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1.
报道了徐淮地区早白垩世埃达克质岩中首次发现的含橄榄石单斜辉石岩捕虏体的岩相学与矿物化学资料, 该类捕虏体显示堆积结构、块状构造, 主要由单斜辉石(~80%)、斜方辉石(~5%)、橄榄石(~5%)和普通角闪石(~10%)组成.橄榄石外侧发育有斜方辉石反应边, 角闪石沿辉石粒间分布, 呈嵌晶结构.矿物化学分析结果表明: 橄榄石的镁橄榄石分子值(Fo)=77.7~79.3, Ni=623×10-6~773×10-6; 斜方辉石的Mg#=75.6~80.2, Cr=161×10-6~684×10-6, Ni=79×10-6~708×10-6; 单斜辉石的Mg#=84.5~86.4, CaO=21.59%~23.13%, Al2O3=1.72%~2.44%.上述矿物与中、新生代玄武岩中橄榄石、斜方辉石和单斜辉石斑晶以及堆积成因辉石岩中的斜方辉石和单斜辉石成分类似.此外, 单斜辉石的稀土配分型式以相对富含中稀土元素的上凸型为特征, 稀土元素含量较低(∑REE=10.14×10-6~12.71×10-6), 无明显的铕异常(δEu=0.90~1.16), 类似于新生代玄武岩中单斜辉石斑晶.捕虏体中的普通角闪石的Mg#=74.0~80.4、SiO2=43.2%~44.5%、Na2O=2.04%~2.29%, 稀土元素分馏不明显, 显示亏损高场强元素(HFSEs, 如Nb、Ta、Zr、Hf), 富集Sr、Rb、Ba的特征, 与新生代玄武岩中角闪石捕虏晶成分不同.结合其嵌晶结构, 普通角闪石应是寄主岩浆贯入结晶的产物.综合上述特征, 可以看出含橄榄石单斜辉石捕虏体为镁铁质岩浆高压堆晶成因.结合华北克拉通东部早白垩世双峰式火山岩组合的出现, 推断含橄榄石单斜辉石岩捕虏体可能是早白垩世基性岩浆底侵的产物. 相似文献
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吉林红旗岭1号和7号岩体中含矿超镁铁质岩的矿物化学特征:对岩浆演化过程以及铜镍硫化物矿床形成机制的约束 总被引:2,自引:1,他引:1
本文对吉林红旗岭1号和7号岩体中含矿超镁铁质岩的主要造岩矿物进行了详细研究。两岩体的主要造岩矿物为贵橄榄石、古铜辉石、单斜辉石、斜长石、角闪石和金云母。岩浆的暗色矿物结晶顺序为:橄榄石→斜方辉石→单斜辉石→角闪石→黑云母,与镜下实际观察一致,是岩浆在不同深度结晶的产物。原始岩浆来自上地幔,两岩体进入高位岩浆房中的熔体的MgO含量分别13.98%和14.22%、Mg#值分别为72.22和71.05,为含水的高镁的苦橄质玄武岩浆。深部岩浆房深度距地表约26~27km,岩浆房内的结晶温度介于1280~1379℃之间,即结晶于下地壳中。岩浆由深部上升到高位(浅部)岩浆房中的过程是近绝热的,也是快速完成的。岩浆可能经历了两次岩浆房的演化过程,岩浆在上升到高位岩浆房之前,在深部曾经历了较短时间的橄榄石和少量辉石的分离结晶作用;但在高位岩浆房中混染了地壳物质,与此同时,还经历了同源岩浆混合作用以及岩浆过冷却作用,这些都有利于岩浆体系中成矿元素含量增高以及硫达到饱和状态,使金属硫化物熔离并晶出,从而使岩体发生铜镍矿化作用。 相似文献
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义敦岛弧形成于晚三叠世大规模俯冲造山作用过程中,位于松潘甘孜地体和羌塘地体之间。稻城边部岩体是义敦岛弧带内规模巨大的复式花岗质岩体,由花岗岩、花岗闪长岩和钾长花岗岩组成。大量暗色镁铁质微粒包体发育于花岗闪长岩和钾长花岗岩中,且其与寄主岩石的接触界线明显。暗色镁铁质微粒包体具有细粒结构,发育石英眼构造、针状磷灰石和具环带结构的斜长石斑晶。文中以稻城岩体寄主岩石和暗色微粒包体中斜长石、黑云母和角闪石为研究对象,开展岩相学和电子探针原位化学成分分析,厘定了矿物形成的物理化学条件,探讨了岩浆混合作用过程及其形成的构造环境。研究表明:花岗闪长岩和暗色微粒包体中的斜长石主要为中长石,其核部呈浑圆状;前者核部的An值(21~50)显著高于幔部(21~34);后者则发育典型的突变环带,An值(29~44)呈波状变化且相对集中。暗色微粒包体与寄主花岗闪长岩中斜长石的An值部分重叠表明二者形成过程中存在含量的岩浆混合作用。斜长石环带中的An值随Al2O3、FeO、MgO和CaO含量的升高而升高,但随SiO2、Na2O和K2O含量的升高而降低。寄主岩石和暗色微粒包体中角闪石富镁铁,阳离子特征为:CaB=1.56~1.75,Ti=0.08~0.13,属于钙质角闪石,具壳源特征,其结晶温度分别为697~725 ℃和680~705 ℃。花岗闪长岩中黑云母的Mg/(Mg+Fe2+)为0.37~0.45,显示出富Fe贫Ca、Mg,属于典型的岩浆成因黑云母。黑云母TiO2含量变化范围为3.54%~4.62%,Al2O3含量变化范围为13.89%~15.15%;黑云母的氧化系数为0.08~0.11,Mg#为0.39~0.46,MF值为0.36~0.44,单位分子中阳离子数AlⅥ为0.03~0.11,以单位分子中Ti和Al阳离子数计算的黑云母结晶温度为584~624 ℃,表明其结晶温度较高,具壳幔混源特征。稻城岩体是以壳源为主的壳幔混源成因的I型花岗岩,暗色微粒包体是由镁铁质岩浆与长英质岩浆不同程度的混合作用形成的。 相似文献
4.
