Chloritoid–glaucophane schist in the north Qilian orogen, NW China: phase equilibria and P–T path from garnet zonation

Chloritoid–glaucophane‐bearing rocks are widespread in the high‐pressure belt of the north Qilian orogen, NW China. They are interbedded and cofacial with felsic schists originated from greywackes, mafic garnet blueschists and low‐T eclogites. Two representative chloritoid–glaucophane‐bearing assemblages are chloritoid + glaucophane + garnet + talc + quartz (sample Q5‐49) and chloritoid + glaucophane + garnet + phengite + epidote + quartz (sample Q5‐12). Garnet in sample Q5‐49 is coarse‐, medium‐ and fine‐grained and shows two types of zonation patterns. In pattern I, X_grs is constant as X_py rises, and in pattern II X_grs decreases as X_py rises. Phase equilibrium modelling in the NC(K)MnFMASH system with Thermocalc 3.25 indicates that pattern I can be formed during progressive metamorphism in lawsonite‐stable assemblages, while pattern II zonation can be formed with further heating after lawsonite has been consumed. Garnet growth in Q5‐49 is consistent with a continuous progressive metamorphic process from ～14.5 kbar at 470 °C to ～22.5 kbar at 560 °C. Garnet in sample Q5‐12 develops with pattern I zonation, which is consistent with a progressive metamorphic process from ～21 kbar at 540 °C to ～23.5 kbar at 580 °C with lawsonite present in the whole garnet growth. The latter sample shows the highest P–T conditions of the reported chloritoid–glaucophane‐bearing assemblages. Phase equilibrium calculation in the NCKFMASH system with a recent mixing model of amphibole indicates that chloritoid + glaucophane paragenesis does not have a low‐pressure limit of 18–19 kbar as previously suggested, but has a much larger pressure range from 7–8 to 27–30 kbar, with the low‐pressure part being within the stability field of albite.     

大别造山带白垩纪花岗岩对太古宙基底的再造: 来自U-Pb年代学、Sr-Nd-Hf同位素的证据

本文对大别造山带大崎山花岗岩进行了系统的野外调查、岩石学、地球化学、锆石U- Pb- Hf和Sr- Nd同位素研究。锆石U- Pb定年结果显示大崎山花岗岩形成于早白垩世,年龄为124~120 Ma。样品具有较高的SiO2(69. 3%~75. 2%)、Al2O3(13. 4%~15. 3%)和全碱(7. 94%~8. 71%)含量,较低的MgO(0. 23%~0. 84%)、TiO2(0. 16%~0. 49%)与TFeO(1. 05%~2. 66%)含量,A/CNK=1. 01~1. 03,显示弱过铝质特征。岩石富集大离子亲石元素(如Rb、K、Pb)、轻稀土元素以及Th、U等,亏损高场强元素(如Nb、Ta、Ti)、重稀土元素以及Sr和Ba,具有明显Eu负异常(δEu=0. 34~0. 52),属于高钾钙碱性的I型花岗岩,这些地球化学特征表明大崎山花岗岩经历了以斜长石、钾长石和磷灰石为主的分离结晶作用。白垩纪锆石εHf(t)值为〖CD*2/3〗32. 9~〖CD*2/3〗15. 2,对应tDM2为3258~2140 Ma,全岩εNd(t)为〖CD*2/3〗22. 5~〖CD*2/3〗15. 8,对应tDM2=2754~2209 Ma,指示岩浆源区主要为古老地壳物质。样品中含有大量的~2. 65 Ga继承锆石,锆石εHf(t)为〖CD*2/3〗7. 3~3. 6,显示与贾庙地区2. 65~2. 63 Ga片麻状花岗岩有良好的亲缘性。大崎山花岗岩可能源自北大别变质带太古宙基底的再造,其源区还存在年轻地壳物质的参与,可能形成于古太平洋板块的俯冲板片在130 Ma后快速后撤的伸展背景。     

