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1.
怀安蔓菁沟早前寒武纪高压麻粒岩混杂岩带地质特征,岩石学和同位素… 总被引:7,自引:10,他引:7
华北克通北缘中段怀安蔓菁沟高压麻粒岩混杂岩带产在太古宙怀安杂岩南缘与花岗岩带交界处,由高压其性麻粒岩,辉长质麻粒岩,英云闪长质麻粒岩和少量夕线石榴片麻岩相间排列的席状岩层物估算的早期高压变质作用条件:T=800C,P>1.4GPa。环绕斑晶的后成合晶反应边矿物组合的变质条件为:T=820C,P为0.7-0.9GPa。全岩Sm-Nd等时时线年龄2.65Ga,矿物Sm-Nd等年龄1.82Ga,锆石U- 相似文献
2.
张宣高变质花岗岩-绿岩带内早期花岗质侵入体是以英云间长岩和花岗间长岩为主体的TTG岩系,经历了麻粒岩相高级变质作用的改造,已变质成以含紫苏辉石为特征的片麻岩类岩石。麻粒岩相峰期变质作用的时代为2390±19Ma。紫苏花岗岩属典型岩浆成因侵入岩,其侵位成岩时代为2390±24Ma,是区域麻粒岩相峰期变质作用期间长英质熔浆直接结晶的产物。钾质花岗岩类具多种不同的岩石类型,为一系列小规模的富钾质花岗岩侵入体,是与紫苏花岗岩同一构造岩浆活动事件的产物。麻粒岩相峰期变质作用、岩浆活动时代的一致性,表明了本区太古宙末-古元古代早期,由于大规模构造运动,麻粒岩相变质作用由峰期变质条件向相对低温低压条件演化、花岗岩-绿岩带基底岩石由地壳深部向地壳浅部抬升、并同时伴随紫苏花岗岩及钾质花岗岩等大规模岩浆侵入活动的区域地壳演化规律。 相似文献
3.
怀安蔓菁沟早前寒武纪高压麻粒岩混杂岩带地质特征、岩石学和同位素年代学 总被引:11,自引:19,他引:11
华北克拉通北缘中段怀安蔓菁沟高压麻粒岩混杂岩带产在太古宙怀安杂岩南缘与花岗岩带交界处,由高压基性麻粒岩、辉长质麻粒岩、英云闪长质麻粒岩和少量夕线石榴片麻岩相间排列的席状岩层构成,岩层间被高应变带或剪切带分隔。高压基性麻粒岩是石榴辉石麻粒岩。据石榴石斑晶内包裹的早期矿物(Cpx+Q)估算的早期高压变质作用条件:T=800℃,P>1.4GPa。环绕斑晶的后成合晶反应边矿物组合(P1+Opx+Hb+Cpx)的变质条件为:T=820℃,P为0.7~0.9GPa。全岩Sm-Nd等时线年龄2.65Ga,矿物Sm-Nd等时线年龄1.82Ga,锆石U-Pb一致线年龄1.83Ga。高压基性麻粒岩的原岩代表晚太古代陆壳的最下部,大约在2.7Ga从上地幔分异出来,可能经壳下垫托作用加在早期陆壳底部,随后经历高压变质作用。早元古代晚期,由于地壳规模的大型逆冲作用,使其上升,并经受褶皱形变、剪切推覆和退变质等作用的改造,形成高压麻粒岩混杂岩带。 相似文献
4.
晋冀蒙高级区两期高压麻粒岩的地质特征及成因 总被引:6,自引:1,他引:5
钟长汀 《前寒武纪研究进展》1999,22(2):53-58
晋冀蒙高级区存在两期高压麻粒岩,其分布、产状、时代、成因都不同。早期高压麻粒岩,沿宣化西葛峪、大东沟、怀安蔓菁沟南部、恒山白蟒石一带分布,呈透镜状产于钾长花岗岩中,形成时代约2400Ma,属岩浆包体。晚期高压麻粒岩,沿孔兹岩系和麻粒岩杂岩的接触带分布,呈透镜状、岩脉状产出,并和孔兹岩岩片、高温韧性剪切带、超基性岩一同构成具有“混杂岩”性质的构造-岩浆杂岩带,其时代为1800Ma左右。 相似文献
5.
