东南极格罗夫山镁铁质麻粒岩的变质作用

东南极内陆－格罗夫山存在一套经历了麻粒岩相变质作用的镁铁质麻粒岩和斜长角闪岩。变质反应结构显示该区多为单一的区域性麻粒岩相变质作用。但是，对含石榴石的镁铁质麻粒岩的详细工作则显示了包括3个阶段的近等温降压（ITD）的顺时针PT演化轨迹，M1：0．93GPa＞800℃：M2:0.65GPa,733-850℃;M3:0.46-0.61GPa，并有着与拉斯曼丘陵相似的演化历史。根据矿物组合和成分、变质反应结构及温压计算结果，格罗夫山镁铁质麻粒岩可能为高压麻粒岩。     

麻粒岩相变质流体及麻粒岩相岩石成因

流体在麻粒岩相地钵形成过程中所扮演的角色是有争议的。麻粒岩相变质流体目前的研究成果可归纳为碳变质模式、无流体变质模式和高盐度流体变质模式。碳变质模式强调幔源CO2在麻粒岩形成过程中起着非常重要的作用，这一模式在许多麻粒岩相地体得到了肯定。但碳、氧稳定同位素的不均一现象、峰期矿物组合热力学计算结果以及富CO2流体对硅酸盐的搬运能力低使碳变质受到了质疑。无流体变质模式强调部分熔融降低H2O活度的绝对重要性，但却无法解释普遍存在的麻粒岩相原生富CO2包裹体。而高盐度流体变质模式的确有潜在的优势，如低H2O活度、较强的碱金属、LILE及硅酸盐的搬运能力，但这一理论需要进一步证实。     

东南极拉斯曼丘陵泥质麻粒岩变质作用演化

普里兹湾拉斯曼丘陵代表了东南极一条重要的早古生代的～530Ma泛非期(Pan-African)高级构造活动带。然而,该区早期的晚元古代的～1000Ma格林维尔期(Grenvellian)高级变质作用的演化历史至今仍有争论。该区呈透镜状产出的泥质麻粒岩峰期矿物组合(M1)为石榴石+堇青石+斜方辉石+钾长石+石英,峰期石榴石变斑晶发育堇青石或堇青石+斜方辉石反应边(M2)。利用Thermocalc程序在KFMASH模式体系对该泥质麻粒岩进行的定量模拟表明,其峰期矿物组合是由反应石榴石+黑云母+石英=堇青石+斜方辉石+钾长石+熔体形成的。利用Themocalc平均P-T计算方法获得峰期M1变质P-T条件为～0.9GPa和～900℃,而叠加的M2组合反映了一个减压冷却的过程,其变质P-T条件为～0.7GPa和800～850℃。结合已有的年代学数据,认为该区泥质麻粒岩的峰期M1矿物组合反映晚元古代(～1000Ma)格林维尔期挤压D1构造事件,而叠加的M2矿物组合与M3蠕虫状结构则形成于早古生代泛非期(～530Ma)D2～D3高级扭压剪切构造期间。该扭压事件导致了面状高低应变带的发育以及进步花岗岩和伟晶岩的侵入。     

东南极拉斯曼丘陵麻粒岩相岩石中早期残留矿物组合的特征及其变质…

东南极拉斯曼丘陵出露的麻粒岩相泥质片麻岩和镁铁质麻粒岩经历了复杂的变形变质历史。代表前进的增厚事件的早期残留变质构造Ｄ１形成于１０００Ｍａ期间。对应于Ｄ１的变质峰期Ｍ１的变质组合以泥质片麻岩的石榴石和尖晶石变斑晶中的堇青石和夕线石包裹体以及镁铁质麻粒岩的石榴石变斑晶中的斜方辉石和斜长石包裹体为特征。在该区斯托罗斯半岛的紫苏黑云石英岩的粗粒紫苏辉石中发现了包裹的假蓝宝石＋磁铁石和假蓝宝石＋尖晶石＋夕     