云南永平县水泄辉长岩锆石U- Pb年代学、地球化学及地质意义

滇西地区二叠纪—三叠纪岩浆岩展布还不清楚,导致相关古特提斯构造演化模型还存在争议。本文对兰坪-思茅盆地西缘水泄地区的辉长岩开展了LA-ICP-MS锆石U-Pb定年、锆石Hf同位素、全岩主微量元素及Sr-Nd同位素分析,探讨了岩石成因及地质意义。水泄辉长岩2件样品的锆石U-Pb年龄分别为237.8±3.4 Ma和240.8±3.3 Ma,代表其结晶年龄,属于中三叠世。样品具有较高的Na₂O/K₂O(3.81～49.14),明显富集Ba、Rb、Th、U等大离子亲石元素,相对亏损Nb、Ta等高场强元素,稀土元素弱分馏,轻稀土弱富集,δEu值为0.87～1.07,无明显的Eu异常。锆石ε_Hf(t)值全为正值,主要介于+5.67～+15.75,全岩初始⁸⁷Sr/⁸⁶Sr比值为0.70453～0.70776,ε_Nd(t)值全为正值,介于+4.9～+5.2。地球化学特征显示水泄辉长岩来源于亏损地幔的部分熔融,在岩浆演化过程中发生了镁铁质矿物和铁钛矿物的分离结晶作用。水泄...     

喜马拉雅造山带中段亚东地区石榴角闪岩的成因：岩石学和锆石U- Pb年代学

喜马拉雅造山带中段出露的基性麻粒岩是理解印度大陆前喜马拉雅期演化历史和新生代碰撞造山作用的理想研究对象。本文对亚东多庆湖地区的石榴角闪岩进行了岩石学、全岩主微量元素地球化学和锆石U- Pb年代学研究,揭示了其原岩类型和新生代的变质作用过程。石榴角闪岩的原岩很可能为新元古代(~890 Ma)的玄武岩,具有E- MORB型岩石的地球化学特征。石榴角闪岩具有三期矿物组合：① 进变质矿物组合可能为石榴子石+角闪石+斜长石+钛铁矿+石英,即石榴子石核部及其中包裹体;② 峰期矿物组合为石榴子石+角闪石+斜长石+黑云母+石英,即石榴子石边部和基质矿物;③ 退变质矿物组合为角闪石+斜方辉石+斜长石+黑云母+石英,包括退变质域和石榴子石边部的后成合晶矿物。矿物温压计和相平衡模拟表明,石榴角闪岩进变质、峰期和退变质条件分别为609~621℃和0. 59~0. 65 GPa、805~845℃和0. 91~1. 04 GPa、825~840℃和0. 61~0. 68 GPa,经历了峰期高压麻粒岩相的变质作用。锆石U- Pb年代学研究表明,石榴角闪岩的峰期变质时间为34. 8~20. 3 Ma,退变质时间为18. 1~17. 7 Ma,可能经历了一个较长期的部分熔融过程。本文研究认为,亚东石榴角闪岩是印度板块向欧亚板块长期俯冲、地壳增厚成因的基性麻粒岩,原岩可能与Rodinia超大陆拼合相关;其以加热埋藏、近等温降压为特征的顺时针P- T轨迹指示了喜马拉雅造山带中段的大喜马拉雅岩系上部构造层位经历了长期持续的地壳增厚和高温麻粒岩相变质作用,以及早中新世(21~17 Ma)相对快速的减压抬升和随后(17 Ma之后)相对缓慢的折返至地表的演化过程。     

西藏冈底斯造山带几乎同时形成的两套埃达克岩为什么一套含矿一套不含矿？

野外地质调查结合锆石U-Pb年龄测定和岩石化学成分分析,发现西藏冈底斯碰撞造山带晚中新世发育两套埃达克岩.一套呈NS向岩墙产出,锫石U-Pb-LAICP-MS年龄为15.6～16.8 Ma,地球化学上以富Na2O、贫K2O、Sr/Y比值高为特点,不含矿;另一套呈岩株产出,锆石 U-Pb SHRIMP 年龄为14.0～15.3 Ma,地球化学上以富K2O、贫NaO、Sr/Y比值低为特点,伴随着大规模的斑岩型铜钼矿化.两套埃达克岩都高度富集大离子不相容元素(LILE)Rb、Ba、Th、U、K、Sr、Pb,强烈亏损高场强元素(HFSE)Nb、Ta、Ti,反映出俯冲组分对岩浆源区的明显影响,具备岛弧岩浆作用的基本特征.比较而言,含矿埃达克岩更富集Rb、Th、U、K、Pb,而不含矿埃达克岩更富集Sr;不含矿埃达克岩的高场强元素Nb、Ta、Ti亏损更加强烈,Zr、Hf相对富集.两套埃达克岩都是形成于碰撞后地壳伸展的同一地球动力学背景下,其岩石地球化学差异主要与岩浆源区有关.研究表明,含矿埃达克岩的岩浆源区较浅,位于下地壳底部,参与岩浆作用的俯冲组分以沉积物熔体为主,岩浆的氧化性较强,并且经历了更多的分异过程.不含矿埃达克岩的岩浆源区较深,位于岩石圈地幔上部,参与源区岩浆作用的俯冲组分主要是板片流体,岩浆氧化性较低,岩浆分异过程较少.两套埃达克岩含矿与不含矿的原因包含了源区物质组成和岩浆生成条件两方面的差异.     