对山东高压—超高压变质带的几点看法:程裕淇院士野外考察记 总被引:5,自引:0,他引:5
通过对山东高压-超高压变质带的考察,初步认为:榴辉岩的最后降升时代为蒸山期;含更玉石英岩+榴辉岩+(透辉石)大理岩组合说明表壳岩经历了高压-超高压变质作用;该带晋宁期长英质片麻岩-花岗岩广泛出露,在其北部麻粒岩和榴辉岩密切伴生。 相似文献
6.
大别山超高压变质带是华北与扬子板块俯冲碰撞作用的产物。迄今为止,报导的超高压变质岩除镁铁、超镁铁质岩石外,主要为火山-沉积岩,然而除上述岩石外,大别山南部出露大量花岗质片麻岩。作者在近期对大别山东南部变质花岗岩岩石学研究中发现:变质花岗岩中含有Gt+Ru+Phe±Acg+Aug±Di+Pl+Na-Amp+Or+Q组合,与钠长石共生的霓石或透辉石可能是早期矿物硬玉或富硬玉质绿辉石退变的,而岩石中石榴石分带特征,即内带以铁铝榴石(43.06%)和钙铝榴石(46.28%)为主,外带则以锰铝榴石(30.40%)和钙铝榴石(35.67%)为主,这些都表明它们是由高压向低压退化变质之产物。因此,变质花岗岩可能早期存在着这样的榴辉岩相峰期矿物组合Jd/omp+Q/CS+Phe+Ru+Gt+Or,这个组合由于后期的压力降低而退变为中低压的矿物组合。 相似文献
7.
藏南萨迦拉轨岗日淡色花岗岩特征及与变质核杂岩的关系 总被引:11,自引:1,他引:10
藏南拉轨岗日带展布着串珠状变质核杂岩,其内出露的淡色花岗岩体构成北喜马拉雅淡色花岗岩带.岩体既有在变质核杂岩内核中分布的,亦有在滑脱系分布的,岩体均表现出强力主动侵位的特征.淡色花岗岩可分为两期:早期黑云母淡色花岗岩和晚期白云母淡色花岗岩.岩石高硅富铝,含白云母±电气石±石榴石特征富铝矿物,为S型花岗岩.北喜马拉雅淡色花岗岩结晶年龄为17~10Ma,源岩为MCT上部基底副变质岩.当挤压体制与伸展体制转换时,降压作用导致了岩浆的生成,同时,由于压力骤减,年轻造山带更为塑性的下地壳物质与软层隆起导致上地壳伸展,从而形成变质核杂岩,岩浆对内核的上隆起到促进作用. 相似文献
8.
大陆碰撞造山带中花岗岩浆主要是因下部地壳缺乏流体熔融过程而形成的。对其源岩成分限制而进行的微量元素模拟不仅要考虑源岩和熔体中有关矿物相比例的变化,还要考虑熔融过程中源岩矿物相组合的变化,并选择合适的元素用于模拟。Rb、Sr、Ba和REE模拟结果显示,上溪群杂砂岩作为扬子隆起带中生代花岗岩类的源岩是不合适的:大别隆起带中的中生代花岗岩类也不可能完全由大别杂岩中的TTG质片麻岩熔融形成,更可能是变基性岩和TTG质片麻岩构成的复合源岩熔融的结果 相似文献
9.
