Petrogenesis of the Late Triassic shoshonitic Shadegai pluton from the northern North China Craton: Implications for crust-mantle interaction and post-collisional extension

Latest Permian to Triassic plutons are widespread in the northern North China Craton(NCC); most of them show calc-alkaline, high-K calc-alkaline, or alkaline geochemical features. The Shadegai pluton in the Wulashan area has shoshonitic affinity and I-type character, and is composed of syenogranites containing abundant mafic microgranular enclaves(MMEs). LA-MC-ICP-MS U-Pb data yield weighted mean 206 Pb/238 U ages of 222 ± 1 Ma and 221 ± 1 Ma for the syenogranites and MMEs, respectively, suggesting their coeval formation during the Late Triassic. The syenogranites have high SiO_2(70.42-72.30 wt%),K_2O(4.58-5.22 wt.%) and Na_2O(4.19-4.43 wt.%) contents but lower concentrations of P_2O_5(0.073-0.096 wt.%) and TiO_2(0.27-0.37 wt.%), and are categorized as I-type granites, rather than A-type granites, as previously thought. These syenogranites exhibit lower(^(87)Sr/^(86)Sr)i ratios(0.70532-0.70547) and strongly negative whole-rock εNd(t) values(-12.54 to-11.86) and zircon εHf(t) values(-17.81 to-10.77),as well as old Nd(1962-2017 Ma) and Hf(2023-2092 Ma) model ages, indicating that they were derived from the lower crust.Field and petrological observations reveal that the MMEs within the pluton probably represent magmatic globules commingled with their host magmas. Geochemically, these MMEs have low SiO_2(53.46-55.91 wt.%)but high FeOt(7.27-8.79 wt.%) contents. They are enriched in light rare earth elements(LREEs) and large ion lithophile elements(LILEs), and are depleted in heavy rare earth elements(HREEs) and high field strength elements(HFSEs). They have whole-rock(^(87)Sr/^(86)Sr)i ratios varying from 0.70551 to 0.70564, εNd(t) values of -10.63 to -9.82, and zircon εHf(t) values of -9.89 to 0.19. Their geochemical and isotopic features indicate that they were derived from the subcontinental lithospheric mantle mainly metasomatized by slab-derived fluids, with minor involvement of melts generated from the ascending asthenospheric mantle. Petrology integrated with elemental and isotopic geochemistry suggest that the Shadegai pluton was produced by crust-mantle interactions, i.e., partial melting of the lower continental crust induced by underplating of mantle-derived mafic magmas(including the subcontinental lithospheric mantle and asthenospheric mantle), and subsequent mixing of the mantle-and crust-derived magmas. In combination with existing geological data, it is inferred that the Shadegai pluton formed in a post-collisional extensional regime related to lithospheric delamination following the collision between the NCC and Mongolia arc terranes.

The petrographical and isotope geochemical tracers for deep ore-forming fluids from the Laowangzhai gold depoist in the northern part of the Ailao Mountains

Based on the petrological studies of wall rocks, mineralized rocks, ores and veins from the Laowangzhai gold deposit, it is discovered that with the development of silification, carbonation and sulfidation, a kind of black opaque ultracrystalline material runs through the space between grains and amphibole cleavages, which is the product of fast condensing consolidation with magma mantle fluids turning into hydrothermal crustal fluids in the process of mineralization and alteration. It is thought that the water in ore-forming fluids mainly derived from magmatic water through research on H-O isotopes, and C as well as S isotopic compositions, has clear mantle-derived characteristics, and rock (mine) stones contain high 87Sr/86 Sr ratios, low 143Nd/144 Nd ratios and high 206Pb/204 Pb ratios, which also reflects the ore-forming fluids were derived from the metasomatically enriched mantle. In combination with the features of H-O-C-S isotopes and Sr-Nd-Pb isotopes described above, the ore-forming fluids of the Laowangzhai gold deposit in the northern part of the Ailao Mountains were derived mainly from the deep interior of the mantle, and their properties were transformed from magma fluids to hydrothermal fluids in the course of metasomatism and alteration, which initiated crust-mantle contamination simultaneously to be in favor of mineralization.

