东秦岭松树沟蛇绿岩构造变形及其演化

东秦岭松树沟蛇绿岩是沿西沟早期韧性剪切带和界岭韧性剪切带构造侵位于早元古代秦岭群变质杂岩南缘之上的蛇绿岩推覆体，主要遭受了４期构造变形，反映蛇绿岩演化过程中四期主要的构造运动，分别为：１０亿年左右上地幔部分熔融残余体──蛇绿橄榄岩块底辟侵位于上覆玄武岩、晋宁期蛇绿岩构造侵位、加里东─早华力西期由南向北的过冲及晚华力西─印支期的左行走滑运动。     

东秦岭松树沟超镁铁岩侵位机制及其构造演化

东秦岭松树沟蛇绿岩主要由镁铁质-超镁铁质岩石组成。镁铁质岩类的Sm-Nd全岩等时年龄为1030±46(2δ)Ma,ε_Nd(t)=+5.7±0.2,代表了蛇绿岩的形成时代。超镁铁质岩石由不同成因的橄榄质糜棱岩和中粗粒橄榄岩组成,橄榄质糜棱岩是地幔橄榄岩经历复杂变形并多次部分熔融的残余体,具LREE亏损特征,其中发育橄榄石高温位错构造和高温组构以及低温位错构造和低温组构。中粗粒橄榄岩具LREE略富集的分布特征,是地幔橄榄岩残余体再次部分熔融熔体分离结晶的产物。野外地质、地球化学、构造变形特征均表明超镁铁岩块是因洋壳俯冲而底辟侵位于上覆玄武岩中的地幔橄榄岩残余体。综合分析认为,松树沟蛇绿岩经历了古陆块裂解或洋脊扩张(1271-1440Ma)-洋壳形成(1030-1271Ma)-洋壳俯冲消减-橄榄岩块底辟侵位(983Ma)-蛇绿岩构造侵位及其后构造变形叠加改造的复杂演化过程。     

东秦岭松树沟超镁铁岩侵位机制及其构造演化

 东秦岭松树沟蛇绿岩主要由镁铁质-超镁铁质岩石组成。镁铁质岩类的Sm-Nd全岩等时年龄为1030±46(2δ)Ma,ε_Nd(t)=+5.7±0.2,代表了蛇绿岩的形成时代。超镁铁质岩石由不同成因的橄榄质糜棱岩和中粗粒橄榄岩组成,橄榄质糜棱岩是地幔橄榄岩经历复杂变形并多次部分熔融的残余体,具LREE亏损特征,其中发育橄榄石高温位错构造和高温组构以及低温位错构造和低温组构。中粗粒橄榄岩具LREE略富集的分布特征,是地幔橄榄岩残余体再次部分熔融熔体分离结晶的产物。野外地质、地球化学、构造变形特征均表明超镁铁岩块是因洋壳俯冲而底辟侵位于上覆玄武岩中的地幔橄榄岩残余体。综合分析认为,松树沟蛇绿岩经历了古陆块裂解或洋脊扩张(1271-1440Ma)-洋壳形成(1030-1271Ma)-洋壳俯冲消减-橄榄岩块底辟侵位(983Ma)-蛇绿岩构造侵位及其后构造变形叠加改造的复杂演化过程。     

关于大陆地壳消亡与再生循环过程的新认识——大别山新的区域地质资料和榴辉岩专题研究成果提出的启示

越来越多的区域地质资料显示，大别山UHP榴辉岩相变质的大陆岩石以及在片麻岩中发现的含有柯石英包裹体的锆石和含有绿辉石包裹体的石榴子石等重矿物可能却是一个已经熔融了的榴辉岩相大陆岩片遗留下来的残留体，它们被包裹在由变形、变质深成侵入体构成的正片麻岩之中。这些深成侵入体底辟在扬子陆块北缘新元古代低一中级变质的火山一沉积地层之下。依据上述区域地质事实，本文认为，大别山含有榴辉岩残留体的高级片麻岩不是一个“UHP变质地体”或“含有榴辉岩外来构造块体的混杂岩”，其原岩应该是一套由榴辉岩化大陆岩片熔融形成的深成岩浆底辟体。由此本文提出一个新的理论假说和构造模型，即深俯冲到地幔软流圈之中的大陆边缘在不同的深度发生了相应的HP-UHP榴辉岩相变质作用，随着与俯冲洋壳的断离，其在浮力的作用下快速底垫在仰；中大陆边缘之下并发生部分熔融，熔融体底辟并置换了造山带原有的根，后经过同结晶过程的变形和变质作用形成一套含有榴辉岩相残留体的，高级片麻岩本文称之为再生地壳。     