东喜马拉雅构造结南迦巴瓦杂岩中存在典型的泥质、长英质和基性高压麻粒岩。但是,高压麻粒岩在南迦巴瓦杂岩中的分布范围、变质条件和变质时间是否存在空间上的变化并不明确。本文对南迦巴瓦杂岩西南部巴嘎地区的高压基性麻粒岩进行了岩石学和年代学研究。研究表明,巴嘎高压基性麻粒岩由石榴子石、单斜辉石、角闪石、斜长石、黑云母和石英组成,石榴子石变斑晶发育生长成分环带。识别出三期矿物组合:进变质矿物组合M1为石榴子石变斑晶核部及其矿物包裹体,包括石榴子石、石英、榍石和磷灰石;峰期矿物组合M2为变斑晶石榴子石边部和基质矿物,即石榴子石+单斜辉石+斜长石+角闪石+石英+金红石+熔体;退变质矿物组合M3呈冠状体或基质产出,其组合为角闪石+斜长石+单斜辉石+黑云母+石英+榍石。高压基性麻粒岩的峰期变质条件约为1. 5 GPa和915 ℃,具有顺时针P- T轨迹,退变质的早期和晚期分别为近等温降压和降温降压过程。高压基性麻粒岩在峰期条件下发生了明显的部分熔融,含~26%(体积)的熔体,其退变质和熔体结晶作用很可能发生在26~14 Ma。本文和研究区现有研究成果表明,东喜马拉雅构造结南迦巴瓦杂岩中的高压麻粒岩广泛分布,从东北部的加拉、直白和派乡延伸到西南部的巴嘎沟,形成了一条长度超过80 km的高压麻粒岩带。整个带中的高压麻粒岩具有类似的变质条件和持续时间,是印度大陆地壳平缓俯冲并经历了高温和高压变质与部分熔融的产物,构成了喜马拉雅造山带的加厚下地壳。大量高压麻粒岩强烈部分熔融产生的熔体可能为喜马拉雅淡色花岗岩提供了源区。 相似文献
10.
大别山超高压带中变质花岗岩特征:(1) 岩石组合较单一,以二长花岗岩( 原岩) 为主,缺乏中基性岩和正长岩类;(2) 具鳞片花岗变晶结构,片麻状构造,保留残存的岩浆岩组构;(3) 与榴辉岩及其它超高压变质岩石有明显侵入接触关系,并可见有其捕虏体;(4) 岩石化学表现为富硅、富碱、贫钙、贫镁等特征,一般地SiO2 > 76 % ,( Na2 O+ K2 O) > 8 % ,CaO< 0 .5 % ,MgO < 0 .4 % ;(5) 痕量元素表现为Zr 、Y、Nb 、REE 含量高,Sr 、Sc 、V、Ni 等低;(6) 变质矿物组合为斜长石+ 石英+ 钾长石+ 白云母+ 石榴石+ 绿帘石,属于低角闪岩相。(7) 锆石U - Pb 同位素年龄值为685 ±41 Ma 。大别山超高压变质带中变质花岗岩为A 型花岗岩,更接近A2 亚类。变质A 型花岗岩的确定,对进一步认识大别山的大地构造演化、榴辉岩等超高压变质带的形成、折返机制等提供了重要地质依据。 相似文献
11.
Single zircon ages from high-grade rocks of the Jianping Complex, Liaoning Province, NE China 总被引:13,自引:0,他引:13
The high-grade rocks of the Jianping Complex in Liaoning Provi nce, NE China, belong to the late Archaean to earliest Proterozoic granulite belt of the North China craton. Single zircon ages obtained by the Pb–Pb evaporation method and SHRIMP analyses document an evolutionary history that began with deposition of a cratonic supracrustal sequence some 2522–2551 Ma ago, followed by intrusion of granitoid rocks beginning at 2522 Ma and reaching a peak at about 2500 Ma. This was followed by high-grade metamorphism, transforming the existing rocks into granulites, charnockites and enderbites some 2485–2490 Ma ago. The intrusion of post-tectonic granites at 2472 Ma is associated with widespread metamorphic retrogression and ends the tectono–metamorphic evolution of this terrain. A similar evolutionary sequence has also been recorded in the granulite belt of Eastern Hebei Province. We speculate that the Jianping Complex was part of an active continental margin in the late Archaean that became involved in continental collision and crustal thickening shortly after its formation. There is a remarkable similarity between the 2500 Ma North China granulite belt and the equally old granulite belt of Southern India, suggesting that the two crustal domains could have been part of the same active plate margin in latest Archaean times. 相似文献
12.
冀西北高压麻粒岩带构造环境的再思考 总被引:5,自引:0,他引:5
在崇礼岛弧型绿岩带与怀安古陆块之间,从怀安大虎沟,经宣化大东沟至赤城沤麻坑发育一条大体呈东西走向并向南倾斜的板状高压麻粒岩带。其中轻稀土亏损的洋中脊型拉斑玄武岩(TH1) 的存在显示部分洋壳残片的可能卷入。变质条件(850 ~900 ℃,13 ~14GPa) 表明它属于俯冲杂岩。同时比怀安陆块(2 900 Ma) 显著年轻的模式年龄(2 700 ~2 600 Ma) 证明了它的增生性质。从综合地球化学、变质作用和年代学资料来看,它们不属于连续下地壳剖面的最下部,而更可能是新太古代侧向增生的弧后混杂岩带。 相似文献
13.
