赣中变质岩带变质带的重新划分及变质作用P-T条件的确定

根据随变质作用增强而出现的特征变质矿物及矿物组合,对赣中变质岩带重新划分出五个变质带,由低到高依次为绢云母一绿泥石带、黑云母带、铁铝榴石带、十字石带、夕线石带。在对各变质带变质矿物进行详细研究的基础上,采用石榴石-黑云母(Gt-Bi)、斜长石-角闪石(Pl-Hb)、石榴石-十字石(Gt-St)、石榴石-角闪石(Gt-Hb)、石榴石-斜长石-夕线石-石英(Gt-Pl-Sil-Q)、石榴石-斜长石-黑云母-白云母(Gt-Pl-Bi-Mu)等多种地质温压计确定了各变质带的形成温度、压力,绢云母-绿泥石带的形成温度为250-350℃,压力为0.25-0.35GPa;黑云母带的形成温度为350-450℃±,压力为0.25-0.40GPa±;铁铝榴石带的形成温度为450-550℃±,压力为0.40～0.60GPa±;十字石带的形成温度为550-600℃±,压力为0.50-0.60GPa±;夕线石带的形成温度为600-650℃±,压力为0.55-0.65GPa±,赣中变质岩带峰期变质作用已达到角闪岩相。     

相山地区变质基底新认识及其原归属的对比研究

在相山北部首次发现十字石片岩及堇青石片岩。根据随变质作用增强而出现的新变质矿物，将相山变质岩基底划分为绢云母千枚岩带、黑云母征 岩带、铝榴石片岩带和十字 石片岩带。提出并采用微量元素地球化学比值聚类分析方法，确认相山地区变质岩原岩不属震旦系，而与华在睡地块（古了南）的陈蔡群相当。     

相山地区变质基底新认识及其原岩归属的对比研究

在相山北部首次发现十字石片岩及堇青石片岩。根据随变质作用增强而出现的新变质矿物，将相山变质岩基底划分为绢云母千枚岩带、黑云母片岩带、铁铝榴石片岩带和十字石片岩带。获得相山地区黑云母片岩－十字石片岩的Ｒｂ－Ｓｒ等时线年龄值为７１９Ｍａ，斜长角闪片岩的Ｒｂ－Ｓｒ等时线年龄值为７２６．６Ｍａ，表明相山基底变质岩属新元古期变质岩而不是加里东期变质岩。提出并采用微量元素地球化学比值聚类分析方法，确认相山地区变质岩原岩不属震旦系，而与华夏地块（古陆）的陈蔡群相当。     

浙西南陈蔡群变质阶段划分及变质作用p—T—D轨变研究

按照构造变形不同阶段变质矿物生长发育特征，浙西南陈蔡群变质作用可分为四个阶段，变质阶段Ｉ与Ｄ１变形同期，变质矿物共生组合为绿泥石＋黑云母＋白云母＋斜长石＋石英，相当于绿片岩相变质；变质阶段Ⅱ发生于Ｄ１变形和Ｄ２变形这间的静态期，变质矿物共生组合为十字石＋石榴石＋斜长石＋石英＋黑云母＋白云母，变质温度范围为±５１０℃，压力为０．７ＧＰａ；变质阶段Ⅲ与Ｄ２变形同期或稍后，变质矿物共生组合为矽线石＋石榴     

陕西宽坪群某些前进变质矿物的研究

在宽坪群区域变质作用研究中,通过对某些前进变质矿物(角闪石、斜长石、黑云母、白云母、石榴石)成分结构的分析,不仅为了解这类矿物形成时的物理化学条件提供了较可靠的信息,而且为变质相带划分和变质相系确定提供了重要依据。这类矿物分布广,一般贯通整个变质带。其形态、光性及成分、结构随变质温度和压力的变化,显示宽坪群自南向北前进变质带(低绿片岩相—高绿片岩相—低角闪岩相)的存在或区域热流的分布状况。白云石和角闪石的成分及结构反映其形成于中压环境。这与变质泥质岩中出现的蓝晶石、十字石、铁铝榴石组合反映的中压相系特征是一致的。     