香花岭岩浆底辟伸展构造及其控矿的研究

香花岭穹隆是一个岩浆底辟伸展构造，它的结构与变质核杂岩、剥离断层的结构相似，由核部、滑动系统及盖层构造三部分组成，核部为隐伏花岗岩体和寒武系变质岩系。滑动系统为隐伏岩体与其上覆盖层之间的高温韧性剪切带和沿泥盆系与寒武系之间的不整合面发育的剥离断层。盖层构造为发育于泥盆系一石炭系中的阶梯状缓倾斜正断层和大量层间滑脱断层，香花岭岩浆底辟伸展构造是在区域伸展作用的背景下，由岩浆底辟上隆，并引起上覆盖层下滑而形成的。香花岭锡、铬、锌多金属矿的矿田、矿床及矿体构造都受该伸展构造控制。     

北京西山房山岩体岩浆底辟构造及其地质意义

运用底辟构造的理论和模型, 通过对北京西山房山岩体边缘围岩构造、变形和应变的研究, 厘定出岩体边缘的高温剪切带、周缘向斜、呈穹状分布陡倾的线理和面理, 并结合对西山区域构造事件分析后提出房山岩体为典型的岩浆底辟构造(HotStokesDiapir).这项研究成果不仅在世界上首次证实了岩浆底辟的存在, 而且对理清北京西山地区的地质构造格架和演化序列具有十分重要的意义.研究认为房山地区可能不存在变质核杂岩; 房山岩体边缘的关坻太古宙杂岩是基底岩石随岩体底辟流动上升带到地壳上部的; 原先确定的一些印支期“剥离断层”是房山岩体岩浆底辟的刺穿构造或围岩高温剪切作用造成的地层缺失; 太平山和凤凰山等向斜是岩体底辟过程中在围岩拖曳下形成的周缘向斜.      

周口店岩体热动力构造及定位机制研究

周口店岩体是一个具有两次侵入活动的复式岩株。根据与侵入体协调一致的围岩构造、岩体的流动构造、捕虏体应变测量、岩体西北缘强变形带特征及小型韧性剪切带研究,表明周口店岩体是一个典型的斜向底辟侵入、类热气球膨胀模式的岩体。岩体西北缘强变形区的“片麻状构造”是岩桨脉动形成的挤压片理(S),不是原生流动构造;岩体西北部小型韧性剪切带的剪切片理(C)晚于挤压片理(S)。它们都是岩桨脉动底辟侵入的产物。这一结论由韧性剪切带中石英组构分析得到验证。     

DFl—1底辟区构造应力场及渗流场演化的数值模拟研究

DFl—1底辟区是莺歌海盆地内超压流体最活跃的地带之一．超压流体的活动直接受控于构造应力及其形成的不同类型的断裂和裂隙构成的输导系统．从底辟区大规模流体垂向活动以及幕式活动的特征来看，流体流动的动力主要是由于垂向压差的存在以及渗流场变化引起的局部应力场(包括热应力场)的作用所致．在详细研究底辟区的构造及流体活动关系的基础上，对底辟区构造应力场及渗流场的演化进行了模拟．结果显示：构造运动引起的应力场决定了DFl—1底辟区油气沿主要断裂系走向迁移的总趋势，在底辟区流体从底辟的两侧向其中心运移，由底辟体中向上运移为主；高压流体产生的热应力控制局部应力场状况及油气运移方向，驱动流体向底辟体顶部运移，当热应力值过大时有可能改变应力场状况以及油气运移总趋势．     

安徽大别山团岭花岗岩体岩石学特征及成因

团岭花岗岩体侵位于大别山南部超高压变质带变质表壳岩中, 由细粒少斑二长花岗岩和中粒少斑二长花岗岩组成。通过岩石学、岩石化学、地球化学的研究, 确定其为Ｓ 型花岗岩, 源岩可能来自大别山变质杂岩。结合同位素资料, 认为其属燕山期花岗岩, 侵位机制为底辟式强力就位。     