西昆仑普鲁新生代火山岩的矿物化学特征及其对岩浆演化过程的约束 总被引:2,自引:0,他引:2
对西昆仑普鲁新生代火山岩的矿物学进行了系统的研究。结果表明:该地区火山岩主要由橄榄石、单斜辉石和斜长石组成,并有少量的斜方辉石、黑云母、角闪石、碱性长石和铁钛氧化物。其矿物学特征指示了岩浆的性质有点类似于碱性岩浆,但与典型的碱性玄武岩又有明显的区别,属于橄榄安粗岩系列。利用橄榄石-熔体平衡原理估算了进入高位岩浆房中的熔体的MgO含量约为6.2%,Mg^#为0.57,说明其不是地幔熔融形成的原始岩浆,而是经历了深部岩浆房的分离结晶过程。由单斜辉石估算的高位岩浆房的深度约7~9km。岩浆在高位岩浆房中发生了较长时间的强烈分离结晶作用,分离结晶相主要为橄榄石、单斜辉石和斜长石以及少量的斜方辉石、黑云母、角闪石、碱性长石和铁钛氧化物。不同时期形成的铁钛氧化物指示了分离结晶过程由相对高温高氧逸度向相对低温低氧逸度演化。与此相对照的是岩浆在深部岩浆房中可能只发生了橄榄石和辉石等铁镁矿物的分离结晶作用,且分异作用时间较短。深部岩浆房可能存在于岩石圈地幔或壳幔过渡带中,岩浆由深部岩浆房上升到高位岩浆房中的过程是近绝热的,从浅部岩浆房到地表是快速上升的过程。 相似文献
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铬铁矿作为蛇绿岩中的重要矿产,其成矿母岩浆性质及演化一直存在较大争议.铬铁矿的矿物包裹体同时或先于铬铁矿结晶,其成分和类别能很好地记录成矿母岩浆性质和演化过程.土耳其Pozant?-Karsant?蛇绿岩不同类型铬铁岩的铬铁矿中发现了多种类型包裹体:不含水硅酸盐矿物(如橄榄石和单斜辉石)、含水硅酸盐矿物(如角闪石和金云母)、复合型矿物包裹体(如蛇纹石、硅灰石和单斜辉石的复合型包裹体)和不常见矿物(如磷灰石、铂族元素硫化物).含水矿物包裹体的出现以及矿物的高Mg#特征(如橄榄石Fo=95.4~97.1;单斜辉石Mg#=92.0~99.9;角闪石Mg#=88.9~99.8)表明结晶铬铁矿的母岩浆具有富水、富Mg的特征.同时,除钙铬榴石和磷灰石的包裹体外,在铬铁矿中首次发现富Ca矿物方解石和硅灰石,其中方解石和菱镁矿以复合型包裹体形式产出,硅灰石则分布于蛇纹石矿物包裹体中.这些富Ca矿物的出现以及硅酸盐矿物的高CaO含量均揭示了铬铁岩母岩浆的富Ca特征.母岩浆中的Ca组分可能来源于俯冲板块中富Ca岩石/矿物的部分熔融,Ca离子的大量出现使得Cr3+在熔体中更加稳定,同时富Ca矿物的结晶促进了岩浆中Cr的进一步富集而利于铬铁矿的大量结晶沉淀. 相似文献
6.