Crystallization Conditions and Mineral Chemistry in the East of Tafresh, Central Iran, with Insights into Magmatic Processes

The Tafresh granitoids are located at the central part of the Urumieh-Dokhtar Magmatic Arc(UDMA)in Iran.These rocks,mainly consisting of diorite and granodiorite,were emplaced during the Early Miocene.They are composed of varying proportions of plagioclase+K-feldspar+hornblende±quartz±biotite.Discrimination diagrams and chemical indices of amphibole phases reveal a calc-alkaline affinity and fall clearly in the crust-mantle mixed source field.The estimated pressure,derived from Al in amphibole barometry,is approximately 3 Kb.The granitoids are I-type,metaluminous and belong to the calc-alkaline series.They are all enriched in light rare earth elements and large ion lithophile elements,depleted in high field strength elements and display geochemical features typical of subduction-related calc-alkaline arc magmas.Most crystal size distribution(CSD)line patterns from the granitoids show a non-straight trend which points to the effect of physical processes during petrogenesis.The presence of numerous mafic enclaves,sieve texture and oscillatory zoning along with the CSD results show that magma mixing in the magma chamber had an important role in the petrogenesis of Tafresh granitoids.Moreover,the CSD analysis suggests that the plagioclase crystals were crystallized in a time span of less than 1000 years,which is indicative of shallow depth magma crystallization.

松辽盆地天然气中稀有气体地球化学特征及其地质意义

稀有气体地球化学已运用于地球深部物质及天体陨石研究,随着测量技术的进步,在天然气研究中也开始得到越来越多的应用。使用目前最先进的稀有气体质谱仪,对中国东部松辽盆地中深部天然气的稀有气体全组分丰度及同位素进行了系统的分析,明确了断陷盆地稀有气体的组成特征。研究表明,天然气中稀有气体的丰度从轻稀有气体到重稀有气体具有逐渐减小的反“厂”字形趋势。稀有气体的同位素比值^(3)He/^(4)He为2.64×10^(-6)、^(20)Ne/^(22)Ne为9.94、21Ne/^(22)Ne为0.02922、^(40)Ar/^(36)Ar为743.7,均高于大气值,^(80)Kr、^(84)Kr、^(86)Kr、^(131-136)Xe均表现出相对大气过剩的特征,显示天然气中有幔源气体的混入。综合稀有气体的组成特征,说明松辽盆地中深部天然气均为壳幔混源的无机成因,而且不同构造区块、不同类别天然气的幔源组分贡献存在一定差异。对比稀有气体组成与天然气类型发现,轻稀有气体可以较好地区分天然气的类型,而重稀有气体的组成在各种天然气中没有明显差别。稀有气体同位素除了可以示踪天然气来源外,还可以应用在判别天然气成因、区分天然气类型、表征大地构造等方面。

油气地质勘探将从烃源岩时代进入幔源油气新时代

简要梳理了人类石油勘探发展历程,分析并研究了国内外25个油田(或盆地、油区)的勘探资料,得出结论:石油地质勘探经历过的第一个阶段是背斜(构造)勘探阶段(19世纪60年代~20世纪60年代),第二个阶段是烃源岩勘探阶段(20世纪30年代至今),现在已经进入一个全新的阶段——幔源油气勘探时代。依据幔源油气理论,提出了创新的“盆-壳-幔镜像叠置成藏模式”。