洋脊下地幔熔融和底辟作用的证据—Oman蛇绿岩

对Oman蛇绿岩的三个岩体进行的详细构造填图表明具底辟特点。镁质岩脉的大量分布以及地幔橄榄岩和上覆层状辉长岩之熔体反应带的过渡演变特点证明,在洋脊熔体萃取过程中底辟所起的主要作用。通过与底辟形状有关的镁质岩脉走向的研究,就能更准确     

High-K calc-alkaline plutonism in Zouzan, NE of Lut block, Eastern Iran: An evidence for arc related magmatism in Cenozoic

The Zouzan pluton is one of the intrusive bodies in the NE of Lut block enclosed by Cenozoic volcanic and sedimentary rocks. It consists of two distinct mafic and felsic magmas which are genetically unrelated. All studied rocks are calc-alkaline in nature, with LILE/REE and HFSE/REE ratios compatible with arc related magmatism. Mafic phase has dioritic composition emplaced as small stocks in felsic rocks. Geochemical characteristics in dioritic rocks (relatively high contents of incompatible elements, low Na₂O and Mg#>44) suggest they were derived from partial melting of metabasalt sources in a subduction settings. Felsic phase composed of granodiorite to granite rocks with high-K calcalkaline metaluminous to slightly peraluminous signature. Major and trace element data exclude high pressure melting and metasedimentary parental in the formation of Zouzan felsic rocks. They have been formed by partial melting of mantle-derived mafic rocks. Field relation, petrographical evidences and chemical composition show that partial melting of a mantle wedge in conjunction with magma mixing and crystal fractionation would have led to generation of Zouzan pluton.     

Partial Melting Processes During Exhumation of Ultrahigh-Pressure Metamorphic Rocks in Dabieshan, China

INTRODUCTIONUptonowthereisinagreementonthetectonic-dynamicbackgroundoftheformationofUHPmetamorphicrocks,i.e.,theUHPMrocksareproductsofobliquecollisionbe-tweentheYangtzeandSinokoreancratonsinIndosinianstage(Jahn,1998lWangandCong,l998,1996;Lietal.,l997,l996iHackeretal.,l996ILiouet.al.,l9961Okay;Sen-gor,l993,CongandWang,l994;Sengor,1993).Buthowthesemetamorphicrocksareformedatmantledepthexhumedbacktothesurfacesorapidlyisstillastandingproblem-TheexhumationofUHPMrocksisacomplextectoni…     

Triassic shoshonites and andesites,Lakmon Mountains,western continental Greece: Differences in primary geochemistry and sheet silicate alteration products

Shallow marine lavas and pyroclastic rocks, several tens of metres thick, outcrop at the base of thrust slices in the Pindos nappe in the Lakmon Mountains of western continental Greece. These volcanic rocks are basalts and andesites formed during mid-Triassic subduction. Geochemically, on the basis of the potassium content, shoshonitic and calc-alkalic groups are distinguished. Principally the shoshonitic rocks contain primary K-feldspar. The calc-alkalic rocks contain complexly zoned feldspars and are depleted in intermediate REE: this depletion could reflect a small degree of partial melting of amphibole, or possibly phlogopite, during petrogenesis. These two characteristics are found in other examples of minor calc-alkalic rocks associated with shoshonites described in the literature. A petrogenetic model is developed involving deeper mantle enrichment in LILE and partial melting of this enriched mantle rock containing amphibole. Calc-alkalic rocks are the result of initial partial melting and may be mixed with small amounts of magma of deeper origin; further partial melting produces the more voluminous shoshonites. Celadonite developed as a secondary mineral during burial beneath about 1 km of Mesozoic to early Tertiary sediments. During nappe emplacement, vermiculite formed in the calc-alkalic rocks; in contrast, smectite developed in the shoshonites, because the potassium was sufficient to immobilize all available Fe in celadonite.     

Geochemistry and origin of the Archean Prince Albert Group volcanics,western Melville Peninsula,Northwest Territories,Canada

Major and trace element data on the Archean metavolcanic rocks of the Prince Albert Group (PAG), Northwest Territories. Canada, are reported. The following major groups were found, based on combined field and geochemical evidence: ultramafic flows; basaltic rocks, predominantly tholeiites; andesites; heavy REE depleted dacites; and rhyolites.The ultramafic and basaltic rocks are relatively normal Archean volcanics except for the downward bowed REE patterns of the tholeiitic basalts. The andesites, dacites and rhyolites, however, are not typical of Archean terrains. Comparisons between the andesites of the PAG and other Archean and more recent ones show that those of the PAG are most similar chemically to modern high-K andesites. REE patterns in these rocks suggest that partial melting of assemblages with significant garnet are an unlikely source but it is not possible to ascribe their origin to any simple process. Partial melting of a garnet-poor mafic granulite is an acceptable source for the heavy REE depleted dacites. The geochemical characteristics of the rhyolites cannot be explained by partial melting of a mafic source or by fractional crystallization from the daeites. It is suggested that these rocks originated by partial melting of pre-existing sialic crust.     