东昆仑造山带以广泛发育富含镁铁质包体的早-中三叠世花岗岩为主要特征,但目前尚缺乏对不同类型镁铁质包体系统的岩相学和矿物学研究.在本文中,我们选择了极具代表性的香加花岗岩体及其中包体为研究对象,从岩相学和矿物化学角度揭示了东昆仑地区壳幔岩浆相互作用的详细过程.研究表明包体发育眼球状石英、韵律环带斜长石和针状磷灰石等不平衡结构和快速结晶现象,指示存在岩浆混合作用,而似辉绿辉长结构包体代表了岩浆混合的基性端元.此外,长石的多阶段生长证明可能存在多次的岩浆混合过程.镁铁质包体相对寄主岩(Mg#值为0.39~0.56,Fe#值为0.44~0.62)具高Mg#和低Fe#特征.包体具有两类角闪石:一类结晶源自早期深部幔源岩浆(TiO2=2.1%~2.9%,SiO2=41.75%~44.49%),另一类则起源于浅部壳幔混合作用(TiO2=1.0%~1.8%,SiO2=42.49%~48.10%).部分黑云母具有高镁特征(MgO=9.78%~11.53%,Mg#=0.462~0.541),与幔源成因黑云母成分相当.斜长石的韵律环带及化学组成指示其岩浆混合成因.幔源基性岩浆在5×108 bar(约18 km)左右深度结晶并形成高钛角闪石,玄武质岩浆底侵上升,并发生壳幔岩浆混合作用,混合的岩浆上升至2.5×108 bar(约8 km)左右深度结晶形成低钛角闪石.以上证据指示,东昆仑地区在三叠纪时期可能经历了多期次的岩浆混合作用,地幔岩浆的注入在地壳深熔作用和地壳生长过程中扮演了重要角色.广泛的壳幔岩浆相互作用可能是三叠纪时期阿尼玛卿洋板片断离的重要响应. 相似文献
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报道了徐淮地区早白垩世埃达克质岩中首次发现的含橄榄石单斜辉石岩捕虏体的岩相学与矿物化学资料,该类捕虏体显示堆积结构、块状构造,主要由单斜辉石(~80%)、斜方辉石(~5%)、橄榄石(~5%)和普通角闪石(~10%)组成.橄榄石外侧发育有斜方辉石反应边,角闪石沿辉石粒间分布,呈嵌晶结构.矿物化学分析结果表明:橄榄石的镁橄榄石分子值(Fo)=77.7~79.3,Ni=623×10-6~773×10-6;斜方辉石的Mg#=75.6~80.2,Cr=161×10-6~684×10-6,Ni=79×10-6~708×10-6;单斜辉石的Mg#=84.5~86.4,CaO=21.59%~23.13%,Al2O3=1.72%~2.44%.上述矿物与中、新生代玄武岩中橄榄石、斜方辉石和单斜辉石斑晶以及堆积成因辉石岩中的斜方辉石和单斜辉石成分类似.此外,单斜辉石的稀土配分型式以相对富含中稀土元素的上凸型为特征,稀土元素含量较低(∑REE=10.14×10-6~12.71×10-6),无明显的铕异常(δEu=0.90~1.16),类似于新生代玄武岩中单斜辉石斑晶.捕虏体中的普通角闪石的Mg#=74.0~80.4、SiO2=43.2%~44.5%、Na2O=2.04%~2.29%,稀土元素分馏不明显,显示亏损高场强元素(HFSEs,如Nb、Ta、Zr、Hf),富集Sr、Rb、Ba的特征,与新生代玄武岩中角闪石捕虏晶成分不同.结合其嵌晶结构,普通角闪石应是寄主岩浆贯入结晶的产物.综合上述特征,可以看出含橄榄石单斜辉石捕虏体为镁铁质岩浆高压堆晶成因.结合华北克拉通东部早白垩世双峰式火山岩组合的出现,推断含橄榄石单斜辉石岩捕虏体可能是早白垩世基性岩浆底侵的产物. 相似文献
8.
目前关于内蒙古东乌旗晚古生代花岗岩中辉石橄榄包体的精确年代学及其构造意义不清,直接制约了该区晚古生代地幔性质及构造演化的探讨.对东乌旗新发现的辉石橄榄岩进行了岩相学、全岩地球化学和锆石U-Pb定年研究.结果表明,辉石橄榄岩主要由橄榄石、角闪石、斜方辉石及少量斜长石、黑云母、单斜辉石组成;锆石U-Pb年龄为317.8±1.6 Ma,属晚石炭世.地球化学数据显示,岩石SiO2含量为40.28%~44.50%、MgO含量为23.42%~29.44%、Na2O+K2O含量为1.00%~2.12%(小于3.5%),具有低m/f比值(3.13~3.86)和高FeOT含量(11.18%~14.70%)、高Mg#值(75.60~79.26),属铁质超镁铁岩和拉斑玄武岩系列.岩石稀土总量较高(∑REE=31.98×10-6~72.60×10-6),轻稀土(LREE)相对于重稀土(HREE)富集,(La/Yb)N=3.56~7.72,Eu异常不明显(δEu=0.79~1.65),球粒陨石标准化稀土元素配分模式表现为右倾型.岩石富集大离子亲石元素Rb、Sr、K等,相对亏损高场强元素Nb、Ta,具明显的Nb、Ta、Ti负异常;其形成于受俯冲流体改造的岩石圈地幔的减薄作用,并且岩浆在演化过程中遭受了地壳物质的同化混染作用. 相似文献
9.