琼西南晚白垩世千家岩体矿物学特征及其对岩石成因的约束

千家岩体为海南岛典型的晚白垩世早期花岗质杂岩体,岩石类型主要有花岗闪长岩、二长花岗岩及正长花岗岩,常见造岩矿物有黑云母、角闪石、斜长石、碱性长石、石英等。为进一步揭示岩石形成过程及源区性质,反演壳幔相互作用,本文选取千家岩体,利用电子探针技术对不同岩石类型中的主要矿物进行了矿物化学分析。结果显示,角闪石、黑云母均属于壳幔混源成因,斜长石发育正反环带及振荡环带,记录了岩浆混合作用的影响。镜下观察发现,千家岩体各类岩石中存在大量的岩浆不平衡结构,如斜长石和角闪石的环带结构,针状产出的磷灰石,以及斜长石、钾长石和石英的嵌晶结构等,结合暗色微粒包体的分布组合及形态特征,认为千家岩体形成中经历了岩浆混合作用。综合来说,岩石及矿物化学证据均表明,岩浆混合作用是研究区岩石形成的主因,矿物学证据表明,千家岩体岩石类型为I型花岗岩,其源区属钙碱性岩浆,黑云母矿物化学数据表明岩石形成环境为相对较低的氧逸度。

镜泊湖地区杏山火山群的火山岩特征及其岩浆演化

镜泊湖火山区是我国陆内新生代玄武岩研究的一个重要窗口。东南部的杏山火山群研究不足且前人的研究否定了其岩浆经历过同化混染作用。笔者等对杏山火山群的玄武岩开展了系统的岩石学、岩石地球化学和Sr—Nd—Pb同位素的研究,认为杏山火山群主要为碧玄岩和粗面玄武岩,原生岩浆在上升过程中发生了橄榄石和单斜辉石的分离结晶,并在上地壳区域发生了同化混染作用,但同化混染—分离结晶作用较为微弱。将杏山火山群与同期的镜泊湖玄武岩对比发现,两个地区的玄武岩都来源于石榴子石橄榄岩的部分熔融,杏山火山群的部分熔融程度略低于同期的镜泊湖玄武岩。在岩浆源区方面,杏山火山群的岩浆源区为普通地幔与全硅酸盐地球端元的混合源。岩浆源区的不均一性和岩浆演化过程中所经历的同化混染作用是造成杏山火山群和镜泊湖火山群的岩性差异的主要影响因素。

A Metallogenic Model of Gold Deposits of the Jiaodong Granite-Greenstone Belt

An analysis of trace elements and isotopic geochemistry suggest that the ore-forming materials of gold deposits in the Jiaodong granite-greenstone belt have multiple sources, especially the mantle source. Seismic wave, magnetic and gravity fields show that the crust-mantle structure and its coupling mechanism are the fundamental dynamic causes for the exchange and accumulation of materials and energy in the metallogenic system. Considering the evolution history of the structural setting, the tectono-metallogenic dynamics model of the area can be summarized as follows: (1) occurrence of the greenstone belt during the Archean-Proterozoic-the embryonic form of Au-source system; (2) stable tectonic setting in the Paleozoic-an intermittence in gold mineralization; (3) intensive activation and reformation of the greenstone belt in the Mesozoic-tectono-mineralization and tectono-diagensis; (4) posthumous structural activity in the Cenozoic-destruction of orebodies in the later stage. In the middle and late Indosinian, the Tancheng-Lujiang fault zone cut deeply into the upper mantle so that the ore-bearing fluids migrated to higher layers through the crust-mantle interaction, resulting in alteration and mineralization.

Early Paleozoic adakite in the Liuyuan area from the Beishan orogenic belt,NW Gansu Province:Petrogenesis and implication for tectonic setting

