反映水体处于稳定匀速沉积的低能状态;浅海相反射层呈现中频弱振幅较连续相特征,显示出横向岩性稳定和低能的沉积环境。重力流浊积体则呈现乱岗状不规则、不连续反射,同相轴弯曲不光滑,表示,沉积量能横向变化快(图 5)。
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3.4 潮汕坳陷侏罗系分布特征
潮汕坳陷所在的南海北部大陆边缘处于欧亚板块、印度洋—澳大利亚板块和太平洋板块等三大板块之间(蔡乾忠,1998)。在晚三叠世,以雅鲁藏布江缝合带为遗迹的新特提斯洋在不断北移的冈瓦纳大陆北缘开始扩张,属于特提斯构造域东延部分的原始华南大陆南缘此时也下陷并接受沉积,海水由南向北侵入,沉积了一套滨浅海相及海陆交互相的碎屑岩。至中晚侏罗世,库拉—太平洋板块向北西俯冲至亚洲大陆之下,由于区域挤压应力的作用,本区发生挤压、隆起和坳陷,并形成一系列NE向的宽缓长轴褶皱。晚侏罗世末—早白垩世初,新特提斯洋再次强烈张开,本区亦开始沉降,海水再次由南向北侵入,并沉积了一套滨浅海相地层,不整合超覆于上三叠统—下侏罗统之上。此时,在华南沿海一带沉积了一套滨浅海相碎屑岩,在台西南盆地沉积了一套海陆过渡相砂泥岩。早白垩世末,本区开始隆升,海水向南退出,但局部地区仍有海水残存。到晚白垩世末,潮汕坳陷已完全隆起,并长期暴露地表,遭受风化剥蚀且较为严重(夏戡原等,2000;钟大赉等, 2002, ;吴国瑄等,2007)。通过前述LF35-1-1井资料与过井地震剖面井震对比和准确标定地震层序格架,利用地震资料解释成果分别编制了MSC1、MSC2和MSC3三个层位的地层残余厚度图(图 6);这些残留厚度图显示,潮汕坳陷侏罗纪沉积时期经历了多期复杂的构造运动和火山活动,剥蚀现象较为普遍,MSC3层位(上侏罗统)显示其残余厚度面积最小,说明晚侏罗世沉积时期潮汕坳陷经历了较为复杂的构造运动和火山活动,被剥蚀情况严重,研究区西北部剥蚀殆尽,而东南部厚度较大;而MSC2层位(中侏罗统)显示其残余厚度相比MSC3面积扩大,东南部厚度相对较浅,说明晚侏罗世沉积时期潮汕坳陷经历了复杂的构造运动,研究区西部被剥蚀情况严重;而MSC1层位(下侏罗统)显示其残余厚度相比MSC3和MSC1残留面积最大,呈现西北部高而东南部低的地势,研究区西部有剥蚀情况,地层厚度呈现北部薄东南部厚的特征。
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图 6 潮汕坳陷侏罗系残余地层厚度图Figure 6. The map of Jurassic residual formation thickness in Chaoshan sub-basin (See Fig. 1 for locations of profiles)4. 沉积相横向展布的控制作用
潮汕坳陷侏罗纪地层倾角资料研究表明,潮汕坳陷侏罗系的物源主要来自两个方向,分别是正北和西北方向。主要沉积相类型包括:滨岸三角洲相、深海相、浅海相、深水扇和滑塌浊积体等(陈洁,2007;何家雄等,2009;段九春等,2012;李文浩等;2014;陆宝亮等2014)。按照上述6种地震相分类,将地震剖面按照6个特征各异的地震相类型划分为不同的地震相区域,从而展示出各种地震相类型在地震层序内的平面分布情况,在结合地震响应特征和LF35-1-1井测井响应特征上的变化,以及综合考虑地层格架划分,将潮汕坳陷侏罗系纵向划分为3个具有等时地层意义的作图单元,并依此为划分依据,在各个作图单元内绘制沉积相平面分布图。
4.1 下侏罗统沉积相特征
在早侏罗世地层沉积时期,潮汕坳陷整体处于海退阶段,主要是一套以泥岩为主,夹杂部分砂岩和灰岩的海相沉积地层,其中潮汕坳陷的东南部主要是深海相沉积,西北部以浅海相沉积为主。由于远离华南大陆,物源供给并不十分充分且不均衡,来自西部的物源供应相对充分,形成的滨岸三角洲前缘亚相由西北向东南一直向坳陷深部延续到LF35-1-1井附近,而形成的前三角洲亚相则延伸更远,范围更大。而在此时期,由于海平面下降,有利于形成在无外界触发作用机制下的滨岸三角洲前缘滑塌浊积体,尤其在海退阶段,滨岸三角洲前缘向前快速推进,朵叶向前延伸较远时,在三角洲前缘向坳陷延伸范围,形成数量众多,面积不一的重力作用的滑塌浊积体沉积。在早侏罗世沉积时期,该类滑塌浊积体发育和分布在研究区西北部地区范围较广,而在北部和南部地区较少沉积。潮汕坳陷北部物源在相对海平面快速下降时期,大量的沉积物由陆架边缘三角洲经过海底峡谷以重力流的方式搬运到坳陷的深部区域,从而堆积形成盆底深水扇,而扇端亚相前缘,常常由于海水的浮力作用,滑塌形成小规模的浊积体,该浊积体发育规模较小,受控于物源通道的发育规模(图 7)。