云开隆起低压麻粒岩相变质作用时代的重要发现

首次报道云开隆起低压麻粒岩９５０Ｍａ左右的变质作用年龄，结合麻粒岩的岩相学以及区域地质特征，指出晋宁期云开地区处于拉张的构造环境。     

冀东麻粒岩相区的变质作用及其演化

根据对表壳岩、中酸性侵入岩和基性岩墙的变质变形作用及相互关系的深入研究,确定冀东麻粒岩相区在早前寒武纪时期主要经历了两期变质作用,每期变质作用均经历了一个长期的演化过程,峰期阶段的变质条件均达到了麻粒岩相。第一期变质作用(3000～2500Ma)的PTt演化具近等压冷却(IBC)特点的逆时针轨迹,第二期变质作用(2300～2000Ma)是近等压加热(IBH)特点的顺时针轨迹,反映两期变质作用具有不同的构造环境和演化过程。     

冀东地区麻粒岩相变质作用的演化

据冀东迁安－遵化一带麻粒岩相区的变质岩石、变质矿物及其组构特征、变质作用的温度、压力条件,结合同位素年代学资料,以及岩浆作用、构造变形作用和变质作用之间的关系,可将本区太古代变质作用划分为两期。太古代第一期变质作用只限于表壳岩包体岩石中,变质级为高角闪岩相和辉石麻粒岩相,第二期变质作用发生在晚太古代,早期变质阶段是在紫苏花岗岩侵位以后发生的辉石麻粒岩相变质作用,晚期变质阶段发生在稍后侵位的基性侵入岩体、英云闪长岩、奥长花岗岩等深成侵入体中,变质级达角闪麻粒岩相。早元古代第一期角闪石榴二辉麻粒岩型岩脉,遭受了辉石麻粒相变质作用,第二期角闪石榴斜长辉石岩型岩脉经历了角闪麻粒岩相变质作用。这些变质作用在早期岩石中都有不同程度的叠加。麻粒岩相变质作用的温度在７００℃～９２０℃,压力在０．８８～１．１４ＧＰａ。变质作用的ＰＴｔ演化呈现了逆时针近等压冷却的轨迹     

麻粒岩相变质作用的PTt演化及其地质动力学意义

麻粒岩地体和基性火山岩中的麻粒岩包体是研究过去和现在下部地壳的窗口,通过它们的研究可了解下地壳的物质组成,物理和化学状态,构造变形,岩浆作用和变质作用的特征,并进而探讨大陆地壳形成和改造的地质动力学机制。当前研究中涉及许多重要问题,如麻粒岩相变质作用的PTt演化和成因模式及其构造环境、变质流体的含量、成分和作用,岩浆作用的性质和机制及其对麻粒岩相变质作用的贡献,构造变形作用的样式及其所反映的构造体制,麻粒岩中LILE亏损等地球化学特征的成因意义等等。这些问题互相联系,都是麻粒岩地体成因的约束条件。本文将讨论麻粒岩相变质作用的PTt演化特征,阐述大地构造环境和地质动力学机制对其所起的约束作用。     

东南极格罗夫山变质基性岩地球化学特征

东南极格罗夫山变质基性岩的地球化学研究表明，该区存在两类玄武岩，即洋岛型玄武岩（OIB）和洋中脊型玄武岩（MORB）。OIB型具有大体类似的地球化学性质，它们均富集Ti（TiO2＝2．68％）、REE＝（202μg/g）、LREE[（La/Yb)N＝4．8]、Ti/Y（＝343）、Zr／Y(＝3．1），具洋岛玄武岩的特征，推测岩浆来源于富休地幔源区（EM）。而MORB型以低Ti（TiO2＝1．1％－1．31％），明显低于OIB的P的含量（P2O5＝0．1％－0．2％），低REE（47－93μg/g）。LREE／HREE（2．27－2．54）、（La/Yb)N（＝1．30－1．62）为特征，具洋中脊玄武岩的特征。MORB和OIB组合的出现说明在泛非期该区可能存在过洋分。     