The Liuyuan area,which is located on the southern margin of the Beishan orogenic belt,develops abundant Early Paleozic granitoids.SHRIMP zircon U-Pb dating yielded a weighted mean 206Pb/238U age of 421±8 Ma for the Liuyuan granodiorite(Zhao Zehui et al.,2007),implying its Late Silurian intrusion.Geochemical compositions showed that the Liuyuan granodiorite is characterized by high SiO2(65.01%-67.31%),A12O3(17.17%-18.05%) and Na2O(Na2O/K2O=1.67-1.87) but low Mg# contents calculated as 100×Mg2+/(Mg2++∑Fe2+) from 28.77 to 31.15,as well as being enriched in Sr(472×10-6-517×10-6) but depleted in Yb(1.2×10-6-1.42×10-6) and Y(12.8×10-6-14×10-6).The REEs are characterized by right-inclined patterns with LREE enrichment,HREE depletion and slightly negative Eu anomalies(Eu/Eu*=0.91-0.97).Major and trace elements indicate that the granodiorite is an adakite.The Nb/Ta values of the granodiorite vary from 10.80 to 18.01 and Nb/U from 6.32 to 10.09,both lying between the values of the crust and the mantle.The rock has low εNd(t) values(-2.5--0.8) and high ISr(0.706321-0.706495).Geochemical and Sr-Nd isotopic compositions indicate that the Liuyuan granodiorite is possibly derived from partial melting of thickening lower crust,related to mantle underplating.The Yb-Ta and Y+Nb-Rb discriminant diagrams imply the Liuyuan granodiorite intruded in a local extensional tectonic setting during late collision.Combined with previous studies on geochronology,geochemistry and tectonic setting of granitoids,we interprete that the constraint of this adakite in the Liuyuan area indicates that the tectonic setting may have transformed from collision to extension during the Early Devonian.

暗色微粒包体是壳幔岩浆混合作用的证据吗?

暗色微粒包体常见于钙碱性花岗岩中,已普遍被认为是幔源基性岩浆与壳源酸性岩浆在地壳深部发生混合作用的产物。本文通过大量资料的分析研究,发现暗色微粒包体可以具有很大负值的全岩εNd(t)值和锆石εHf(t)值,及大于0.710的全岩[n(87Sr)/n(86Sr)]i值,不存在幔源岩浆混合的痕迹;而且,大多数暗色微粒包体与寄主花岗岩在晶体化学、形成年龄、全岩和锆石同位素成分等方面显示出完全相似的特征,反映出两者在时空与物质上都具有紧密的成因联系。笔者认为,暗色微粒包体不应该是壳幔岩浆混合作用的产物。基于包体岩浆极小的体量和稍晚的侵位(相对于寄主花岗岩),笔者提出一种新的暗色微粒包体的形成方式:同造山花岗岩浆的主动上侵造成岩浆房内的“负压力”而导致岩浆房下部呈晶粥状态的闪长质层发生等温减压熔融作用,从而形成体量极小的包体岩浆;并即时“注入”地壳上部尚未固结的寄主花岗岩中,快速冷凝形成暗色微粒包体。因此,暗色微粒包体不能被视作为“壳幔岩浆混合作用”的证据。

氦气资源的分类、特征及富集主控因素分析

我国氦气供应量不足,根本原因是氦气资源相对贫乏。加强对富氦天然气的分类研究,明确不同类型氦气藏的特征及富集主控因素,对促进我国氦气勘探开发研究和保障我国用氦安全都具有重要意义。通过研究氦气的成因,同时考虑氦气资源丰度禀赋,铀、钍放射性元素所处空间层位,载体气藏类型,以及成藏主控因素的差别,对含氦气藏进行了细致划分。氦气藏总体分为两类:壳幔混合型和壳源型,壳源型又可细分为壳源远源型(包括烃类伴生型和水溶气型)和壳源近源型(页岩气型),不同类型氦气资源特征大相径庭。从国内目前发现的氦气藏来看,只有与烃类气藏共同成藏的壳源氦才具有工业利用价值,尽管其资源品位相对较低,但资源潜力较大。壳源远源型和壳源近源型氦气藏富集主控因素大致相同,但在氦源岩和运移通道上存在差异。

