弧地壳深部岩浆结晶分异过程:来自中祁连西段哈马尔达坂杂岩体的年代学、地球化学和热力学模拟研究SCIEI北大核心CSCD

俯冲带弧岩浆分异是大陆地壳形成的主要过程,对研究大陆地壳的演化与生长机制具有重要意义。本文通过对中祁连弧地体西段盐池湾地区的哈马尔达坂杂岩体进行野外地质、地球化学、年代学和热力学模拟研究,来讨论弧岩浆分异过程。哈马尔达坂杂岩体主要存在两类岩石类型:镁铁质-超镁铁质堆晶岩(包括辉石角闪石岩、角闪辉长岩和角闪石岩)和闪长岩类(包括闪长岩、石英闪长岩)。锆石U-Pb定年结果显示辉石角闪石岩的形成时代为473±1Ma,与相邻高钾岛弧玄武岩的形成时代一致。哈马尔达坂杂岩体与高钾岛弧玄武岩具有相似的全岩Sr-Nd-Hf同位素组成,(^(87)Sr/^(86)Sr)_(i)比值在0.7035~0.7053之间,ε_(Nd)(t)=+3.9~+5.1,ε_(Hf)(t)=+10.8~+13.1,表明它们来自同一岩浆源区。结合野外地质关系与岩石地球化学特征,推测该侵入杂岩体的原始熔体为相邻的高钾玄武质弧岩浆。岩石学和地球化学特征表明:闪长岩类是来源于受沉积物熔体交代的俯冲带地幔楔部分熔融形成的原始玄武质岩浆在中下地壳发生(以角闪石为主)结晶分异的产物;镁铁质-超镁铁质岩石具有堆晶结构,地球化学特征呈现富铁贫硅的特征,具有较高的MgO含量(6.19%~14.29%,Mg^(#)=52.3~74.6),代表原始玄武质岩浆分离结晶形成的堆晶体。热力学模拟计算与实验岩石学资料对比,进一步说明该杂岩体中的闪长岩是玄武质岩浆在中压(约0.7GPa)和氧逸度为NNO+1的条件下、发生50%~67%分离结晶的产物。闪长岩类与镁铁质-超镁铁质堆晶岩具有相似的矿物结晶顺序与全岩同位素组成,指示它们具有发生分离结晶作用的互补成分特征,分别代表了玄武质岩浆分离结晶后的衍生熔体和堆晶岩。因此,本文研究表明角闪石分异是弧岩浆分异的主要机制,它导致富SiO_(2)熔体的形成,推动岩浆成分向富硅的方向演变,从而产生新生的安山质地壳。     

Anatomy of the transpressional Dom Feliciano Belt and its pre-collisional isotopic (Sr–Nd) signatures: A contribution towards an integrated model for the Brasiliano/Pan-African orogenic cycle

The Dom Feliciano Belt evolution is reviewed based on cross-sections, space–time diagrams, P-T paths, and Sr–Nd isotopic data of pre-collisional metaigneous rocks. The belt is divided into northern, central and southern sectors, subdivided into tectonic domains, developed at Neoproterozoic pre-, syn- and post-collisional stages. The northern sector foreland pre-collisional setting represents a rift, with tholeiitic (meta)volcanic rocks (∼800 Ma) chronocorrelated to hinterland intermediate and acidic orthogneisses of high-K calc-alkaline arc signature. In contrast, the central sector records a complete section from the forearc towards the back-arc region during pre-collisional times. In the western domain, ophiolites (∼920 Ma) are associated with arc-related orthogneisses and metavolcanic rocks (880–830 Ma; 760–730 Ma). At back-arc position, continental arc-related magmatism (800–780 Ma) is registered by hinterland orthogneisses and central foreland metavolcanic rocks. Ophiolites on the hinterland opposite side comprise two compositional groups, with N-MORB and supra subduction signature, interpreted as a back-arc basin record (∼750 Ma). The pre-Neoproterozoic basement of the whole belt is correlated with the Nico Perez Terrane and Luis Alves Block (Archean to Mesoproterozoic, with Congo Craton affinity). This contrasts with the Piedra Alta Terrane (Rio de La Plata Craton, only Paleoproterozoic), westernmost Uruguay. The suture between the Piedra Alta and Nico Perez terranes is correlated with the suture zone in the westernmost central sector. Transpression affected both foreland and hinterland during collision (660–640 Ma), with high-T/low-P hinterland progressive exhumation, whilst foreland low- to medium-grade correlated sequences record underthrusting. Post-collisional processes included magmatism throughout the belt (640–580 Ma), strain partitioning along strike-slip shear zones, and foreland basin fill. Late tectono-metamorphic and magmatic processes (560–540 Ma) were attributed to the Kalahari Craton collision. Arc magmatism migration due to subduction angle variations suggests modern-style plate tectonics during Gondwana amalgamation. Diachronism and kinematic inversion are characteristic of an oblique convergent multi-plate orogenic system.