大青山造山带中基底再造杂岩的特征及其指示意义

大青山造山带中基底再造杂岩主要由高温韧性剪切变形变质作用的糜棱片麻岩类、部分重烙作用形成的混合岩化糜棱片麻岩类及太古宙地壳残块三部分组成。进一步研究表明该基底再造条岩不仅可以作为一个特定的构造岩性单元，属于造山带根部地壳的一部分，而且其中前两部分既不属于太古富变质上壳岩和侵入岩系，也不属于早元古代变质上亮岩，而是早元古代造山带演化过程中，变形变质作用和部分重熔作用对太古宙基底综合改造作用的产物。基底再造杂岩的研究为进一步探讨前寒武纪克拉通内硅铝壳造山作用的性质、规模和成因机制提供了极为重要的地质证据和信息。     

大青山造山带中基底再造杂岩的特征及其指示意义

大青山造山带中基底再造杂岩主要由高温韧性剪切变形变质作用的糜棱片麻岩类、部分重烙作用形成的混合岩化糜棱片麻岩类及太古宙地壳残块三部分组成。进一步研究表明该基底再造条岩不仅可以作为一个特定的构造岩性单元，属于造山带根部地壳的一部分，而且其中前两部分既不属于太古富变质上壳岩和侵入岩系，也不属于早元古代变质上亮岩，而是早元古代造山带演化过程中，变形变质作用和部分重熔作用对太古宙基底综合改造作用的产物。基底再造杂岩的研究为进一步探讨前寒武纪克拉通内硅铝壳造山作用的性质、规模和成因机制提供了极为重要的地质证据和信息。     

吉林夹皮沟地区变质作用与地壳演化

本区经历四期变质作用,太古宙上壳岩系麻粒岩相变质、晚太古宙英云闪长岩高角闪岩相变质、早元古宙紫苏花岗岩类低角闪岩相变质和元古宙绿片岩相变质。麻粒岩相变质期可分三个阶段,早期角闪岩相、峰期麻粒岩相和晚期角闪岩相,其P-T-t轨迹为逆时针,与IBC型轨迹相似。导致麻粒岩相变质作用的热源为英云闪长质岩浆的垫托作用,形成于岛弧或活动大陆边缘。区内广泛发育的钾长花岗岩与晚太古宙高角闪岩相变质作用晚期的深熔作用有关。     

吉林省太古宙TTG岩类固结的温度压力条件

吉林省太古宙ＴＴＧ岩类型成于变质上壳岩系麻粒岩相变质作用晚期阶段。详细的岩相学研究表明，ＴＴＧ岩类中存在岩浆结晶的绿帘石，角闪石和黑云母等。绿帘石的出现标志了一定的压条件。     

中国华北地区太古宙的基本地质特征

华北地区太古宙和早元古宙的变质岩系,其出露面积占整个华北地台的44％。其中各类岩石所占的比例为:麻粒岩4.2％,片麻岩和混合岩48.4％,变质火山岩及其相伴的沉积变质岩8.7％,年龄老于20亿年的花岗岩和花岗闪长岩38.7％。太古宙由大面积分布的片麻岩和混合岩以及少量另星出露的麻粒岩组成,相当于片麻岩——麻粒岩区;早元古宙的早期以变质的火山岩系和变质沉积岩系为特征,可与浅变质的绿岩——片岩带相     

吉南大荒沟—板石沟地区早前寒武纪变质变形作用及地壳演化

本区早前寒武纪地壳曾经历了三期区域变质和变形作用：中太古宙最早期是上壳岩系沉积的形成，后来在２．６０５Ｇａ时发生角闪岩相区域变质作用，至晚期是英云闪长岩的侵位，并伴生有韧性剪切变形；晚太古宙时期，上壳岩系和英云闪长岩于２．５３８Ｇａ前后发生低角闪岩相变质，在晚期出现ＮＥ向韧性剪切变形事件；至早元古宙时期，早期是黑云钾长花岗岩侵入活动，大约在２．３８０Ｇａ时发育了绿片岩相变质，并发生二次浅层次的ＮＷ     