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图 7 潮汕坳陷下侏罗统沉积相展布图Figure 7. Sedimentary facies distribution of the Lower Jurassic strata in Chaoshan Sub-basin4.2 中侏罗统沉积相特征
在中侏罗世地层沉积时期,潮汕坳陷整体处于海侵阶段,主要是一套以泥岩为主,夹杂部分砂岩和灰岩及泥质灰岩的海相沉积地层,其中潮汕坳陷的东南部深海相沉积范围比早侏罗世沉积时期有所扩大,西北部以浅海相沉积时沉积范围最广,沉积环境主要以浅海-深海欠补偿沉积。来自西部的物源供给缺乏,形成的滨岸三角洲相扇体范围萎缩,形成的前三角洲亚相则延伸范围到LF35-1-1井附近,而此时期,由于海平面上升,不利于在形成无外界触发作用机制下的滨岸三角洲前缘滑塌浊积体,仅在朵叶向前延伸的方向形成滑塌浊积体,范围和数量均少于早侏罗世沉积时期。潮汕坳陷北部物源在相对海平面快速上升时期,陆架边缘三角洲经过海底峡谷以重力流的方式堆积形成破坏型盆底深水扇,由于海水的浮力和冲刷作用,易于围绕扇端滑塌形成规模不等的浊积体,这些浊积体均为良好的储集层(图 8)。
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图 8 潮汕坳陷中侏罗统沉积相展布图Figure 8. Sedimentary facies distribution of the Middle Jurassic strata in Chaoshan Sub-basin4.3 上侏罗统沉积相特征
在晚侏罗世地层沉积时期,潮汕坳陷整体依旧处于海侵阶段,以深海相沉积为主,地层主要沉积一套以泥岩夹杂部分粉砂-细砂岩,以及在LF35-1-1井附近的灰岩及泥质灰岩的海相沉积地层,其中潮汕坳陷的深海相沉积范围最大,西北部以浅海相沉积时沉积范围缩小。来自西部的物源供给缺乏,形成的滨岸三角洲扇体范围进一步萎缩,滨岸三角洲前缘滑塌浊积体发育规模和数量相对较少,主要在朵叶附近分布。而来自北部的物源供给相对充分,滨岸三角洲相砂体由北向南,朝坳陷深部延伸并在前滨岸三角洲亚相前沿形成数量、规模不等的浊积体。潮汕坳陷北部物源在相对海平面快速上升时期,陆架边缘三角洲经过海底峡谷的物源碎屑供给增加,以重力流的方式沿海底峡谷形成盆底深水扇,在海水的浮力作用下,围绕扇端前缘滑塌形成规模不等的浊积体,且浊流砂岩为优质储集层(图 9);该类储集层由于处于欠补偿沉积环境,被周围泥岩包裹,加之埋藏较深,很容易聚集油气。
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图 9 潮汕坳陷上侏罗统沉积相展布图Figure 9. Sedimentary facies distribution of the Upper Jurassic strata in Chaoshan Sub-basin5. 结论
(1) 在潮汕坳陷侏罗系构造层序内,能够清楚识别出4个典型的地震层序反射界面,自下而上分别为Tj0、Tj1、Tj2和Tk0,以及3个反射层MSC1、MSC2和MSC3,其对应的3个地质构造层分别为下侏罗统、中侏罗统和上侏罗统。
(2) 潮汕坳陷侏罗纪地层残余地层厚度显示,多期复杂的构造运动和火山活动对本区储层的影响巨大,剥蚀现象较为普遍,MSC3层位(上侏罗统)显示其残余厚度面积最小,而MSC2层位(中侏罗统)显示其残余厚度相比MSC3面积扩大,而MSC1层位(下侏罗统)显示其残余厚度相比MSC3和MSC1残留面积最大,地层厚度呈现西北部薄东南部厚的特征。
(3) 潮汕坳陷侏罗纪地层主要发育5类沉积相、8种沉积亚相,其中滨岸三角洲前缘亚相和深水扇中亚相是优质的储层发育区,分别控制了碎屑流砂岩优质储层的发育,此外,浊流砂岩储层也是优质储集体,主要受控于物源供给的影响,距离三角洲朵叶越近,滑塌浊积体数量越多,面积也越大。
致谢: 在东际金(银)矿野外考察工作中,感谢福建省东鑫矿业技术股份有限公司朱玉磷教授级高级工程师和王波涛工程师给予的指导和帮助。两位匿名评审的修改意见使得本文质量得到很好提升,在此一并表示感谢。 -
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图 1 政和—建瓯金矿集区大地构造位置(a)和地质矿产图(b)(图a据张克信等, 2015;图b据冯志文等, 1991)
Figure 1. Tectonic location (a) and geological and mineral resources map (b) of the Zhenghe-Jianou gold ore concentration area (a after Zhang Kexin et al., 2015; b after Feng Zhiwen et al., 1991)