新疆黄山杂岩体矿物学特征及其意义 总被引:1,自引:0,他引:1
黄山杂岩体造岩矿物有橄榄石、斜方辉石、单斜辉石、斜长石、角闪石和黑云母。其中斜方辉石的多色性不是由Fe~(2+)引起,而是由Ti~(4+)引起。单斜辉石结晶后常与岩浆继续发生化学反应,形成一种岩浆岩结构——角闪反应补丁结构。橄榄石中镍含量的亏损程度反映杂岩体曾经历过硫化物熔离作用。单斜辉石Si,Al~Ⅳ,Ti的变化表明杂岩体属于拉斑玄武岩系列。超镁铁岩中K,Ba,Th,Hf等元素反常的地球化学行为是由该岩石中黑云母矿物引起。 相似文献
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甘肃北山红柳沟基性-超基性岩体位于塔里木板块北缘北山裂谷带, 岩体侵位于敦煌岩群,主要岩石类型有辉长岩、橄榄辉长岩、橄榄苏长辉长岩、橄榄角闪苏长岩、橄榄辉长苏长岩、二辉橄榄岩、橄榄辉石岩和辉石岩等。橄榄石Fo介于66.97%~82.92%之间,属贵橄榄石,斜方辉石En成分范围为68.49~77.65,属古铜辉石;单斜辉石En成分范围为45.85~48.81,主要为斜顽辉石和透辉石;斜长石An为58.70~72.69,以拉长石为主;角闪石以普通角闪石为主。岩体母岩浆Mg#值为0.59~0.62,属于高镁拉斑玄武质岩浆,岩浆演化过程中主要发生了橄榄石、斜方辉石、单斜辉石和斜长石的分离结晶作用,主要分离结晶矿物受单斜辉石和斜方辉石的控制,岩浆上升侵位过程中遭受到下地壳物质混染。从构造环境、母岩浆、岩体类型、岩浆分异程度、同化混染等方面综合分析认为红柳沟岩体具有形成铜镍硫化物矿床的较大潜力。 相似文献
11.
金岭杂岩体由细粒黑云角闪闪长岩、中细粒黑云角闪闪长岩、中细粒黑云角闪二长闪长岩和细粒角闪二长闪长岩组成,是鲁西地区典型矽卡岩型富铁矿(金岭铁矿)控矿岩体。本次研究对细粒黑云角闪闪长岩和细粒角闪二长闪长岩进行了锆石LA‐ICP‐MS U‐Pb定年,其结果分别为129.2±3.2 Ma和132.8±1.2 Ma,表明该杂岩体的侵位时代为早白垩世。样品SiO2、K2O和Na2O含量分别介于54.17%~63.73%、1.92%~4.76%和3.10%~5.41%之间,K2O/Na2O为0.58~0.94,A/CNK为0.60~0.93,具有轻稀土富集,重稀土亏损的右倾型稀土配分模式,轻、重稀土分馏程度中等((La/Yb)N=9.94~23.49),Eu异常不明显(δEu=0.84~1.10),具中—弱负Ce异常(δCe=0.56~0.92)。样品以富集大离子亲石元素(Ba、K、U、Pb等)、亏损高场强元素(Nb、Ta、Ti)以及高Sr/Y为特征。金岭杂岩体为燕山晚期岩浆活动产物,属准铝质高钾钙碱性系列,岩浆主要来源于富集岩石圈地幔的部分熔融,并在岩浆上升侵位的过程中有地壳物质的同化混染。燕山晚期华北克拉通在古太平洋板块俯冲后后撤引起的板内伸展环境下,增厚陆壳减薄阶段,岩浆上侵就位形成金岭杂岩体。 相似文献
12.