东南极内陆格罗夫山地区冰厚及冰下地形特征

中国第30次南极科学考察队格罗夫山分队(CHINARE30, 2013-2014年)利用雪地车载深层探冰雷达在东南极格罗夫山地区开展了测线总长度超过200 km大范围、高分辨率的冰厚及冰下地形调查, 获得了哈丁山北部和萨哈罗夫岭与阵风悬崖之间详细的冰厚及冰下地形特征. 通过对雷达数据分析表明, 哈丁山北部区域平均冰厚为580 m, 最大冰厚超过1 000 m, 出现在该区域的东北方向, 而东南方向冰厚相对较小; 萨哈罗夫岭与阵风悬崖之间区域的平均冰厚为610 m, 最大冰厚超过1 100 m, 该区域槽谷发育十分成熟, 槽谷形态近似呈U型. 通过对雷达剖面影像的筛选和分析, 推测在格罗夫山地区可能存在2个液态冰下湖泊.     

Pan-African Alkali Granitoids from the Sør Rondane Mountains, East Antarctica

Alkali granitoids (500-550 Ma) representing a prominent Pan-African magmatic event are widely distributed in the Sør Rondane Mountains, Dronning Maud Land, East Antarctica. Geochemically, they are granitic to syenitic in composition and show an alkaline affinity of A-type granites. They are characterized by high K₂O+Na₂O (7-13 wt%) and K₂O/Na₂O (1-2), low to intermediate Mg#, wide ranges of SiO₂ (45-78 wt%), Sr (20-6500 ppm) and Ba (40-13000 ppm) and have Nb and Ti depletion in the primitive mantle normalized diagram. The granitoids are subdivided into Group I granites, Group II granites, Lunckeryggen Syenitic Complex and Mefjell Plutonic Complex. The Group I granites have higher Mg#, Sr/Ba, Sr/Y, (La/Yb)_N and LREE/HREE, lower A/CNK, SREE and initial ⁸⁷Sr/⁸⁷Sr ratios and lack Eu anomalies compared to those with negative Eu anomalies in the Group II granites. The syenitic rocks from the Mefjell Plutonic Complex are higher in alkali, Ga, Zr, Ba, and have lower Mg#, Rb, Sr, Nb, Y, F and LREE/HREE with positive Eu anomaly, whereas the granites from the Mefjell Plutonic Complex have high LREE/HREE ratios with negative Eu anomaly. The Lunckeryggen syenitic rocks have intermediate Mg#, higher K₂O, P₂O₅, TiO₂, Fe₂O₃/FeO, Ba, Sr/Y and LREE/HREE ratios with lack of Eu anomalies and are lower in Al₂O₃, Ga, Y, Nb and Rb/Sr ratios. Based on chemical characteristics combined with isotopic data, we suggest that the Lunckeryggen syenitic body and Group I granitic bodies may be derived from the mantle-derived hot basic magma by fractional crystallization with minor assimilation. We also suggest that the Group II granites may be derived from assimilation with crustal rocks to varing degrees and then fractional crystallization in higher crustal levels (ACF model). The Mefjell Plutonic Complex seems to be derived from a heterogenetic magma source compared with other granitoids from the Sør Rondane Mountains. The syenitic rocks in the Mefjell Plutonic complex have a unique source (iron-enriched) and have a chemical affinity with the charnockites in Gjelsvikjella and western Mühlig-Hofmannfjella, but not like the Yamato syenites in adjacent areas.     