芬兰早元古代普奥兰卡耶尔维组的变质与构造演化——Ⅰ.构造与结构关系

角闪岩相的普奥兰卡耶尔维组(PjF)位于芬兰北部早元古代卡伊努片岩带(KSB)的西缘。PjF的下部和中部由浊积砂质岩和泥质岩、暴风雨沉积的半泥质岩组成。该文集中论述其岩性,包括含有不同数量石榴石、十字石、红柱石和黑云母变斑晶以及矽线石和堇青石分凝作用的石英-二云母-斜长石片岩。     

浙西南陈蔡群变质阶段划分及变质作用p－T－D轨迹研究

按照构造变形不同阶段变质矿物生长发育特征，浙西南陈蔡群变质作用可分为四个阶段。变质阶段Ⅰ与Ｄ＿１变形同期，变质矿物共生组合为绿泥石＋黑云母＋白云母＋斜长石＋石英，相当于绿片岩相变质；变质阶段Ⅱ发生于Ｄ＿１变形和Ｄ＿２变形之间的静态期，变质矿物共生组合为＋字石＋石榴石＋斜长石＋石英＋黑云母＋白云母，变质温度范围为士５ｌ０℃，压力为０．７ＧＰａ；变质阶段Ⅲ与Ｄ＿２变形同期或稍后，变质矿物共生组合为矽线石＋石榴石＋斜长石＋石英＋黑云母＋白云母士钾长石，变质温度范围为６００～６５０℃，压力为０．５５～０．６５ＧＰ３；变质阶段Ｎ发生在Ｄ＿３或Ｄ＿３之后，变质矿物共生组合为绿泥石＋白云母，相当于低绿片岩相变质。根据构造变形不同阶段变质温度、压力变化所建立起来的ｐ－Ｔ－Ｄ轨迹，能够用来反映浙西南陈蔡群变质作用发生的构造环境。     

南秦岭造山带东段的变质作用及其地质意义

南秦岭造山带分布于商丹和勉略两条缝合线之间,其东段变质地层以志留系和泥盆系为主,包括少量的震旦系和上古生界。主要岩性包括变质泥质岩、石英岩、大理岩和少量的变质基性岩及片麻岩等。根据野外分布和显微组构特征发现这些岩石至少遭受了两期变质作用:早期为递增变质作用,它以佛坪地区的高角闪岩相—麻粒岩相为中心,向外依次变为低角闪岩相(十字石—蓝晶石带)、绿帘角闪岩相(石榴石带)和绿片岩相(绿泥石和黑云母带),变质时代约为220～260 Ma。麻粒岩相以出现二辉石为特征,包括基性和中酸世麻粒岩等,野外只见于佛坪县城附近。高角闪岩相在泥质岩石中的矿物组合为夕线石-石榴石-黑云母-斜长石-钾长石-石英,其变质条件为t=688～693℃,P=0.5～0.6 GPa;低角闪岩相在泥质岩石中的矿物组合为蓝晶石(十字石)-石榴石-黑云母-白云母-斜长石-石英,其变质条件为t=570～598℃,P-0.7～1.0 CPa;绿帘角闪岩相在泥质岩石中的矿物组合为石榴石-黑云母-白云母-斜长石-绿泥石-石英,变质条件为t=518～545℃,P=0.5～0.8GPa;绿片岩相的矿物组合为白云母-绿泥石-石英-斜长石-(黑云母),其变质压力为0.6～0.65 GPa,温度可能为400～450℃。采用Spear提出的吉布斯方法,以石榴石变斑晶的环带变化得到高角闪岩相、低角闪岩相     