青海省牛苦头铅锌矿床成矿时代研究:来自成矿岩体年代学和黄铁矿Re-Os地球化学证据

东昆仑造山带祁漫塔格地区是青海重要的矽卡岩多金属成矿带,牛苦头矽卡岩型矿床位于该地区中西段,为祁漫塔格地区探明的中-大型矽卡岩型铅锌多金属矿床之一。鉴于矿区成岩成矿时代以及金属成矿物质来源存在争议,笔者通过LA-ICP-MS及热表面电离质谱Re-Os同位素测试技术对锆石及黄铁矿年代学进行了研究。结果表明,牛苦头矿区M1矿段10线钻孔底部成矿花岗岩体年龄分别为(362.2±2.7)Ma、(361.8±3.4)Ma,与主成矿阶段闪锌矿密切共生的黄铁矿Re-Os等时线年龄为(359.2±6.3)Ma。牛苦头矿区矽卡岩铅锌多金属矿床成岩与成矿时代耦合于(362.2±2.7)~(359.2±6.3)Ma,表明该矽卡型铅锌多金属矿床形成于华力西期晚泥盆世。黄铁矿初始187OS/188Os值为0.13±0.24,表明牛苦头铅锌矿床金属成矿物质为壳幔混合来源,形成于晚泥盆世早古生代—晚古生代早期构造-岩浆旋回中碰撞-后碰撞的拉伸背景之下。

共和盆地干热岩形成的地球动力学过程与成因机制

共和盆地干热岩是我国首次钻获的干热岩,围绕其成因机制还存在诸多争议。基于前人资料和我们的热物性测试、地球化学及地球物理探测成果,通过综合研究,阐述了共和盆地干热岩成因机制与地球动力学过程:(1)印度与欧亚板块晚碰撞及后碰撞等一系列构造活动,导致了青藏高原北部的隆升和软流圈上涌、热侵等深部动力过程,在高原隆升蓄积的重力势能及其导致的重力浮力、青藏高原东北缘的侧向挤压应力、地幔拖曳力、软流圈热物质上侵热力等综合作用下,壳幔通道流沿岩石圈薄弱层(带)整体自西南向青藏高原东北部和共和盆地东北部流动。(2)板块(地块)缝合带、塑性流变韧性剪切带或高导低速体、深大走滑断裂带及其交汇部位等岩石圈薄弱层(带),是深部热物质自深至浅运移的壳幔通道。(3)深部地质结构的不均一使来自深部的热量在地壳浅部形成不均一性的聚集;岩石圈浅部的地下水活动、沉积/剥蚀作用与深部的岩石圈变形以及岩浆热对流等物质运动方式对热流的扰动;深部热流向热导率高的花岗岩类侧向运移等这些岩石圈热量自深至浅的不均一分配。本文突破了以往单因素和少数控热因素的共和盆地干热岩成因认识,阐明了由源(热源、力源)、通道到储、盖(层)的干热岩综合成因机制。

福建泰宁地区早古生代二长花岗岩年代学、地球化学特征及地质意义

华南早古生代武夷‒云开造山带以强烈的变质变形、区域角度不整合和发育大量花岗岩为特征。在武夷地区I型花岗岩主要分布于深大断裂等构造带附近。本文以产于武夷造山带中段石城‒崇安断裂附近的长兴二长花岗岩为研究对象,对其开展年代学、地球化学和Sr-Nd-Hf同位素分析,据此探讨岩石成因及其形成的构造背景。LA-ICP-MS锆石U-Pb年龄为451±3 Ma,表明二长花岗岩形成于晚奥陶世。岩石具有较高的SiO_(2)(71.97%~74.94%)、Al_(2)O_(3)(13.16%~14.86%)和K2O(4.03%~6.95%)含量,较低的MgO(0.27%~0.78%)、TiO_(2)(0.09%~0.26%)、CaO(0.15%~1.44%)和P2O5(0.03%~0.11%)含量,属于高钾钙碱性系列。长兴二长花岗岩具有明显的负Eu异常(δEu=0.44~0.99),富集大离子亲石元素(K、Rb)、Th、U、Pb和轻稀土元素,亏损Ba、Sr、P、Zr、Ti和重稀土元素,显示高分异I型花岗岩的特征。二长花岗岩的锆石Hf同位素具有明显的不均一性,176Hf/177Hf值介于0.282291~0.282647之间,εHf(t)值范围为–7.48~4.46,tDM2(Hf)变化于1058~1718 Ma。全岩(87Sr/86Sr)i为0.7101~0.7156,εNd(t)为–14.7~–11.7,tDM2(Nd)为1971~2171 Ma。综合分析认为武夷‒云开造山带为早古生代陆内造山带,二长花岗岩形成于后造山伸展垮塌阶段初期,为幔源基性岩浆及其上涌诱发的酸性岩浆在地壳深部混合,并经历了高程度的分离结晶作用的产物。

