伟晶质岩浆的同化混染与分离结晶(AFC)作用及铀成矿效应:以纳米比亚湖山铀矿为例

纳米比亚湖山铀矿位于达马拉造山带的中央南部地区,工业铀矿物为晶质铀矿,属于伟晶岩型铀矿床。关于不同矿石中铀元素的富集与沉淀机制还存在一定争议。为了揭示伟晶质岩浆演化与铀矿化作用的关系,本文对矿区内不同矿物组成的伟晶岩型矿石开展了岩石和矿物地球化学研究。野外及镜下鉴定结果显示,矿化伟晶岩可以分为“简单类型”矿体和“复杂类型”矿体。前者具有正常的花岗伟晶结构,晶质铀矿均匀分布于造岩矿物之间,矿化程度低到中等;后者表现出非均匀的结构特征,且矿化程度极高,晶质铀矿在成因上与大量黑云母团块有明显的空间联系。地球化学研究表明:在“简单类型”伟晶岩中,铀元素主要通过伟晶质岩浆的分离结晶作用富集;“复杂类型”伟晶质岩浆的演化则明显受控于同化混染作用,其铀矿化为岩浆同化混染与分离结晶(assimilation-fractional crystallization,AFC)作用产物。具体而言,外来基性组分(FeO,MgO,TiO_(2),MnO)的混入导致“复杂类型”熔体中矿物的结晶顺序发生改变,长石类矿物的“延后”结晶为黑云母提供了更加有利的结晶空间和条件,促使黑云母以团块状聚集的形式产出。黑云母的大量析出会引发残余岩浆中UF_(m)^(4-m)络合物的水解,导致晶质铀矿在团块黑云母内部或周围沉淀。因此,本文有关“简单类型”和“复杂类型”产铀伟晶岩的研究,有效地揭示了岩浆演化过程与铀矿化机制,丰富了伟晶岩型铀矿床理论,为后期勘查开发提供了科学依据。

鄂东南地区晚中生代侵入岩的地球化学和成因及对岩石圈减薄时限的制约

鄂东南地区侵入岩是长江中下游地区晚中生代岩浆岩带的重要组成部分,但其成因和构造背景的研究显得薄弱。本文在前期工作的基础上,开展鄂东南地区侵入岩的主量、微量和稀土元素地球化学特征的研究,探讨地球化学特征所蕴含的成因和岩石圈减薄的时限。鄂东南地区侵入岩具有高碱富钾特征,微量元素以富集大离子亲石元素和轻稀土元素,而亏损高场强元素(Nb、Ta 和 Ti)为特征。研究认为鄂东南地区中生代侵入岩不能完全归为埃达克岩,早期中(酸)性岩具有埃达克岩的地球化学特征,晚期酸性岩明显不同于埃达克岩。鄂东南地区侵入岩的地球特征表明它们是富集地幔部分熔融形成的岩浆同化混染了下地壳物质并发生分离结晶作用的产物。结合年代学和地球化学特征,初步认为早白垩世(132～128Ma) 可能是长江中下游地区岩石圈减薄高峰时间。

纳米比亚湖山铀矿床中黑云母伟晶岩型矿石特征及铀矿化机制

湖山铀矿床位于纳米比亚达马拉造山带的南部中央带,属于伟晶岩型铀矿,是世界上最大的铀矿床之一。目前关于不同矿石中铀元素的富集与沉淀机制还存在一定争议。为了厘清岩浆演化过程与铀成矿作用的关系,本文对湖山铀矿床内E型伟晶岩型矿石开展了岩石学、矿物学和地球化学研究。野外调查及镜下鉴定结果表明,产铀的E型伟晶岩可以分为"简单类型"矿体和"复杂类型"矿体:前者具有花岗伟晶结构,工业铀矿物为晶质铀矿(含少量铀钍石),呈浸染状分布于石英、长石和黑云母之间,矿化程度低到中等;而后者表现出非均匀的结构特征,晶质铀矿在成因上与大量黑云母团块有空间联系,矿化程度极高。地球化学研究表明,在"简单类型"伟晶岩中,铀元素的富集受控于分离结晶作用,而在"复杂类型"伟晶岩中,铀矿化与同化混染作用密切相关。矿石的矿物-熔体相平衡模拟结果显示,外来基性组分(FeO、MgO、TiO_(2))的混入导致"复杂类型"伟晶岩熔体中矿物的结晶顺序发生了改变,相比于"简单类型"伟晶岩熔体,黑云母初始结晶温度的升高和钾长石初始结晶温度的降低为黑云母提供了更充足的结晶时间和生长空间,促使黑云母以团块状聚集的形式产出。该过程会大量消耗岩浆中的F离子,引发UFm4-m络合物的水解,促使晶质铀矿在团块黑云母的附近沉淀,形成高品位的铀矿化。因此,本文有关"简单类型"和"复杂类型"伟晶岩矿石的研究,有效地揭示了矿化过程,丰富了伟晶岩型铀矿床理论,为推动铀矿勘查与开发提供了科学依据。

Constraints of Mantle and Crustal Sources Interaction during Orogenesis of Pre-and Post-collision Granitoids from the Northern Arabian-Nubian Shield:A Case Study from Wadi El-Akhder Granitoids,Southern Sinai,Egypt

The Egyptian older and younger granitic rocks emplaced during pre-and post-collision stages of Neoproterozoic Pan-African orogeny,respectively,are widely distributed in the southern Sinai Peninsula,constituting 70% of the basement outcrops.The Wadi El-Akhder,southwestern Sinai,is a mountainous terrain exposing two granitoid suites,namely the Wadi El-Akhder Older Granites(AOG)and the Homra Younger Granites(HYG).The AOG(granodiorites with subordinate tonalite compositions)have geochemical characteristics of medium-K calc-alkaline,metaluminous to mildly peraluminous granitoids formed in an island-arc environment,which are conformable with well-known Egyptian older granitoids rocks,whereas the HYG display calc-alkaline to slightly alkaline nature,peraluminous syeno-,monzogranites and alkali feldspar granites matching well those of the Egyptian younger granites.With respect to the AOG granitoids,the HYG granites contain lower Al_(2)O_(3),FeO^(*),MgO,MnO,CaO,TiO_(2),Sr,Ba,and V,but higher Na_(2)O,K_(2)O,Nb,Zr,Th,and Rb.The AOG are generally characterized by enrichment in LILE and LREE and depletion in HFSE relative to N-MORB values(e.g.,negative Nb and Ta anomalies).The geochemical features of the AOG follow assimilation-fractional crystallization(AFC)trends indicative of extensive crustal contamination of magma derived from a mantle source.The chemical characteristics of the AOG are remarkably similar to those of subduction-related granitoids from the ArabianNubian Shield(ANS).The compositional variations from monzogranites through syenogranites to alkali feldspar granite within HYG could not be explained by fractional crystallization solely.Correlating the whole-rock composition of the HYG to melts generated by experimental dehydration melting of meta-sedimentary and magmatic rocks reveals that they appear to be derived by extended melting of psammitic and pelitic metasediments,which is similar to the most of younger granitic suites in the ANS.