华北克拉通中部造山带发育的早白垩世钾质岩是研究华北克拉通中部幔源岩浆成因的天然样品,然而其成岩物理化学条件仍不明确。本文选取了涞源县龙门岩体中闪长岩和二长岩开展了矿物原位地球化学和锆石微量元素分析,以探讨矿物形成的温压条件及氧逸度与矿化的关系。分析结果显示,二长岩和闪长岩的锆石Th/U比值较高(>0.1),轻稀土亏损、重稀土富集,具明显的Ce正异常和Eu负异常特征,并具有明显的震荡环带,为典型岩浆成因锆石。电子探针结果显示,龙门岩体中斜长石主要为中性斜长石,黑云母为原生镁质黑云母,角闪石主要为钙铁闪石。闪长岩中角闪石结晶温度为793~842℃,压力为0.50~0.75GPa,深度范围为19~28km,具有较低氧逸度(log f O 2为-12.21~-11.38)和高的含水量(8.5%~10.75%);二长岩中黑云母结晶温度为764~788℃,具有更低的氧逸度(log f O 2=-15.14~-14.54);闪长岩和二长岩中锆石结晶温度为770~978℃,具有较低的氧逸度(ΔFMQ=-0.37~+1.70)。矿物化学分析表明,角闪石和黑云母虽都在地壳开始结晶,但角闪石形成于比黑云母更深的岩浆房。龙门岩体中角闪石、黑云母和锆石的结晶主要受岩浆分异控制,其地球化学动力学机制主要为岩浆上侵时减压熔融,进而引起岩浆氧逸度随岩浆演化而变化。随着岩浆上涌,闪长岩中角闪石随着温度降低和压力减少逐渐结晶,地幔交代作用导致二长岩中的黑云母具有较高的X Mg值,进而形成镁质黑云母。结合区域地质背景,古太平洋板块(伊佐奈琦板块)俯冲-后撤释放的流体交代上覆岩石圈地幔对中部造山带钾质岩(~141Ma)的形成有一定贡献,该过程导致了岩浆具有较高的含水量,但龙门岩体低的氧逸度和区域上较厚的岩石圈制约了成矿金属物质(Fe-Au等)的迁移和富集,因而不利于亲硫、亲铁元素聚集以及铁、金矿化的形成。 相似文献
13.
阿热岩体呈NNE方向展布于义敦岛弧带中甸弧南端,与相邻格咱断裂方向一致。岩体主要发育有角闪闪长玢岩、辉石闪长玢岩、含辉石角闪闪长玢岩及石英闪长玢岩。本文根据岩体内斑晶分布特征,选择角闪闪长玢岩、辉石闪长玢岩及含辉石角闪闪长玢岩及其析离体中的角闪石和单斜辉石进行岩相学及矿物化学研究,其结果显示岩体中角闪石及单斜辉石均分为高Mg#及低Mg#两类,角闪石及辉石均发育与岩浆混合作用相关的不平衡结构,存在同源异相岩浆混合作用,分异结晶作用不明显;成岩岩浆与三叠纪俯冲的甘孜-理塘洋壳板片有关,俯冲过程中板片脱水形成的流体及部分熔融形成的熔体与地幔楔交代是其岩浆形成的重要机制,其岩浆过程主要受构造应力控制,由不富水或局部富水岩浆向富水岩浆演化,具高MgO及SiO2/Al2O3向低MgO及SiO2/Al2O3演化的特点;角闪石温度压力估算结果显示先形成的低Mg#角闪石结晶压力远大于高Mg#角闪石。根据岩浆侵位的构造、压力环境及其动力学背景,我们认为甘孜-理塘洋壳向西俯冲过程中由于中咱地块西侧的羌塘地块于中三叠时期(~230Ma)开始向东挤压碰撞,在此过程中洋壳板片可能发生断离,导致该区背景构造挤压应力在228~219Ma期间先增大后变小。 相似文献
14.
不同成因类型的花岗岩组合,反映出不同的物源组成或迥异的岩浆演化过程。为了进一步探讨西秦岭造山带中生代花岗质侵入岩的成因、矿物结晶条件和地球动力学背景,选择西秦岭东部碌础坝岩体内的石英闪长岩和花岗闪长岩为研究对象,对其开展详细的野外地质调查以及系统的岩相学、矿物学和岩石地球化学研究。研究结果表明:碌础坝石英闪长岩和花岗闪长岩的SiO2含量范围为59.65%~67.36%,A/CNK为0.82~1.04,K2O/Na2O=1.11~1.74,Mg#值为47~53,显示出准铝质-弱过铝质特征,属于高钾钙碱性岩石,其中花岗闪长岩为I型花岗岩;岩体具有富集Rb、Th、U、K和Pb等元素,亏损Nb、Ta、P和Ti等元素的特征,具有中等Eu负异常(δEu=0.50~0.77),轻重稀土分馏明显((La/Yb)N=9.43~30.37)。碌础坝花岗质岩石中斜长石的An值介于18~53之间,以中长石为主,部分斜长石显示振荡环带;角闪石为镁角闪石,部分角闪石具有环带结构,且核部Mg/(Mg+Fe2+)值较高(0.88~0.91)并具有富钙特征(CaO含量为17.80%~22.67%),但Al2O3含量较低,指示角闪石核部与边部的形成环境具有明显差异;黑云母Mg/(Mg+Fe2+)值为0.44~0.57,为镁质黑云母。碌础坝花岗质岩石中全岩和各类矿物的温度计算结果显示,全岩锆饱和温度为736~795 ℃,角闪石结晶温度为704~824 ℃,黑云母结晶温度为700~746 ℃。三种方法计算的结晶温度相近,表明岩体形成于中温环境。碌础坝岩体角闪石全铝压力计结果为1.0~3.5 kbar(1 bar=100 kPa),平均形成深度为6.8 km;黑云母结晶压力为0.9~1.4 kbar,平均形成深度为4.1 km。角闪石湿度及氧逸度计显示其相对氧逸度为ΔNNO=0.1~1.3,含水量为3.9%~6.3%。结合前人资料,认为西秦岭碌础坝岩体由角闪岩为主的变基性岩部分熔融形成,幔源组分的参与导致其具有高Mg#值、高Cr和Ni等元素含量的特征。碌础坝岩体形成于洋-陆俯冲向陆-陆碰撞转换的阶段。 相似文献
15.