江南造山带东段阳储岭钨多金属矿床燕山期岩浆岩成因

与阳储岭钨多金属矿床密切相关的燕山期岩体主要由4个岩石单元组成,分别是似斑状二长花岗岩、似斑状细粒黑云母花岗闪长岩、花岗闪长斑岩、花岗闪长岩。在系统的野外地质调查基础上,开展了岩相学和地球化学分析,探讨了杂岩体的成因及主要岩石单元的活动时序。研究表明,阳储岭花岗岩体具有高硅、过铝质特征,岩石富集K、Rb,亏损Sr和Ba元素,高场强元素Zr、Hf富集不明显,Nb、Ti元素强烈亏损,U、Th相对富集。REE显示弱Eu亏损的较小斜率的右倾模式,微量元素原始地幔标准化蛛网图总体上呈左高右低的趋势,说明阳储岭岩体主要岩石均应属于高分异的I型花岗岩。从岩石的Rb/Sr、Rb/Nb、Zr/Hf及Ti/Zr值与地壳平均值和地幔平均值对比研究,表明岩浆来源于壳源物质与幔源物质的混合。基于以上稀土元素指标及主微量元素的哈克图解分析,阳储岭岩体轻、重稀土元素的分异程度高,暗示其可能由早期的似斑状二长花岗岩→似斑状细粒黑云母花岗闪长岩→花岗闪长斑岩→花岗闪长岩演化趋势,这与野外观察到的岩浆侵入时序较为一致。

陆壳垂向增生的两种方式:以大兴安岭为例

本文讨论了大兴安岭由于中生代底侵作用形成的两种类型的陆壳增生方式： １） 来自地壳底部壳幔混源岩浆房的花岗岩和火山岩对上部陆壳的增生， 岩浆的侵位和喷发集中在１４５～１１５ Ｍａ， 它们具明显的幔源岩石同位素特征， 如正的εＮｄ （ｔ）值（０～４），低的８７Ｓｒ／８６ Ｓｒ 初始比值（０．７０４～０．７０８）等； ２）早中生代形成的镁铁－超镁铁质堆晶岩（２４１～２１４ Ｍａ）对下部陆壳的增生。

山东郗山-龙宝山地区与碱性岩有关的稀土矿床地质特征及成因

郗山和龙宝山稀土矿具有相似的成矿地质背景、控矿岩体特征及矿床地质特征。燕山早期碱性侵入岩与稀土矿关系密切,稀土矿体主要赋存于杂岩体内及其附近围岩中;稀土元素和同位素研究表明,含矿质的富碱岩浆可能属壳幔混源型,碱性岩浆及成矿物质最初可能都来源于上地幔同一部位,而在岩浆上侵过程中同化混染了地壳物质。郗山稀土矿为单一富轻稀土矿床,矿脉类型以含稀土石英重晶石碳酸盐脉为主,含稀土矿物以氟碳铈矿和氟碳钙铈矿为主,碳酸铈钠矿和菱钙锶铈矿属国内首次发现。龙宝山稀土矿为稀土、金共生矿,矿脉类型主要为石英脉和硅化角砾岩;含稀土矿物主要有氟碳铈矿、氟碳铈镧矿、氟碳钙铈矿;金矿物有自然金、银金矿等。成矿时代稍晚于岩浆岩形成时代,属中生代燕山晚期;矿床成因类型为碱性岩浆期后中-低温热液稀土矿床。