佛子岭群变质岩石学变质作用及时代的初步研究

佛子岭群是北淮阳地区分布较广的地层单位之五。主要岩石类型为长石石英岩、细粒石英岩、含蓝晶石英片岩和含石英白质大理岩，变质矿物在蓝晶石、石榴石、黑云母及白云母等。根据石榴石－黑云母矿物对计算温度约５２０℃，压力为０．３－０．５ＧＰａ。主变质作用年龄为３７８±２４Ｍａ。     

晋北娄烦吕梁群变质相带的划分及其成因研究

晋北娄烦吕梁群由一套经受过两期不同性质变质作用的泥砂质岩、基性火山岩和酸性流纹岩组成。早期为吕梁期变质作用,其结果使该区地层构造形迹总体上呈NE走向;晚期为西川河韧性剪切断裂所产生的区域变质作用,其结果使该区地层走向由早期的NE向扭转为近SN向,且使地层层序发生倒转,并与递增变质带的形成关系密切。选取该区中对变质温度和压力变化反映较敏感的原岩为泥砂质岩石的袁家村组和裴家庄组地层为研究对象,采用电子探针微区分析(EPMA)对沿地层走向上连续分布的特征变质矿物及矿物共生组合特征进行研究,并利用矿物对地质温度计估算该区不同采样点的变质温度和压力条件,对研究区进行变质相带的划分,确定各变质相带的变质温、压条件,并探讨其成因。研究结果表明,袁家村组和裴家庄组为等化学系列地层。沿该地层走向上:西川河断裂以北地区,从北向南,特征变质矿物绿泥石、黑云母、石榴石、十字石和蓝晶石依次规律出现;西川河断裂以南地区,红柱石和夕线石依次规律出现。根据特征变质矿物的空间分布规律、首次出现的地点及矿物共生组合特征,划分出5个变质带:绿泥石带、黑云母带、石榴石带、十字石-蓝晶石带和红柱石-夕线石带。这一完整的递增变质带可与苏格兰高地的巴罗型相媲美。矿物对地质温度计估算结果。     

南米仓山变质岩变质时代及地质意义

通过对汪家坪岩组的两件黑云斜长变粒岩变质岩样品进行LA-ICP-MS锆石U-Pb年代学研究,获得的⁽²⁰⁶⁾Pb/(206)Pb/⁽²³⁸⁾U年龄介于843.3(238)U年龄介于843.3⁹04.9Ma之间,最古老的年龄达1138.46±16.7Ma,表示南米仓山结晶基底在新元古代早期曾发生过强烈的构造-岩浆活动;具有变质锆石特征的样品,获得的年龄数据表明南米仓山地区在新元古代发生过两期变质作用,早期的变质作用峰值年龄约为810.0904.9Ma之间,最古老的年龄达1138.46±16.7Ma,表示南米仓山结晶基底在新元古代早期曾发生过强烈的构造-岩浆活动;具有变质锆石特征的样品,获得的年龄数据表明南米仓山地区在新元古代发生过两期变质作用,早期的变质作用峰值年龄约为810.0⁹00.0Ma,代表着晋宁末期华北大陆板块与扬子板块逐渐对接拼合,古秦岭洋壳迅速向南北两侧俯冲消减事件;晚期变质作用发生在约为550.0900.0Ma,代表着晋宁末期华北大陆板块与扬子板块逐渐对接拼合,古秦岭洋壳迅速向南北两侧俯冲消减事件;晚期变质作用发生在约为550.0⁷60.0Ma,记录了这一阶段的澄江期岩浆热事件引起的接触变质事件。     

新疆西天山高压变质带的变质矿物与变质作用演化

新疆西天山高压变质带主要由石榴石，角闪石，绿辉石，多硅白云母，钠云母，绿帘石，绿泥石，钠长石，石英，榍石和金红石等组成，石榴石主要含铁铝榴石组份，角闪石有蓝闪石，亚铁蓝闪石，青铝闪石，冻蓝闪石等类型，变质矿物组合显示高压变质带经历了由硬柱石蓝片岩相，榴辉岩相，绿帘蓝片岩相至绿片岩相的变质作用演化进程。     