北京地区太古宙岩石同位素年龄及其意义

北京地区太古亩大漕．沙厂表壳岩系的麻粒岩相区域变质作用年龄,苇子峪TTG(A)－MMe杂岩中表壳岩系的高角门岩相区域变质作用年龄,以及两个单元中的早期TTG质岩成岩年龄均为2650Ma左右,推测表壳岩成岩时代为中太古代晚期;四合堂表壳岩系的低角闪岩相区域变质作用年龄和该单元内太古宙TTG质岩的成岩时代约为2539Ma至2580．7Ma,推测表壳岩系成岩时代为新太古代早期（2650～2800Ma）;阳坡地TTG-M-Me杂岩中的太古宙晚期ITG质岩成岩时代为2522~2563Ma,推测其中表壳岩系的角闪岩相区域变质作用及早期TTG质岩的成岩时代稍大于2563Ma;马圈子TTG-M-Me杂岩中TTG质岩成岩时代为新太古代晚期（2500～2650Ma）。结论为本区太古宙表壳岩系峰期区域变质作用和太古宙TTG质岩形成时代均发生于新太古代。     

北京地区太古宙岩石,地层单元划分及其特征

北方市密云、怀柔、平保和昌平地区太古宙岩石可划分为混合岩化表壳岩系和非层状岩系两大类岩石、地层单元。前者包括大漕－沙厂混合岩化表壳岩系和四合堂混合岩化表壳岩系;后者主要为ＴＴＧ（Ａ）－Ｍ－Ｍｅ杂岩,它包括苇子峪、阳坡地、马圈子、对角沟门和冯家峪等杂岩。太古宙表壳岩系的原岩建造有杂砂岩＋英安质、安山质炎山岩及其碎屑岩＋铁硅质沉积岩建造,含铁硅质岩的绿岩建造和绿岩建造三类。表壳岩系区域变质作用和太古宙     

北京地区太古宙岩石同位素年龄及其意义

北京地区太古宙大漕－沙厂表壳岩系的麻粒岩相区域变质作用年龄,苇子峪ＴＴＧ（Ａ）－Ｍ－Ｍｅ杂岩中表壳岩系的高角闪岩相区域变质作用年龄,以及两个单元中的早期ＴＴＧ质岩成岩年龄均为２６５０Ｍａ左右,推测表岩成岩时人代为中太古代晚期,四合堂表壳岩系的低角闪岩相区域变质作用年龄和该单元内太古宙ＴＴＧ质岩的成岩时代约为２５３９Ｍａ至２５８０．７Ｍａ推测表壳岩系成岩时国新太古代早期（２６５０～２８００Ｍａ）阳坡     

抚顺东部地区紫苏花岗质岩石特征及成因

抚顺东部地区紫苏花岗质岩石形成于晚太古宙，以包体形式产于黑云长英质片麻岩中。许多特征均说明，它并非由紫苏北岗质岩浆直接结晶形成的，而是源岩在部分熔融与分凝过程中产生的残留相、后经麻粒岩相变质作用及构造变形改造所致的再造岩石。     

川西—滇东地区早元古宙变质岩系及其区域变质作用与地壳演化

在川西—滇东地区,前人一直将会理群、昆阳群等作为该区所出露的最古老的地层,并认为它们代表了扬子地台的最老基底。笔者通过对该区详细的变质地质研究认为,在它们之下还存在着一套与之完全不同的层状变质岩系,我们将其称为康定群,推测其时代至少为早元古宙或晚太古宙。它与中、晚元古宙的会理群、昆阳群等共同构成了扬子地台的古老基底,为基底的两个重要的地质构造单元,分别代表了本区早期地壳演化的不同阶段。     

Pressure–temperature evolution of metapelitic granulites in a polymetamorphic terrane: the Rauer Group, East Antarctica

Distinctive lithological associations and geological relationships, and initial geochronological results indicate the presence of an areally extensive region of reworked Archaean basement containing polymetamorphic granulites in the Rauer Group, East Antarctica.
Structurally early metapelites from within this reworked region preserve complex and varied metamorphic histories which largely pre-date and bear no relation to a Late Proterozoic metamorphism generally recognized in this part of East Antarctica. In particular, magnesian metapelite rafts from Long Point record extreme peak P–T conditions of 10–12 kbar and 100–1050°C, and an initial decompression to 8 kbar at temperatures of greater than 900°C. Initial garnet–orthopyroxene–sillimanite assemblages contain the most magnesian (and pyrope-rich) garnets ( X _Mg= 0.71) yet found in granulite facies rocks. A high-temperature decompressional P–T history is consistent with reaction textures in which the phase assemblages produced through garnet breakdown vary systematically with the initial garnet X _Mg composition, reflecting the intersection of different divariant reactions in rocks of varied composition as pressures decreased. This history is thought to relate to Archaean events, whereas a lower-temperature ( c. 750–800°C) decompression to 5 kbar reflects Late Proterozoic reworking of these relict assemblages.
The major Late Proterozoic ( c. 1000 Ma) granulite facies metamorphism is recorded in a suite of younger Fe-rich metapelites and associated paragneisses in which syn- to post-deformational decompression, through 2–4 kbar from maximum recorded P–T conditions of 7–9 kbar and 800–850°C, is constrained by geothermobarometry and reaction textures. This P–T evolution is thought to reflect rapid tectonic collapse of crust previously thickened through collision.     