http://www.sciencedirect.com/science/article/pii/S1674987113001333

The basement of the Romanian Carpathians is made of Neoproterozoic to early Paleozoic periGondwanan terranes variably involved in the Variscan orogeny,similarly to other basement terrains of Europe.They were hardly dismembered during the Alpine orogeny and traditionally have their own names in the three Carpathian areas.The Danubian domain of the South Carpathians comprises the Dragsan and Lainici-Paius peri-Amazonian terranes.The Dragsan terrane originated within the ocean surrounding Rodinia and docked with Rodinia at ~800 Ma.It does not contain Cadomian magmatism and consequently it is classified as an Avalonian extra-Cadomian terrane.The Lainici-Paius terrane is a Ganderian fragment strongly modified by Cadomian subduction-related magmatism.It is attached to the Moesia platform.The Tisovita terrane is an ophiolite that marks the boundary between Dragsan and Lainici-Paius terranes.The other basement terranes of the Romanian Carpathians originated close to the Ordovician NorthAfrican orogen,as a result of the eastern Rheic Ocean opening and closure.Except for the Sebes-Lotru terrane that includes a lower metamorphic unit of Cadomian age,all the other terranes(Bretila,Tulghes,Negrisoara and Rebra in the East Carpathians,Somes,Biharia and Baia de Aries in the Apuseni mountains,Fagaras,Leaota,Caras and Pades in the South Carpathians) represent late Cambrian—Ordovician rock assemblages.Their provenance,is probably within paleo-northeast Africa,close to the Arabian-Nubian shield.The late Cambrian-Ordovician terranes are defined here as Carpathian-type terranes.According to their lithostratigraphy and origin,some are of continental margin magmatic arc setting,whereas others formed in rift and back-arc environment and closed to passive continental margin settings.In a paleogeographic reconstruction,the continental margin magmatic arc terranes were first that drifted out,followed by the passive continental margin terranes with the back-arc terranes in their front.They accreted to Laurussia during the Variscan orogeny.Some of them(Sebes-Lotru in South Carpathians and Baia de Aries in Apuseni mountains) underwent eclogite-grade metamorphism.The Danubian terranes,the Bretila terrane and the Somes terrane were intruded by Variscan granitoids.     

江南造山带东段桃岭岩体的地球化学特征及其成因

位于江南造山带东段赣东北地区的桃岭岩体地球化学特征总体表现为高钾钙碱性系列,弱过铝质-强过铝质,高Mg#值。桃岭岩体富集轻稀土和大离子亲石元素,亏损高场强元素,具弱的Eu负异常(δEu=0.62~0.81)(样品TL-1除外δEu=0.47)。锆石LA—ICPMS U—Pb定年获得桃岭岩体的成岩年龄为早白垩世(140±1)Ma。岩体初始~(87)Sr/~(86)Sr为0.7131~0.7141,ε_(Nd)(t)值为-7.43~-6.71。结合前人研究,笔者认为早白垩世(约140 Ma)交代的地幔发生部分熔融,幔源岩浆底侵,使地壳深处(至少40 km)的变质沉积岩发生部分熔融,并且与少量的幔源岩浆发生了岩浆混合作用,形成了桃岭岩体。     

Tectono-magmatic evolution from accretion to collision in the southern margin of the Central Asian Orogenic BeltSCIEI北大核心CSCD

造山带演化及增生到碰撞的转变是板块构造与大陆动力学研究中的前沿科学问题。中亚造山带被认为是古亚洲洋长期俯冲-增生演化形成的显生宙最大的增生造山带,以发育巨量的面状展布的俯冲-增生相关的弧岩浆岩为特征。并且,由于中亚增生型造山带在潘吉亚最后聚合过程中发生弧弧(陆)碰撞,因此缺乏大规模且跨构造单元的碰撞相关的构造和变质等物质标志。显然,能否识别出大洋闭合期间碰撞作用的岩浆标志成为确定增生造山带增生过程终止的关键之一。本文系统研究确定:中亚造山带东南缘二叠纪到三叠纪钙碱性-碱钙性岩浆在空间分布上显示出由北西向南东迁移演化的特征;在岩浆性质上具有从二叠纪新生地壳来源的弧岩浆向早-中三叠世碰撞挤压背景下古老陆壳组分逐渐增多的高Sr/Y岩浆以及晚三叠世后造山伸展相关的A型花岗岩演化的特征。这些特征提供了俯冲-增生向碰撞造山演变的关键岩浆岩证据。结合区域资料,厘定出增生造山带最后碰撞相关的标志性岩浆为沿缝合带呈零星线性展布的增厚下地壳源区的高Sr/Y花岗岩类,构建了中亚造山带南缘从双向俯冲-增生到增生楔-增生楔碰撞及后造山伸展的三阶段构造-岩浆演化模型。系统对比研究,揭示出增生-碰撞相关的岩浆记录沿横向展布在中亚造山带南缘甘肃北山到吉林中部一带,表明碰撞挤压相关的岩浆作用在中亚造山带南缘具有一定的普适性。中亚造山带南缘从增生到碰撞的岩浆演化记录的厘定,证实显生宙最大的巨型增生造山带演化末期经历了碰撞造山作用,对进一步深入探索增生造山演化末期碰撞相关的标志性岩浆具有重要意义。     