东昆仑沟里地区暗色包体及其寄主岩石地球化学特征及成因 总被引:2,自引:0,他引:2
通过青海东昆仑东部沟里地区阿斯哈岩体中寄主闪长岩和暗色微粒包体的岩相学、全岩地球化学研究,确定了岩石成因及其构造属性。阿斯哈岩体中暗色包体广泛分布,包体岩性主要为角闪辉长岩。包体具有岩浆结构,部分包体具有塑性流变特征,包体中可见寄主岩石矿物的捕掳晶和针状磷灰石,表现出岩浆混合的岩相学特征。主岩及暗色包体同属准铝质、高钾钙碱性-钾玄岩系列过渡岩石,主量元素在Harker图解及Al2O3/K2O-CaO/K2O和SiO2/CaO-K2O/CaO的共分母协变图上具良好的线性关系,反映两者成分的变化与岩浆混合作用有关。两者的稀土元素配分模式总体一致,显示二者密切的成因联系。两者都富含大离子亲石元素(Rb、K),相对亏损高场强元素(Nb、Ta、P、Ti)。暗色包体具有贫硅(w(SiO2)=50.70%~53.88%)和富镁、铁、钙的地球化学特征,其Mg#值较高(Mg#=0.52~0.59),暗示其来源于俯冲带流体交代地幔楔的部分熔融。主岩的Rb/Sr值为0.22~0.27,接近地壳平均值,Nb/Ta值为14.5~15.2,介于地幔平均值与地壳平均值之间,表明寄主岩石岩浆具有壳源岩浆的性质并经历了幔源岩浆的混合作用。结合区域构造演化及构造判别,认为阿斯哈岩体形成于安第斯型活动大陆边缘的构造环境。早三叠世,阿尼玛卿洋向北俯冲,俯冲带流体交代地幔楔,导致其部分熔融形成基性岩浆,底侵的幔源基性岩浆诱发下地壳部分熔融并与之发生混合形成本区闪长岩,而其中的暗色包体为幔源岩浆混合不彻底的产物。 相似文献
16.
房山岩体位于华北克拉通燕山构造带内,在平面上为不对称环状分布的复式侵入体.其主要由多期侵入的花岗闪长质岩石组成,被划分为中央相、过渡相和边缘相3个岩相带,岩体内部分布大量的暗色镁铁质微粒包体.黑云母作为中酸性火成岩中重要的镁铁质矿物,其矿物化学特征可以记录岩浆属性以及岩石形成时的物理化学条件.本研究对房山花岗岩体和暗色镁铁质微粒包体中的黑云母进行了系统的岩相学观察,并通过电子探针分析对黑云母的化学组成进行了详细研究,从而探讨房山花岗岩体的岩浆来源以及岩浆混合作用过程.结果表明,花岗岩体和暗色镁铁质微粒包体中的黑云母具有相似的矿物化学成分.花岗岩体中的黑云母富Mg,贫Fe,属于镁质黑云母.从外向内3个相带的花岗岩中黑云母的含铁系数[(Fe3++Fe2+)/(Fe3++Fe2++Mg2+)]分别为0.42~0.47,0.45~0.47,0.41~0.46.FeOT/MgO均接近0.60.MF值[2×Mg/(Fe2++Mg+Mn)]分别为1.05~1.21,1.06~1.15,1.12~1.23,指示3个相带的花岗岩的物质来源均发生了壳幔混染.从外向内3个相带中的暗色镁铁质微粒包体中的黑云母富Mg,贫Fe,属于镁质黑云母,含铁系数[(Fe3++Fe2+)/(Fe3++Fe2++Mg2+)]分别为0.44~0.48,0.45~0.50,0.44~0.52.FeOT/MgO均接近0.60.MF值[2×Mg/(Fe2++Mg+Mn)]分别为1.00~1.16,1.03~1.15,1.10~1.18,说明包体的岩浆受到了中酸性岩浆的影响,发生了岩浆混合.花岗岩体与暗色镁铁质微粒包体中的黑云母矿物化学特征相似,但不同岩相带之间存在差异,推测该区域发生了一个多阶段的岩浆相互作用过程,可能为幔源基性岩浆注入壳源酸性岩浆,在岩浆房内以不同程度进行了岩浆混合. 相似文献
17.