新疆前震旦纪地层划分及地壳演化

根据变质地质学的观点,新疆的前震旦纪地层可划分为太古界、下元古界和中一上无古界,它们在岩石组合、原岩建造、变质作用类型及形成环境等方面具有明显的区别,同时表明古西北陆台具有与古华北陆台完全不同的地质发展历史。     

华北燕山期区域变质与内生成矿作用关系雏议

初步讨论了华北地区燕山期区域变质作用与内生成矿作用的关系。指出华北地区众多内生金属矿床产于绿片岩相岩石组合中，其中包括太古宙岩石的退变质、沉积盖层和中生代火山-侵入杂岩的进变质岩石。因此，这些矿床的形成与燕山期区域变质作用及其相应的韧性-韧脆性变形作用密切相关。     

Tectonic framework of the Precambrian of Madagascar and its Gondwana connections: a review and reappraisal

The Precambrian of Madagascar is divided into two sectors by the north-west trending sinistral Ranotsara shear zone, which continues in the Mozambique belt, probably as the Surma shear zone, and in Southern India as the Achankovil shear zone. South of Ranotsara six north-south trending tectonic belts are recognized that consist largely of granulite and high amphibolite facies paragneisses, phlogopite diopsidites, concordant granites and granulites. North of Ranotsara the central-northern segment is traversed by a north-trending axial 100–150 km wide dextral shear zone of probable Pan-African age, which was metamorphosed under granulite and high amphibolite facies conditions and which has reworked older basement. This shear zone continues across southern India as the Palghat-Cauvery shear zone. Major stratiform basic -ultrabasic complexes occur in the axial zone and in the basement to the west. Well preserved low grade continental margin-type sediments (quartzites, mica schists and stromatolitic marbles) of Kibaran age are present in western Madagascar. Two partly greenschist grade sedimentary groups lie unconformably on high grade basement in north-east Madagascar. Isotopic age data suggest the presence in Madagascar of Archaean, Early and Mid-Proterozoic crustal material that was extensively reworked in Pan-African times.     

Metamorphic and tectonic domains of China

Abstract Ten metamorphic domains can be distinguished in China, comprising four cratonic, three intracratonic and three intercratonic domains. Each domain contains one or more metamorphic belts, each of which, in turn, contains a characteristic metamorphic facies or facies series that was formed during a distinct metamorphic epoch.
The metamorphic domains reflect the tectonic domains and tectonic evolution of China. Ancient continental nucleii in the North China and Tarim–Alxa cratons were probably unified with the Yangtze craton during the Early Proterozoic to form the China Platform. Widespread greenschist facies metamorphism, during the Middle and Late Proterozoic, accompanied by glaucophane–greenschist facies metamorphism, represents a rifting and closure event in the China Platform; a second rifting and closure event in the China Platform occurred during the Caledonian. The China and Siberian platforms were closed during the Hercynian to form the Eurasian Continent. Closure of the ancient Tethys Ocean occurred in the Indosinian epoch, and subduction and collision within Xizang (Tibet) and Taiwan occurred during Mesozoic–Cenozoic time.
The distribution in time of types of metamorphism in China suggests cyclical changes of metamorphism known as the Archaean, Proterozoic and Phanerozoic megacycles. Each megacycle since the Archaean consists of a change from progressive, low- to intermediate-grade metamorphism to lower grade, greenschist metamorphism that was superimposed on a general trend in which high-grade metamorphism became progressively less important with time. The change in metamorphic megacycles shows a general secular decrease in regional heat supply during metamorphism punctuated by episodic high-grade, progressive metamorphism within orogenic belts.     

Two types of Precambrian high-grade metamorphism, Inner Mongolia, China

Abstract Archaean and Proterozoic granulite facies complexes of Inner Mongolia differ in lithological association, tectonic style, mineral assemblage and metamorphic P–T path. A nearly isobaric cooling path for Archaean high-grade metamorphic rocks is suggested by reaction textures and geothermobarometry. Early Proterozoic metamorphic rocks show nearly isothermal decompression. Archaean metamorphism may have been caused by magmatic accretion, whereas early Proterozoic metamorphism suggests a major continental thickening event followed by exhumation.     