New U-Pb single-zircon geochronology undertaken on tonalitic gneisses, granite sheets, migmatites and metasediments from the Lewisian Gneiss Complex on the mainland and the northern part of the Outer Hebrides, NW Scotland, have been used to test the correlation of so-called Laxfordian events across the complex from the Outer Hebrides to the mainland, and the current model for the evolution of the complex as a whole. The study has revealed that the granite sheets originated in two quite different melting events. Those on the mainland at Loch Laxford are ca. 1,855 Ma old whereas those on Harris and Lewis, with which they are presently correlated, are ca. 1,675 Ma old. Grey gneisses associated with granites on the south side of Loch Laxford are confirmed to belong to the 'northern region'. A migmatitic grey gneiss on Harris has given a protolith age of ca. 3,125 Ma, the currently oldest recognised in the complex. Detrital zircons in the Leverburgh and Langavat belts range in age from 2,780 to 1,880 Ma and unequivocally demonstrate deposition in the Palaeoproterozoic. The granulite facies metamorphism in this block is dated from zircon overgrowths at ca. 1,880 Ma. The Laxford Shear Zone which separates the northern and central regions is interpreted to have evolved post-1,860 Ma, during amphibolite facies metamorphism accompanying deformation which took place at ca. 1,740 Ma in both regions. On Harris, the Langavat-Finsbay shear zone developed after 1,675 Ma when a ca. 1,880-Ma granulite facies Proterozoic arc was juxtaposed against amphibolite facies Archaean rocks to the north. Therefore, the shear zones which bound tectonic blocks in the Lewisian Complex evolved at different times and can be interpreted as terrane boundaries. The new data confirm that the Lewisian Complex was not constructed from one contiguous piece of Archaean crust reworked in the Proterozoic but was progressively assembled from several discrete terranes during the Proterozoic. Accordingly, the former regional divisions of the Lewisian Complex are here renamed as follows. On the mainland, the northern region is called the Rhiconich terrane, and the central region the Assynt terrane. On the Outer Hebrides, the Archaean gneisses of Lewis and the northern part of Harris comprise the Tarbert terrane, whereas the newly accreted Proterozoic blocks are called the Roineabhal terrane in Harris and the Niss terrane in the north on Lewis. Wider correlations show that the geology of the Outer Hebrides has more in common with East Greenland than mainland Scotland on the eastern side of the Minch Fault. 相似文献
14.
V. V. Sesha Sai 《Journal of the Geological Society of India》2013,81(2):167-182
The area adjoining the western part of Archaean Nellore schist belt and the eastern margin of the Proterozoic Cuddapah basin in south Peninsular India is marked by emplacement of a number of granite plutons of Proterozoic age, intermittently extending over a stretch of 350 km from Vinukonda in the north to Sri Kalahasti in the south. Vinukonda, Darsi, Podili and Anumalakonda plutons are intensely deformed particularly along the margins, while development of crude deformational fabric is noticed in Kanigiri, Rapur and Kayyuru-Vendodu plutons. Petrographically majority of these granites vary from alkali feldspar granite to granite with the exception of Rapur granite which varies from granite to granodiorite. Geochemically they exhibit calc-alkaline trend and in A/NK-A/CNK plot they are positioned at the juncture of peraluminous-metaluminous-peralkaline field. Characteristically, majority of these granites are fluorite bearing. Biotite mineral chemistry suggests high FeOT contents (31.68 to 34.69 %) and very low MgO contents (0.49 to 2.41 %). Geochemically, these are charecterised by high SiO2 (69 to 74.5 %), Na2O+K2O (8.19 to 10.11%), Zr (280–660ppm), Y (70–340 ppm), Rb content (180–370 ppm) and high REE contents (except Eu); and low CaO (0.01 to 1.99), MgO (0.01 to 0.92%) and Sr (10 ppm to 85 ppm) contents. Rare earth element studies reveal a general enrichment of LREE, pronounced negative Eu anomaly; flat and depleted HREE. Enriched LILE and HFSE contents; presence of fluorite and interstitial biotite indicate that these granites are crystallized from a fluorine saturated magma derived from enriched crustal source. The field setup, distinct mineralogy and chemical characteristics suggest that these granite plutons are emplaced along a major tectonic zone i.e. terrane boundary shear zone (TBSZ) in a late-orogenic to anorogenic tectonic setup, close to the vicinity of a collision boundary zone; western margin of NSB and eastern margin of Nallamalai Fold Belt (NFB). The Proterozoic granite magmatism reported in the present studies represents a significant event of Precambrian crustal growth at the juncture of two tectonically contrasting terranes i.e. the Archaean Nellore schist belt and the Proterozoic Cuddapah basin in eastern Dharwar craton. 相似文献
15.