大别山铙钹寨被麻粒岩相变质作用改造的变质超镁铁岩体：石榴辉石岩证据

对大别山铙钹寨超镁铁岩体中石榴辉石岩的研究表明，铙钹寨岩体经历了从尖晶石－富铝辉石相（750度，1．1GPa)，尖晶石－石榴石相（850度，1．5GPa)到麻粒岩相（800度，0．85GPa)的变质演化，该岩体与南大别超高压变质杂岩的演化过程存在很大差异，它基本上处于一较高温地热体制之下，属于南大别俯冲陆壳的上盘杂岩，铙钹寨岩体及其它超镁铁岩体的普遍麻粒岩化与区域麻粒岩相的相关性可能说明大别变质基底已被彻底改造，北大别（安徽省内）目前所展示的高级变质作用仅是印支期后麻粒岩相变质事件的反映。     

东南极泛非普里兹带：碰撞造山带还是板内造山带

东南极普里兹带是近几年在南极大陆上识别出的一条重要的泛非期构造带，因其成因涉及到冈瓦纳超大陆在寒武纪时的形成与演化问题，因此一直是国际地学界关注的焦点。但到目前为止，对于该造山带的构造属性还存在着不同的认识，有些人认为它是板内造山带，而另一些人认为它是两个大陆板块之间的碰撞带。其基本特征是：普里兹带两侧为前泛非期不同性质的岩石圈单元，整个区域经历了早期中一下地壳挤压逆冲和晚期中一上地壳伸展垮塌的构造演化历史，区域麻粒岩相变质作用表现为近等热减压的顺时针p-t轨迹。此外，东南极克拉通与冈瓦纳其他块体在500Ma前的古地磁极移曲线并不一致。所以，尽管目前尚未发现蛇绿岩套、岛弧增生杂岩或高压变质岩等直接指相标志，但这些特征均反映了普里兹带是板间碰撞拼合的缝合带，而不是板内造山带，东南极地盾本身则是由不同块体在泛非期拼合而成的。     

Charnockite composition in relation to the tectonic evolution of East Antarctica

Charnockitic suites in central Dronning Maud Land (DML), Mac.Robertson Land (MRL), and the Bunger Hills area are compositionally varied and probably include both mantle and lower-crustal components. In this paper we present new geological and geochemical data on the DML charnockitic rocks, and compare their geochemistry with that of charnockitic rocks from several other Antarctic high-grade terranes, particularly MRL and the Bunger Hills. These areas have different geological histories and one of the main aims of this study is to investigate possible links between charnockite composition and the tectonic history of their host terranes. Antarctic charnockitic rocks form two distinct compositional groups. 510 Ma DML charnockites are relatively alkalic and ferroan, with high K₂O, Zr, Ga, Fe / Mg, and Ga / Al, and very low MgO, characteristic of A-type (alkaline, commonly anorogenic) granitoids. The more mafic DML rocks, at least, were derived by fractionation of a relatively alkaline high-P–Ti ferrogabbro parent magma. Most other early Palaeozoic charnockitic rocks in Antarctica are of similar composition. In contrast, MRL (c. 980 Ma) and Bunger Hills (c. 1170 Ma) charnockites are mainly calc-alkalic or calcic and magnesian, and the associated mafic components are tholeiitic. MRL and Bunger Hills charnockites are late-orogenic, whereas DML charnockites are post-orogenic, and appear to have been emplaced after post-collision extension and decompression. These two mineralogically and geochemically distinct charnockite groups may thus reflect a compositional trend in an evolving orogen, either accretional or collisional, respectively.     

Early Cambrian crustal shortening and a clockwise P–T–t path from the southern Prince Charles Mountains, East Antarctica: implications for the formation of Gondwana

Cambrian orogenesis (550–490 Ma) in the Lambert Province of the southern Prince Charles Mountains resulted in three successive stages of deformation. The earliest of these deformations resulted in the development of a layer‐parallel foliation (S1) that was folded into macro‐scale recumbent folds (F2). Subsequent deformation buckled the rocks into long‐wavelength (c. 20 km), SW‐ to NW‐trending antiformal closures (F3) mostly separated from each other by west to SW trending, steeply dipping, high‐strain zones. Metapelitic rocks from the region are divisible into two compositional types: a high‐Al, ‐Fe and ‐K type and a high‐Mg, ‐Ca and ‐Na type. In rocks of both composition, relic staurolite preceded the formation of upper amphibolite facies garnet + biotite + sillimanite ± muscovite mineral assemblages that record peak pressures and temperatures of c. 650–700 °C and 6–7 kbar. Subsequent decompression of c. 3 kbar is implied from texturally late plagioclase and a reduction in the modal abundance of garnet in the high‐Al, ‐Fe and ‐K metapelites, and from texturally late cordierite in the more magnesium rocks. This clockwise P–T–t path, with prograde heating followed by rapid decompression, is: (i) equivalent to that recorded in the same‐aged rocks at Prydz Bay located 600 km to the north, and (ii) similar to the modelled response of the crust to thickening following continent–continent collision. These results indicate that large areas of East Antarctica were thickened and rapidly exhumed, probably in response to collisional orogenesis during the Early Cambrian. This supports the inference that Early Cambrian orogenesis in the Prydz Bay–Prince Charles Mountains region of East Antarctica marks one of the fundamental lithospheric boundaries within Gondwana.     