Metamorphic K-Feldspar in Low-grade Metasediments from the Ogcheon Metamorphic Belt in South Korea

Metamorphic K-feldspar was found in the low-grade pelitic rocks from the Ogcheon metamorphic belt in South Korea. It occurs as extremely fine-grained crystals (5-15 mm in width and 15-25 mm in length) closely associated with fine-grained muscovite and biotite. Their micro structural relations by X-ray mapping analyses using an electron-probe microanalyzer strongly suggest that K-feldspar has grown directly from the matrix phases as a stable phase coexisting with muscovite and biotite during the Ogcheon metamorphism. The phengite component in muscovite indicates about 4.2 kbar at 400°C, suggesting intermediate P/T type of metamorphism. Muscovite separates of two size fractions, 2-4 and 4-8 mm, give K-Ar ages of 153.4±3.3 and 156.7±3.4 Ma, respectively. The biotite separate is 156.5±3.3 Ma in age. Coarse-grained biotite crystal (ca. 0.5 mm) often occurs and it was analyzed by ⁴⁰Ar/³⁹Ar method using a laser probe step heating technique. It gives a plateau age of 158.2±0.5 Ma that is the same as the K-Ar muscovite and biotite ages. These data, including the previous works, suggest that intermediate P/T type of Ogcheon metamorphic belt exhumed in Middle Jurassic with the dextral strike-slip fault movement.     

贵州前寒武系区域变质岩的主要变质时期

贵州前寒武系变质岩主要有区域变质岩。区域变质作用有两上重要的递进发展阶段,有泥盆纪时期的埋深静压变质作用和燕山期的动压变质作用。     

近70年中国变质岩石学-变质地质学的研究进展

为总结我国变质地质学的历史经验,回顾了我国从变质岩石学到变质地质学近70年的发展历程.依据大量文献,分3个阶段和8个方面总结了变质岩石学和变质地质学取得的进展.我国在超高压变质地质学、早前寒武纪变质地质学、变质作用年代学、变质作用相平衡模拟等领域处于国际先进行列,蓝片岩、变质流体和变质岩化学动力学方面与世界研究基本处于同步水平,极低级变质作用研究等领域与国际先进水平尚有较大差距.通过历史的回顾,表明变质岩的研究已经从变质岩石学转变为变质地质学,已经从单一的岩石学研究转变为以变质岩为基础,变质矿物、地球化学、同位素地质、构造地质等多学科的综合研究.在变质岩和变质地质领域我国有一些区位优势,但是只有坚持自主创新才能把区位优势转变为学科优势.各种分析实验技术的发展促进了变质地质学的发展,随着新技术的不断涌现和大数据时代的来临,变质地质学会有更大的发展.      

超高压变质岩的塑性流变学

岩石流变作用是大陆造山作用的基本特征,超高压岩石的形成和折返过程也是大陆深俯冲带内物质的复杂流变过程。要深入理解大陆造山带的造山作用和大陆壳岩石的深俯冲和折返动力学过程,必须对大陆地壳及地幔岩石的流变学进行深入研究。岩石圈流变学的主要研究内容主要包括流变学分层性、变形分解和应变局部化及大陆壳岩石部分熔融作用的流变学效应等。应用岩石圈流变学的基本原理和方法,分析了大别-苏鲁超高压变质带中超高压变质岩的塑性流变特点,探讨了超高压变质岩形成和折返过程的塑性流变学。     