青藏高原新生代火车头山碱性及钙碱性两套火山岩的地球化学特征及其物源讨论

藏北羌塘火车头山新生代火山岩可区分为钙碱性及碱性两个不同的系列.钙碱性火山岩主要岩石组合为玄武岩-安山岩-英安岩,其SiO2介于49%～70%之间,Al2O3＞10%,Na2O/K2O＞1;其中玄武岩具平坦型稀土配分型式,LREE/HREE为1.3～1.8,（La/Yb）N为2.87～4.45,无明显铕异常,δEu为0.96～1.09;该套岩石的Mg#与SiO2相关关系以及La/Sm-La等亲岩浆元素与超亲岩浆元素协变关系表明,它们应为幔源岩浆经分离结晶演化的产物,其岩石组合类型以及低的Sm/Yb值（Sm/Yb=1.53～5.35）表明它们的原始岩浆应来源于岩石圈地幔尖晶石二辉橄榄岩的局部熔融.本区碱性火山岩为一套典型的钾质岩石系列,主要岩石组合类型为碱玄岩-碱玄质响岩-响岩,其SiO2介于44%～59%之间,Al2O3＞14%,Na2O/K2O介于0.47～1.51之间;岩石轻稀土强烈富集,LREE/HREE为13.20～15.76,（La/Yb）N=50.44～91.99;其岩石组合类型以及Mg^#与SiO2相关关系以及La/Sm-La协变关系同样表明它们为共源岩浆分离结晶演化的产物;然而,其较高的Sm/Yb值（Sm/Yb=2.63～13.98）表明它们并非地幔橄榄岩直接局部熔融的产物,岩石弱的负Eu异常（δEu=0.77～0.85）以及Th、U的强烈富集和Nb、Ta的相对亏损,又反映了原始岩浆中有显著的地壳物质的贡献;该套钾质碱性系列岩石在La/Co-Th/Co同分母协变图上呈直线型分布,而在La/Co-Sc/Th异分母协变图上呈显著的双曲线分布,从而表明其源区为二源混合型,是青藏高原特殊的壳幔混合层局部熔融的产物,这些特征是新生代青藏高原壳幔层圈物质交换的重要岩石学证据.

南秦岭勉略带北光头山花岗岩体群的成因及其构造意义

南秦岭勉略带北部花岗岩体从闪长岩到花岗闪长岩和花岗岩变化,反映了钙碱性岩岩石组合特征,矿物组成以长石、石英、黑云母和少量角闪石为主,副矿物有锆石、磷灰石、磁铁矿和榍石,岩石化学上它们相对高K、Sr,Zr／Y比值较高,富集LEE和LILE,贫化HFSE,与后碰撞富钾钙碱性I型花岗岩特征一致。此外,它们明显亏损Nb、Ta,低Y、Yb和有较高的 LaN／YbN和Sr／Y比值,多数岩体发育淬冷岩浆结构的暗色闪长质微粒包体,包体与寄主花岗岩的稀土及微量元素存在明显差异,证明它们是地壳增厚背景下,可能由下部地壳拆沉作用导致的分别来自幔源和下部地壳熔融的二元岩浆混合演化的产物。个别高分异岩体的Fetot／Mg比值高、明显亏损Sr、Ba、Ti、P,呈现了向强分异A型花岗岩过渡的后碰撞富钾过铝偏碱性花岗岩特征。因此,结合西部岩体形成年代早于东部岩体分析,西部形成时代较早偏中基性的含有大量闪长质微粒包体的岩体代表了早期下部地壳拆沉作用的发生,东部形成较晚分异程度高的高钾钙碱性Ⅰ型花岗岩体的出现指示了南、北两大陆块碰撞汇聚后向伸展的转折,而更晚期高度分异的姜家坪富钾花岗岩体的出现则表明秦岭造山带已进入主碰撞结束期的伸展拉张演化阶段,并预示了新的板内演化期的到来。

华南中生代同熔系列花岗岩类的Nd-Sr同位素特征及成因讨论

本文讨论了华南20个同熔系列花岗岩类的Nd-Sr同位素组成。根据样品的同位素组成及其在￠Nd-T,(87Sr/86Sr)i-T和￠Nd-￠Sr图上的分布特征,认为这些同熔系列花岗岩类是华南上地壳端员和亏损地幔端员按一定比例混合的产物。利用简单二元混合方程计算了这些花岗岩体的壳幔混合比例。根据产出的大地构造环境和物质来源,华南同熔系列花岗岩类可划分为三种类型:大陆边缘型,大陆内部型和断裂拗陷带型。