五台山地区分布着复杂的变质杂岩。过去人们把这些变质岩作为地层分成群组段。龙泉关剪切构造岩的发现突破了这种传统观念。野外工作中发现所谓五台群主要包含了三个蛇绿混杂带;阜平群和恒山群的主要成分是灰片麻岩,它们构成两个太古代陆块的基底。五台地区的花岗岩类由代表弧环境的双花岗岩带的I型和S型花岗岩组成,它们与变质的钙碱性火山岩代表了古代的岩浆弧。滹沱群的豆村和东冶亚群以及过去划入阜平群和五台群的某些变沉积岩是阜平陆块被动大陆边缘的沉积。滹沱群的郭家寨亚群则是前陆盆地的磨拉石沉积。因此可以认为,这是一个由恒山仰冲陆块、北台-车厂弧和阜平俯冲陆块构成的碰撞造山带,碰撞时间大致是距今2050Ma。闭合的弧前大洋和弧后盆地形成了三条蛇绿混杂带。 相似文献
16.
A. B. Roy Alfred Kröner Sanjeev Rathore Vivek Laul Ritesh Purohit 《Journal of the Geological Society of India》2012,79(4):323-334
Several bodies of granulites comprising charnockite, charno-enderbite, pelitic and calc-silicate rocks occur within an assemblage of granite gneiss/granitoid, amphibolite and metasediments (henceforth described as banded gneisses) in the central part of the Aravalli Mountains, northwestern India. The combined rock assemblage was thought to constitute an Archaean basement (BGC-II) onto which the successive Proterozoic cover rocks were deposited. Recent field studies reveal the occurrence of several bodies of late-Palaeoproterozoic (1725 and 1621 Ma) granulites within the banded gneisses, which locally show evidence of migmatization at c. 1900 Ma coeval with the Aravalli Orogeny. We report single zircon ‘evaporation’ ages together with information from LA-ICP-MS U-Pb zircon datings to confirm an Archaean (2905 — ca. 2500 Ma) age for the banded gneisses hosting the granulites. The new geochronological data, therefore, suggest a polycyclic evolution for the BGC-II terrane for which the new term Sandmata Complex is proposed. The zircon ages suggest that the different rock formations in the Sandmata Complex are neither entirely Palaeoproterozoic in age, as claimed in some studies nor are they exclusively Archaean as was initially thought. Apart from distinct differences in the age of rocks, tectono-metamorphic breaks are observed in the field between the Archaean banded gneisses and the Palaeoproterozoic granulites. Collating the data on granulite ages with the known tectono-stratigraphic framework of the Aravalli Mountains, we conclude that the evolution and exhumation of granulites in the Sandmata Complex occurred during a tectono-magmatic/metamorphic event, which cannot be linked to known orogenic cycles that shaped this ancient mountain belt. We present some field and geochronologic evidence to elucidate the exhumation history and tectonic emplacement of the late Palaeoproterozoic, high P-T granulites into the Archaean banded gneisses. The granulite-facies metamorphism has been correlated with the thermal perturbation during the asymmetric opening of Delhi basins at around 1700 Ma. 相似文献
17.
Concordant granite sheets from the granulite facies Scourian Complex, N.W. Scotland exhibit the following features:
- a common planar fabric with their host pyroxene granulites;
- the presence of an exsolved ternary feldspar phase;
- a low-pressure, water-saturated minimum composition;
- K/Rb ratios (450–1,350) distinctly higher than most upper crustal granites but similar to the surrounding granulites;
- low absolute concentrations of the rare earth elements (REEs), light REE enrichment, and large positive Eu anomalies.