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图 2 东际金(银)矿床地质简图(据刘永发, 2011修改)
Figure 2. Simplified geological map of the Dongji Au(Ag) deposit (after Liu Yongfa, 2011)
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图 3 东际金(银)矿0#勘探线地质剖面图(据刘永发, 2011修改)
Figure 3. Sketch geological section along 0# geological exploration line of the Dongji Au(Ag) deposit (after Liu Yongfa, 2011)
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图 4 东际金(银)矿床主要金属矿物特征
a—自形—半自形粒状结构黄铁矿;b, c—黄铁矿被毒砂交代,黄铜矿沿毒砂颗粒边缘或者微裂隙生长,指示矿物生成顺序由早到晚依次为黄铁矿→毒砂→黄铜矿;d—黄铜矿、方铅矿交代他形粒状黄铁矿;e—银矿物沿黄铁矿裂隙生长(BSE图像);f—银矿物呈包裹体形式产于黄铁矿中(BSE图像);g, h—金矿物生长于石英颗粒间(BSE图像)。矿物代号:Py—黄铁矿;Ccp—黄铜矿;Apy—毒砂;Gn—方铅矿
Figure 4. Characteristics of main metal minerals of the Dongji Au(Ag) deposit
a-Euhedral-subhedral texture pyrite; b, c-Pyrite replaced by arsenopyrite and chalcopyrite, which suggests that the sequence of metal minerals is pyrite, arsenopyrite and chalcopyrite; d-Anhedral texture pyrite replaced by chalcopyrite and galena; e-Ag-bearing mineral growing in the fracture of pyrite (BSE image); f- Ag-bearing mineral occurring as a inclusion in the pyrite (BSE image); g, h-Au-bearing mineral growing in the quartz. Mineral abbreviation: Py-Pyrite; Ccp-Chalcopyrite; Apy-Arsenopyrite; Gn-Galena
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图 5 东际金(银)矿床矿化特征
a—黄铁矿-石英细脉;b—网脉状黄铁矿细脉;c, d, e—角砾状矿化,其中角砾已发生强烈硅化,胶结物为热液成因石英和黄铁矿;f—角砾状矿化,当岩石角砾变小和变少时,可变化为块状矿石,金含量也随之升高
Figure 5. Mineralization characteristics of the Dongji Au(Ag) deposit
a-Pyrite-bearing quartz vein; b-Stockwork pyrite; c, d, e, f -Breccia mineralization, silicification breccias cemented by hydrothermal quartz and pyrite. The breccias become smaller and less in the breccia zone, whereas the Au grade is higher
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图 6 晶屑凝灰岩(a, b, c)和花岗斑岩(d, e, f)产状及矿物组成
Q—石英;Pl—斜长石;Bt—黑云母;γπ—花岗斑岩
Figure 6. Geological characteristics and minerals of crystal tuff and granite porphyry