苏鲁造山带池庄超高压榴辉岩中变质脉:大陆俯冲带超临界流体活动的证据

高压-超高压变质岩中的变质脉能够反映俯冲带变质流体的组成和演化。为了探究大陆俯冲带超临界流体活动及伴随的元素迁移,本文系统地研究了苏鲁造山带南部江苏东海池庄地区的超高压榴辉岩及变质脉。变质脉主要是由石英、石榴石、绿辉石、多硅白云母、蓝晶石、黝帘石、金红石和锆石等矿物组成,与寄主榴辉岩的矿物组成类似。相比于榴辉岩,脉体中的石榴石更加富集重稀土元素(HREE);黝帘石强烈富集轻稀土元素(LREE)。变质脉和榴辉岩中各主要矿物的氧同位素组成在误差范围内一致(石英的δ18O分别为2.42‰和2.79‰;石榴石为-0.30‰和0.010‰;绿辉石为0.25‰和0.071‰),说明变质脉的形成与榴辉岩释放的内部流体有关。综合已有的研究,发现大别-苏鲁造山带不同地区的变质脉和榴辉岩具有极不均一的氧同位素组成,说明在陆壳深俯冲和折返过程中,流体活动有限。利用矿物温压计得到变质脉的峰期变质温压条件为692±65℃和3.6±0.3GPa,脉体中锆石U-Pb定年结果表明锆石的形成时代为218±2.4Ma,指示变质脉形成于深俯冲陆壳折返初期的超高压变质阶段。变质脉中矿物组合和矿物的主微量元素特征说明成脉流体富集Si、Al、Ca、K、LILE、REE和HFSE等元素,表明成脉流体可能是溶解能力极强的超临界流体。     

White mica K–Ar geochronology of Sanbagawa eclogites from Southwest Japan: implications for deformation-controlled K–Ar closure temperature

White mica (phengite and paragonite) K–Ar ages of eclogite-facies Sanbagawa metamorphic rocks (15 eclogitic rocks and eight associated pelitic schists) from four different localities yielded ages of 84–89 Ma (Seba, central Shikoku), 78–80 Ma (Nishi-Iratsu, central Shikoku), 123 and 136 Ma (Gongen, central Shikoku), and 82–88 Ma (Kotsu/Bizan, eastern Shikoku). With the exception of a quartz-rich kyanite-bearing eclogite from Gongen, white mica ages overlap with the previously known range of phengite K–Ar ages of pelitic schists of the Sanbagawa metamorphic belt and can be distinguished from those of the Shimanto metamorphic belt. The similarity of K–Ar ages between the eclogites and surrounding pelitic schists supports a geological setting wherein the eclogites experienced intense ductile deformation with pelitic schists during exhumation. In contrast, phengite extracted from the Gongen eclogite, which is less overprinted by a ductile shear deformation during exhumation, yielded significantly older ages. Given that the Gongen eclogite is enclosed by the Higashi-Akaishi meta-peridotite body, these K–Ar ages are attributed to excess ⁴⁰Ar gained during an interaction between the eclogite and host meta-peridotite with mantle-derived noble gas (very high ⁴⁰Ar/³⁶Ar ratio) at eclogite-facies depth. Fluid exchange between deep-subducted sediments and mantle material might have enhanced the gain of mantle-derived extreme ⁴⁰Ar in the meta-sediment. Although dynamic recrystallization of white mica can reset the Ar isotope system, limited-argon-depletion due to lesser degrees of ductile shear deformation of the Gongen eclogite might have prevented complete release of the trapped excess argon from phengites. This observation supports a model of deformation-controlled K–Ar closure temperature.