中国东北麻山杂岩晚泛非期变质的锆石SHRIMP年龄证据及全球大陆再造意义

中国东北地区佳木斯地块南部麻山杂岩正、副片麻岩 7个样品的锆石 SHRIMP年龄数据首次明确地表明 ,东北地区存在 500 Ma的晚泛非期高级变质作用事件。峰期麻粒岩相变质导致柳毛地区 (502± 10)Ma (2σ )深熔花岗岩的形成。正、副片麻岩变质年龄的一致性表明它们已在变质前发生了构造叠置。西麻山副片麻岩中含有在后期麻粒岩相变质过程中未重结晶的碎屑锆石，由此形成从协和一致的 550 Ma到弱不一致 1 900 Ma的较大 207Pb/206Pb年龄变化范围，表明其原岩具有从新元古代到中元古代-古元古代的年龄。柳毛地区变质的片麻状闪长岩中所含的古老锆石的 207Pb/206Pb年龄为 546～ 1 460 Ma表明，该闪长岩大约在 1 400 Ma就位，并受到 500 Ma变质事件的影响，从而说明柳毛地区存在中元古代基底。然而，与以前的认识相反，麻山杂岩不存在具有太古宙基底的同位素证据。晚泛非期变质事件年龄的确定对重塑晚前寒武纪-显生宙早期麻山杂岩和佳木斯地块的古地理位置具有重要意义。根据目前获得的有关证据，认为佳木斯地块可能曾经位于冈瓦纳大陆北缘的华北克拉通附近。     

The early Precambrian history of rock metamorphism in the Urals segment of crust

Early Precambrian rock units in the Urals are present in several polymetamorphic complexes, which are exposed in the Urals in the form of small (<1500 km²) tectonic blocks. Their ages are Archaean (as old as 3.5 Ga) and Palaeoproterozoic. During the formation of these complexes in the early Precambrian, two stages of ultra-high-temperature (granulite) metamorphism occurred. The maximum age of the early Neoarchaean stage of metamorphism is 2.79 Ga. Evidence of this metamorphic event includes the dating of the Taratash gneiss-granulite complex of the South Urals. Gneiss-migmatite complexes, which dominate the lower Precambrian section of the Urals, were formed in the Palaeoproterozoic during the sequential appearance of granulite facies metamorphism followed by amphibolite facies metamorphism and accompanying granitization. The maximum age of the Palaeoproterozoic stage of granulite metamorphism in the Alexandrov gneiss-migmatite complex, the most well-studied complex in the South Urals, is 2.08 Ga.     

Palaeoproterozoic terrane assembly in the Lewisian Gneiss Complex on the Scottish mainland,south of Gruinard Bay: SHRIMP U–Pb zircon evidence

New SHRIMP U–Pb zircon geochronology and fieldwork integrated with reappraisal of earlier mapping demonstrates that the so-called ‘southern region’ of the mainland Lewisian Gneiss Complex comprises a package of distinct tectono-stratigraphic units. From south to north these are the Rona (3135–2889 Ma), Ialltaig (c. 2000 Ma) and Gairloch (ca. 2200 Ma) terranes. These terranes were metamorphosed and deformed separately until ca. 1670 Ma by which time they had been juxtaposed and were integral with terranes to the north. The northern boundary of the Palaeoproterozoic Gairloch terrane is a shear zone, north of which is the Archaean Gruinard terrane with 2860–2800 Ma protoliths and ca. 2730 Ma granulite facies metamorphism. In contrast, south of the Gairloch terrane, the Archaean gneisses of the Rona terrane have older protolith ages, underwent an anatectic event at ca. 2950 Ma and show no evidence of 2730 Ma granulite facies metamorphism. In current structural interpretations the Gruinard terrane forms a structural klippe over the intervening Gairloch terrane. However, the Rona and Gruinard terranes cannot be equivalent on age grounds, and are interpreted as unrelated different entities. Contained within the southern margin of the Gairloch terrane is the Ialltaig terrane, shown here to comprise an exotic slice of granulite facies Palaeoproterozoic crust, rather than Archaean basement as previously thought. The ca. 1877 Ma granulite facies metamorphism of the Ialltaig terrane is the youngest event that is unique to a single terrane in the mainland Complex, making it an upper estimate for the timing of amalgamation with surrounding tectonic units. U–Pb titanite ages of 1670 ± 12 Ma and ca. 1660 Ma for low-strain zones at Diabaig are interpreted to be cooling through the titanite closure temperature after the amphibolite facies reworking of these southern terranes and the southern margin of the Gruinard Terrane. These new data have implications for the tectonic setting of the mainland in relation to the Outer Hebrides and in the wider evolution of the basement in the North Atlantic.