The Han-Xing region is located in the south Taihang Mountains (TM) in the central part of the North China Craton, and is an important iron producing area. The iron deposits in this region are of skarn type, related to an Early Cretaceous high-Mg diorite complex, including gabbro diorite, hornblende diorite, diorite, diorite porphyrite, and monzonite. In this study we report the detailed mineral chemistry of the high-Mg diorites and skarn rocks. The olivine in the gabbro diorite shows chemical composition similar to that in mantle peridotite xenoliths. Clinopyroxene in the gabbro diorite is dominantly augite, with only minor diopside, whereas the clinopyroxenes in the diorite and monzonite are diopside. Amphiboles in the high-Mg diorites show compositional range from magnesiohornblende to magnesiohastingsite, with minor pargasite and tschermakite. Most plagioclase in the high-Mg diorite is andesine and oligoclase. The magnesio-biotite in gabbro diorites shows chemical characteristics of re-equilibrated primary biotites and those in calc-alkaline rocks. In the diorite and diorite porphyrite, plagioclase shows complex chemical zoning. Clinopyroxene and garnet in skarn rocks show varying FeO contents, the former containing low FeO (< 9 wt.%) and occurring as the major skarn mineral in large-scale iron deposits, and the latter within small-scale iron deposits with high FeO (mostly > 25 wt.%) content. We computed the pressure, temperature, oxygen fugacity and water contents based on the mineral chemistry of amphibole and biotite. Based on the results, the magma crystallization can be divided into two stages, one within the deep magma chamber, forming clinopyroxene, amphibole and plagioclase phenocrysts; the other after emplacement, forming the rim of phenocrysts and matrix minerals. The magma during the early stage shows high temperature (~ 900 °C–950 °C), pressure (~ 300 MPa–500 MPa), relatively high logfO2 (NNO–NNO + 2), and H2O content in melt (4%–8%). During the late stage, the magma temperature dropped to about 750 °C, and pressure came down to less than 100 MPa, with the logfO2 rising to NNO + 1–NNO + 2.The zoning of amphibole and plagioclase records the process of magma mixing and crystallization, with injection of mafic magma into the felsic magma chamber. The relatively high logfO2 and H2O content inhibited partitioning of iron into mafic minerals and favored concentration of Fe in the melt. Iron ore precipitation occurred when the magma was emplaced at shallow level, and was principally controlled by the chemical composition of carbonate wall rocks. The high logfO2, Fe3 + rich ore-forming fluid generated andradite and clinopyroxene when it reacted with limestone and dolomitic limestone respectively. 相似文献
18.
Akira IMAI 《Resource Geology》2000,50(1):1-23
Abstract: The Mamut deposit of Sabah, East Malaysia, is a porphyry type Cu‐Au deposit genetically related to a quartz monzonite (“adamellite”) porphyry stock associated with upper Miocene Mount Kinabalu plutonism. The genesis of the Mamut deposit is discussed based on petrology of the intrusives in the Mount Kinabalu area combined with ore– and alteration–petrography, fluid inclusion and sulfur isotope studies. Groundmass of the adamellite porphyry at Mamut is rich in K which suggests vapor transport of alkaline elements during the mineralizing magmatic process, while the groundmass of the post‐ore “granodiorite” porphyry at Mamut contains small amounts of normative corundum suggesting depletion in alkaline elements at the root zone of the magma column. Sub‐dendritic tremolitic amphibole rims on hornblende phenocrysts in the Mamut adamellite porphyry suggest interaction between the mineralizing magma and the exsolved fluids. Occurrences of clinopyroxene microphenocrysts and pseudomor‐phic aggregates of shredded biotite and clinopyroxene after hornblende phenocrysts in the barren intrusives imply lower water fugacity and decreasing in water fugacity, respectively. Compositional gap between the core of hornblende phenocrysts and the tremolitic amphibole rims and those in the groundmass of the Mamut adamellite porphyry suggests a decrease in pressure. Higher XMg (=Mg/(Mg+Fe) atomic ratio) in the tremolitic amphibole rims in the Mamut adamellite porphyry compared to those of the barren intrusions suggests high oxygen fugacity. High halogen contents of igneous hydrous minerals such as amphiboles, biotite and apatite in the Mamut adamellite porphyry suggest the existence of highly saline fluids during the intrusion and solidification of the mineralizing magma. Fluid inclusions found in quartz veinlet stockworks are characterized by abundant hypersaline polyphase inclusions associated with subordinate amounts of immiscible gaseous vapor. Both Cu and Au are dispersed in disseminated and quartz stockwork ores. Chalcopyrite and pyrrhotite as well as magnetite are the principal ore minerals in the biotitized disseminated ores. Primary assemblage of intermediate solid solution (iss) and pyrrhotite converted to the present assemblage of chalcopyrite and pyrrhotite during cooling. Subsequent to biotitization, quartz veinlet stockworks formed associated with retrograde chlorite alteration. The Cu‐Fe sul–fides associated with stockwork quartz veinlet are chalcopyrite and pyrite. Overlapping Pb and Zn and subsequent Sb mineralizations were spatially controlled by NNE‐trending fractures accompanying the phyllic and advanced argillic alteration envelope. Sulfur isotopic composition of ore sulfides are homogeneous (about +2%) throughout the mineralization stages. These are identical to those of the magmatic sulfides of Mount Kinabalu adamellitic rocks. 相似文献
19.