Q-Quartz; Pl-Plagioclase; Bt-Biotite; γπ-Granite porphyry
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图 7 东际金(银)矿床208Pb/204Pb-206Pb/204Pb和207Pb/204Pb-206Pb/204Pb图解
(大药坑数据肖凡等, 2017, 邻区金矿、晶屑凝灰岩、二长斑岩和石英闪长岩铅同位素数据冯志文等, 1991, 马面山岩群绿片岩、石英片岩、灰绿色片岩铅同位素数据丰成友等, 2007)
Figure 7. Plot of 208Pb/204Pb versus 206Pb/204Pb and 207Pb/204Pb versus 206Pb/204Pb of the Dongji Au(Ag) deposit
(Dayaokeng Au deposit data after Xiao Fan et al., 2017; adjacent Au deposits, crystal tuff, monzonite porphyry and quartz diorite data after Feng Zhiwen et al., 1991; Mamianshan Group metamorphic rock data after Feng Chengyou et al., 2007)
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图 8 东际金(银)矿床中不同类型黄铁矿岩相学特征
Figure 8. Petrographic characteristics of different types of pyrites from the Dongji Au(Ag) deposit
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图 9 东际金(银)矿床不同类型黄铁矿微量元素变化曲线
Figure 9. Plot of trace elements of different kinds of pyrites in the Dongji Au(Ag) deposit
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图 10 东际金(银)矿床晶屑凝灰岩锆石CL图和U-Pb谐和图
Figure 10. Zircon CL images and U-Pb concordia diagram of crystal tuff from the Dongji Au(Ag) deposit
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图 11 东际金(银)矿床花岗斑岩锆石CL图和U-Pb谐和图
Figure 11. Zircon CL images and U-Pb concordia diagram of granite porphyry of the Dongji Au(Ag) deposit
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图 12 东际金(银)矿床黄铁矿Co-Ni图解和As-Co-Ni图解
(紫金山铜金矿黄铁矿数据张文媛等,2014)
Figure 12. Plot of Co-Ni and As-Co-Ni of pyrites from the Dongji Au(Ag) deposit
(Zijinshan Cu-Au deposit data after Zhang Wenyuan et al., 2014)
表 1 东际金(银)矿床黄铁矿硫、铅同位素特征
Table 1 Sulfur and lead isotope data of pyrites from the Dongji Au(Ag) deposit
下载: 导出CSV
表 3 东际金(银)矿床晶屑凝灰岩和花岗斑岩锆石U-Pb数据
Table 3 Zircon U-Pb data of crystal tuff and porphyry granite of the Dongji Au(Ag) deposit
下载: 导出CSV
表 4 典型金矿床黄铁矿Fe、As、S和Fe/(As+S)含量
Table 4 Content of Fe, As, S and Fe/(As+S) of pyrites from typical gold deposits
下载: 导出CSV
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