Triassic rift-related komatiite, picrite and basalt, Pelagonian continental margin, Greece

A wide range of Triassic rift-related volcanic rocks is preserved on the extensional continental margin of the central part of the Pelagonian micro-continental block of Greece, in the region of northern Evia Island and Othris. This part of the continental margin is unusual for the abundance of lavas, the wide range of lava types, and the presence of komatiitic lavas. The predominant rock types are subalkaline basalt and basaltic andesite, mildly alkaline basalt and picrite, and minor komatiite. Four groups of mafic rocks are distinguished from the 32 samples analyzed on the basis of variation in incompatible trace elements, with all but one group including both picritic and basaltic rocks. The geochemical character of the volcanic rocks suggests derivation from inhomogenous, spinel-bearing, lithospheric mantle. This mantle source was variably depleted and moderately refertilized by subduction-related fluids during earlier Hercynian subduction. The picrites were generated by variable degrees of partial melting, which are inferred to inversely correlate with pressure, thus suggesting decompression melting of their source. Evidence is lacking for a major mantle plume, but the enhanced magmatism in this sector of the rifted margin suggests that melting was induced by a large amount of hydration, which is appropriate to generate melts at lower temperatures. Consequent fractionation coupled with crustal assimilation generated the wide range of subalkaline to mildly alkaline mafic rocks.     

Partial melting of ultrahigh-pressure metamorphic rocks at convergent continental margins: Evidences,melt compositions and physical effects

Ultrahigh-pressure(UHP) metamorphic rocks are distinctive products of crustal deep subduction,and are mainly exposed in continental subduction-collision terranes. UHP slices of continental crust are usually involved in multistage exhumation and partial melting, which has obvious influence on the rheological features of the rocks, and thus significantly affect the dynamic behavior of subducted slices. Moreover,partial melting of UHP rocks have significant influence on element mobility and related isotope behavior within continental subduction zones, which is in turn crucial to chemical differentiation of the continental crust and to crust-mantle interaction.Partial melting can occur before, during or after the peak metamorphism of UHP rocks. Post-peak decompression melting has been better constrained by remelting experiments; however, because of multiple stages of decompression, retrogression and deformation, evidence of former melts in UHP rocks is often erased. Field evidence is among the most reliable criteria to infer partial melting. Glass and nanogranitoid inclusions are generally considered conclusive petrographic evidence. The residual assemblages after melt extraction are also significant to indicate partial melting in some cases. Besides field and petrographic evidence, bulk-rock and zircon trace-element geochemical features are also effective tools for recognizing partial melting of UHP rocks. Phase equilibrium modeling is an important petrological tool that is becoming more and more popular in P-T estimation of the evolution of metamorphic rocks; by taking into account the activity model of silicate melt, it can predict when partial melting occurred if the P-T path of a given rock is provided.UHP silicate melt is commonly leucogranitic and peraluminous in composition with high SiO_2,low MgO, FeO, MnO, TiO_2 and CaO, and variable K_2 O and Na_2 O contents. Mineralogy of nanogranites found in UHP rocks mainly consists of plagioclase + K-feldspar + quartz, plagioclase being commonly albite-rich.Trace element pattern of the melt is characterized by significant enrichment of large ion lithophile elements(LILE), depletion of heavy rare earth elements(HREE) and high field strength elements(HFSE),indicating garnet and rutile stability in the residual assemblage. In eclogites, significant Mg-isotope fractionation occurs between garnet and phengite; therefore, Mg isotopes may become an effective indicator for partial melting of eclogites.     