1.8 Ga Svecofennian post-collisional shoshonitic magmatism in the Fennoscandian shield 总被引:8,自引:0,他引:8
At least 14 small (1–11 km across) 1.8 Ga Svecofennian post-collisional bimodal intrusions occur in southern Finland and Russian Karelia in a 600-km-long belt from the Åland Islands to the NW Lake Ladoga region. The rocks range from ultramafic, calc-alkaline, apatite-rich potassium lamprophyres to peraluminous HiBaSr granites, and form a shoshonitic series with K2O+Na2O>5%, K2O/Na2O>0.5, Al2O3>9% over a wide spectrum of SiO2 (32–78%). Although strongly enriched in all rocks, the LILE Ba and Sr and the LREE generally define a decreasing trend with increasing SiO2. Depletion is noted for HFSE Ti, Nb and Ta. Available isotopic data show overlapping values for lamprophyres and granites within separate intrusions and a cogenetic origin is thus not precluded. Initial magmas (Mg#>65) in this shoshonitic association are considered to be generated in an enriched lithospheric mantle during post-collisional uplift some 30 Ma after the regional Svecofennian metamorphic peak. However, prior to the melting episode, the lithospheric mantle was affected by carbonatite metasomatism; more extensively in the east than in the west. The melts generated in the more carbonate-rich mantle are extremely enriched in P2O54%, F12,000 ppm, LILE: Ba9000 ppm, Sr7000 ppm, LREE: La600 ppm and Ce1000 ppm. The parental magma underwent 55–60% fractionation of biotite+clinopyroxene+apatite+magnetite+sphene whereupon intermediate varieties were produced. After further fractionation, 60–80%, of K-feldspar+amphibole+plagioclase±(minor magnetite, sphene and apatite), leucosyenites and quartz-monzonites were formed. In the west, where the source was less affected by carbonatite metasomatism, calc-alkaline lamprophyres (vogesites, minettes and spessartites) and equivalent plutonic rocks (monzonites) were formed. Removal of about 50% of biotite, amphibole, plagioclase, magnetite, apatite and sphene produced peraluminous HiBaSr granites. The impact of crustal assimilation is considered to be low. At about 1.8 Ga, the post-collisional shoshonitic magmatism brought juvenile material, particularly enriched in alkalis, LILE, LREE and F, into the crust. Although areally restricted, the regional distribution of the post-collisional intrusions may indicate that larger volumes of 1.8 Ga juvenile material resides in unexposed parts of the crust. 相似文献
20.
Yao-Hui Jiang Shao-Yong Jiang Hong-Fei Ling Xun-Ruo Zhou Xing-Jian Rui Wan-Zhi Yang 《Lithos》2002,63(3-4):165-187
A series of granitoids from Proterozoic to Cenozoic age occurred in the western Kunlun orogenic belt, Xinjiang, northwestern China. Several intrusions such as the West Datong (Middle Caledonian age), North Kuda (Late Caledonian age) and Kuzigan, Karibasheng, Zankan (Himalayan age) plutons have shoshonitic affinity. Their rock assemblages include (quartz) monzodiorite–(quartz) monzonite–quartz syenite (Middle Caledonian) or monzonitic granite–granite (Late Caledonian) or biotite (monzonitic) granite–diopside granite–diopside syenite (Himalayan). Generally, biotite is iron–phlogopite, with some eastonite and high Mg/(Mg+FeT) and Fe3+/Fe2+ ratio. Amphibole is mainly edenitic hornblende and magnesian hastingsitic hornblende, with some edenite and higher Mg/(Mg+FeT) and Fe3+/Fe2+ ratio. The rocks show SiO2 contents of 52.77–71.85% and high K2O+Na2O (mostly >8%, average 9.14%), K2O/Na2O (mostly >1, average 1.50) and Fe2O3/FeO (0.85–1.51, average 1.01) and low TiO2 contents (0.15–1.12%, average 0.57%). Al2O3 contents (13.01–19.20%) are high but variable. The granitoids are prominently enriched in LILE, LREE and volatiles such as F. However, the studied shoshonitic granitoids among the three intrusive periods also show differences in isotopic compositions and trace element concentrations, suggesting their different geneses: the origin of the West Datong pluton is probably related to the involvement of subducted oceanic crust sediments into the mantle source; the North Kuda and Himalayan plutons could have been generated by partial melting of subducted oceanic crust sediments or metasediments of thickened continental lower crust in the process of late-orogenic slab break-off or lithospheric thinning. 相似文献