东南极格罗夫山陨石(GRV 052382):一块强烈冲击变质的橄辉无球粒陨石

GRV052382陨石是在南极格罗夫山地区发现的强烈冲击变质的橄辉无球粒陨石。它主要由橄榄石(75%)、易变辉石(5%)、富碳填隙物(20%)和少量金属组成。橄榄石呈半自形等粒细晶结构,颗粒大小约10~20μm,细晶颗粒间有少量辉石质的熔融填隙物。根据富碳填隙物分布和颗粒间的裂隙,可以区分出原粗粒橄榄石结构的轮廓,原颗粒大小约0.5~1.5mm。这些原粗粒橄榄石具有还原边结构,即边缘的橄榄石细晶富MgO,而核部橄榄石细晶富FeO。因强烈的还原作用,这些原粗粒橄榄石的核部成分变化大(Fa12.2-21.8),因此,原橄榄石核部成分Fa应为21.8%或略高。易变辉石呈浑圆粒状,大小约0.4~0.9mm,在颗粒之间其成分基本相当(En76.4-82.6Wo4.6-9.8Fs10.9-13.8),但在颗粒内部因冲击作用,产生波浪状韵律成分变化。富碳质填隙物充填在原粗粒橄榄石颗粒之间,主要由碳质和富MgO的硅酸盐组成。碳质多型主要为石墨,呈不规则蠕虫状或网脉状,大小约0.2~0.4mm,其中包含有少量金刚石颗粒(约1~3μm)。因此,这些特征表明GRV052382具有橄辉无球粒陨石结构,为单矿岩质橄辉无球粒陨石。根据橄榄石成分,GRV 052382陨石被进一步划分为富FeO亚型(I型)。此外,强烈冲击变质特征,即:(1)橄榄石冲击细晶结构;(2)橄榄石细晶颗粒具有圆化特征,其间存在熔融填隙物;(3)易变辉石晶体具有波浪状韵律成分变化;(4)易变辉石中存在大量不规则气孔;(5)金属Fe沿裂隙或气孔充填;(6)石墨发生金刚石相变等,表明GRV052382陨石的冲击变质程度为S6。因此,GRV052382陨石可能是经受最强烈冲击变质的橄辉无球粒陨石,这不仅为橄辉无球粒陨石的冲击历史提供直接证据,而且有可能获得其母体早期经历的冲击作用信息。     

东南极格罗夫山地区铷含量初步调查及手持矿石分析仪的可行性研究

本文对东南极格罗夫山地区出露的基岩样品进行实验室地球化学分析,结果显示出该地区明显的铷元素富集。所测试的123个样品主要为花岗岩、闪长岩、花岗片麻岩、片麻岩等,其中15个样品的铷含量达到0.04%,2个样品的铷含量达到0.1%以上。同时,利用手持快速矿石分析仪(NITON XL3t-500S GOLDD)对该地区213件岩石样品以及92件粉末样品进行测试,并将测试结果与实验室分析结果进行对比分析。分析对比发现,虽然手持快速矿石分析仪相对实验室测试存在一定误差,但是两种测试方法的铷含量随样品表现出一致的变化趋势,且粉末样品相对岩石样品误差明显偏小。