GEOCHEMICAL CHARACTERISTICS OF PLATINUM GROUP ELEMENTS IN JINCHUAN SUPER-LARGE SULFIDE COPPER-NICKEL DEPOSIT, JINCHANG CITY, GANSU PROVINCE, CHINA

The platinum-group element geochemistry of rocks and ores from Jinchuan super-large copper-nickel sulfide deposit is systemically studied in this paper. The Cu/Pd mean ratio of Jinchuan intrusion is lower than that of original mantle magma, which indicates that these ultrabasic rocks were crystallized from magma that lost Pd in the form of melting segregation of sulfides. The PGE of the rocks show trend of partial melting, similar to that of mantle peridotite, which shows that magma formation occurs during rock-forming and ore-forming processes. The chondrite normalized PGE patterns of the rocks and ores are well related to each other, which signifies the signatures of multi-episode magmatic intrusion, melting and differentiation in the formation processes of rocks and ores. In addition, analyses about the relation between PGE and S, and study on Re-Os isotopes indicate that few contamination of the crustal substances occurred during the magmatic intrusion and the formation of deposit. However, contamination by crustal substances helps to supply part of the S for the enrichment of PGE. Meanwhile, the hydrothermal process is also advantageous for the enrichment of PGE, especially lbr Pt and Pd, due to deep melting segregation. The characteristic parameters （such as Pt/（Pt＋Pd）, （Pt＋Pd）/（Ru＋Ir＋Os）, Pd/Ir, Cu/（Ni＋Cu）, and so on.） for platinum-group elements for Jinchuan sulfide copper-nickel deposit show the same features as those for sulfide copper-nickel deposit related to basic magma, which also illustrates its original magma property representative of Mg-high tholeiite. Therefore, it is the marie （not ultramafic） magma that resulted in the formation of the superlarge sulfide copper-nickel deposit enriched in Cu and PGE. To sum up, the geochemical characteristics of platinum-group elements in rocks and ores from Jinchuan copper-nickel sulfide deposit are constrained by the continental rift tectonic environment, the parent magma features, the enriched mantel magma source, the complex metallogenesis and PGE geochemical signatures, and this would be rather significant for the study about the genetic mechanism of copper-nickel sulfide deposits.     

金川超大型铜镍硫化物矿床的铂族元素地球化学特征

对金川超大型铜镍岩浆硫化物矿床岩石、矿石的铂族元素地球化学特征研究表明 ,金川岩体的平均Cu/Pd值远大于原生地幔岩浆的Cu/Pd值 ,说明其岩石为因硫化物析离而失去Pd的岩浆所结晶 ;且岩石的PGE具有部分熔融趋势 ,与地幔橄榄岩接近 ,这些均指示存在岩浆熔离作用。该矿床岩石、矿石的PGE球粒陨石标准化分布模式比较对应 ,均可分为两种类型 ,反映了岩浆多次侵入、熔离分异同时成岩成矿的特征。另外 ,PGE S关系分析表明其成岩成矿过程中有少量地壳物质混染。PGE地球化学特征参数还指示了其高镁拉斑玄武质母岩浆的性质。     

Geochemistry of Miocene shoshonites,Lesbos, Greece

Mid-Miocene shoshonitic volcanism in Lesbos is preceded and followed by minor calcalkaline activity that probably terminated in the Pliocene. Two differentiation trends are recognised in the shoshonites. The older shoshonites include voluminous acid rocks (mostly ignimbrites) and show normal shoshonite REE patterns. They were probably derived from partial melting of garnet peridotite enriched in LILE, with later fractionation controlled by anhydrous phases. Cooling units in the ignimbrites show upward increase in the K content of glass, suggesting K-feldspar fractionation in a high level magma chamber. Later shoshonites and the calc-alkali rocks have HREE enrichment and contain hydrous cognate xenoliths. Partial melting of a rising periodite diapir which had been relatively enriched in HREE within the garnet stability field and then entered the spinel stability field, would produce the observed HREE enrichment pattern. Later fractionation of these younger shoshonites and calc-alkali rocks was controlled largely by hydrous phases.     

藏南定结淡色花岗岩--基底隆升降压熔融成因的地质证据

西藏南部定结地区高喜马拉雅结晶基底中淡色花岗岩体紧靠藏南拆离断层内部产出．野外地质和岩相学特征显示其为S型、分两期侵入的淡色花岗岩体——早期的黑云母淡色花岗岩和晚期的白云母淡色花岗岩。基底副变质岩中广泛分布淡色花岗岩脉体．在基底副变质岩中的淡色花岗岩脉体中发现紫苏辉石暗色麻粒岩残留体，这表明本区高喜马拉雅淡色花岗岩源岩为基底副变质岩，且基底副变质岩是在基底快速隆升降压的条件下发生缺水熔融生成的淡色花岗岩岩浆。