On the Initiation of Metamorphic Sulfide Anatexis

Mineral assemblages in common sulfide ore deposits are examinedtogether with phase relations to (1) investigate the pressure–temperatureconditions required for the onset of metamorphically inducedpartial melting involving economic minerals, and (2) place constraintson the amount of melt produced. Deposits that contain sulfosaltor telluride minerals may start to melt at conditions rangingfrom lowest greenschist facies to amphibolite facies. Depositslacking sulfosalt and/or telluride minerals may begin to meltonce P–T conditions reach the upper amphibolite facies,if galena is present, or well into the granulite facies if galenais absent. The result is two broad melting domains: a low- tomedium-temperature, low melt volume domain involving meltingof volumetrically minor sulfosalt and/or telluride minerals;and a high-temperature, potentially higher melt volume domaininvolving partial melting of the major sulfide minerals. Epithermalgold deposits, which are especially rich in sulfosalt minerals,are predicted to commence melting at the lowest temperaturesof all sulfide deposit types. Massive Pb–Zn (–Cu)deposits may start to melt in the lower to middle amphibolitefacies if pyrite and arsenopyrite coexist at these conditions,and in the upper amphibolite facies if they do not. Exceptingsulfosalt-bearing occurrences, massive Ni–Cu–PGE(platinum group element) deposits will show little to no meltingunder common crustal metamorphic conditions, whereas disseminatedCu deposits are typically incapable of generating melt untilthe granulite facies is reached, when partial melting commencesin bornite-bearing rocks. The volume of polymetallic melt thatcan be generated in most deposit types is therefore largelya function of the abundance of sulfosalt minerals. Even at granulite-faciesconditions, this volume is usually less than 0·5%. Theexception is massive Pb–Zn deposits, where melt volumessignificantly exceeding 0·5 vol. % may be segregatedinto sulfide magma dykes, allowing mobilization over large distances. KEY WORDS: sulfide melt; ore deposits; melt migration; metamorphism     

Petrology, Origin and Metamorphic History of Proterozoic-aged Granulites of the Natal Metamorphic Province, Southeastern Africa

The geochemistry of the Leisure Bay Formation, Natal Metamorphic Province suggests that its protoliths were greywackes, pelites and arkoses that were deposited in an oceanic island arc environment. These rocks contain the mineral assemblage biotite + hypersthene + cordierite (with hercynite inclusions) + garnet + quartz + feldspar. Numerous generations of garnet genesis are evident from which a long history of metamorphism can be interpreted. M₁ involved syn-D₁ high temperature/low pressure metamorphism (4kb and >850^oC) and dehydration melting to produce essentially anhydrous assemblages particularly in the vicinity of, and probably related to the intrusion of the Munster Suite sills. The inclusions of hercynite in cordierite and the garnet + quartz symplectites after hypersthene + plagioclase (550^oC and 5kb) suggests isobaric cooling after M₁. This indicates an anticlockwise P-T loop related to the early intrusion of subduction related calc-alkaline magmatic rocks. M₂ involved syn-D₂ dehydration melting of hydrous assemblages possibly related to the emplacement of many A-type rapakivi charnockite granitoids, which provided heat and loading. The D₂ tectonism post-dated all lithologies in the region, except for syn- to late-D₂ granitoid plutons, and is interpreted as a transpressional tectonothermal reworking of pre-existing (Proterozoic) crust at 1030Ma.     

Rb-Sr and Sm-Nd Mineral Isochron Ages of the Metamorphic Rocks in the Namaqualand Metamorphic Complex, South Africa

Rb-Sr and Sm-Nd isotopic studies were carried out for metamorphic rocks in the Namaqualand Metamorphic Complex, South Africa. The metamorphic rocks give the Rb-Sr mineral isochron ages (whole-rock - biotite - felsic fractions) of 844±85 Ma and 811.6±6.6 Ma for the lower granulite zone and of 776.5±5.4 Ma for the upper granulite zone. The rocks yield the Sm-Nd mineral isochron ages of 1071±18 Ma (whole-rock - garnet - felsic fractions) and 1067±158 Ma (whole-rock - hornblende - biotite rich fraction - felsic fractions) for the lower granulite zone and of 1052.0±3.6 Ma and 1002.5±1.4 Ma (whole-rock - garnet - felsic fractions) for the upper granulite zone. These age data suggest that the granulite facies metamorphism took place at 1060-1000 Ma, and that the rocks cooled down at 850-780 Ma. The Sr and Nd isotopic compositions of metamorphic rocks are different between the lower and upper granulite zones.