18.
锡田钨锡多金属矿田位于南岭成矿带中段,发育多期次岩浆活动与钨锡成矿. 为了厘清花岗岩与钨锡成矿的时空关系,采用野外调查、显微鉴定、锆石U-Pb同位素定年与岩石地球化学的方法对矿田内多期次花岗岩岩体(脉)的空间分布、岩石类型、成岩时代、地球化学组成等进行了研究. 结果表明,锡田矿田发生了三期岩浆事件,分别为加里东期(435~441 Ma)、印支期(220~230 Ma)、燕山期(141~160 Ma);三期花岗岩普遍富集大离子亲石元素Rb、K、U、Th等,亏损Ti、P、Sr、Ba等微量元素,具明显的负Eu异常,其中加里东期花岗岩与印支期花岗岩为S型花岗岩,而燕山期花岗岩为A型花岗岩;不同时期花岗岩中的成矿元素从加里东期→印支期→燕山期逐渐升高,特别是W、Sn元素在燕山期白云母与二云母花岗岩中最为富集,这与华南地区燕山期钨锡大爆发的时间是一致的;印支期岩体接触带发育少量矽卡岩型Fe-Cu-W多金属矿床,燕山期岩体接触带也发育矽卡岩型W-Sn多金属矿床,并在附近陡倾的张裂隙中发育多个中大型石英脉型W-Sn矿床,而加里东期岩体附近尚未发现钨锡矿化. 因此,锡田矿田的多期次花岗岩与钨锡多金属成矿是时空耦合的,且成矿以燕山期矽卡岩型与石英脉型钨锡矿为主. 相似文献
19.
黑龙江省五道岭地区花岗斑岩地球化学特征及地质意义 总被引:1,自引:0,他引:1
五道岭钼矿床是伊春—延寿成矿带上最南部的矽卡岩型矿床。本次工作通过调研矿床寄主岩石边缘的花岗斑岩发现,花岗斑岩与赋矿正长花岗岩不仅形成时代一致,还存在岩石地球化学的相似性:花岗斑岩的锆石U-Pb年代学显示其形成时代为(194.1±2.0)Ma,寄主岩石正长花岗岩形成时代为(193.9±1.3)Ma;花岗斑岩为I型向A型花岗岩过渡的岩石类型,更趋近于A型花岗岩,正长花岗岩属于典型的A型花岗岩,且两者均为高Si、富K-Na、富Al的高钾钙碱性-弱碱性、准铝-过铝质的岩石,具有富集大离子亲石元素Rb、K和轻稀土元素,亏损高场强元素Nb、Ta、P、Ti等特点,两者微量和稀土元素分布趋势一致,显示它们可能是同源岩浆的产物。花岗斑岩的初始Sr比值~(87)Sr/~(86)Sr为0.723 123,结合区域地质演化特征认为,五道岭花岗质岩体可能形成于古太平洋板块俯冲挤压后期的伸展环境,矽卡岩型钼矿床的成矿作用或许与花岗斑岩的侵入密切相关,暗示区域上存在这期花岗斑岩成矿的可能性。 相似文献
20.
E. G. Imeokparia 《Mineralium Deposita》1985,20(2):81-88
The Tongolo Anorogenic Complex consists of peraluminous biotite granites and peralkaline riebeckite granites in which mineralization is spatially associated with the peraluminous biotite granites. Metallization is dominated by Nb-Sn and Sn-W types. Geochemical analyses of fresh bedrock samples indicate that the Tongolo biotite granites are characterized by enhanced values of a suite of trace elements (Sn, Nb, W, Zn, Rb, Li, F, Th, Y, U) which readily identify them as “specialized” granites. These geochemical data are also examined by R-mode factor analysis with the primary objective of isolating the significant factors accounting for the sample composition as derived from mineralization, alteration and lithology. The resulting orthogonal varimax solution yields a three-factor model that accounts for 79.7% of the total variance. These granite series are marked by what is interpreted as the “lithophile factor” (heavily loaded by Li, Rb, F, Th, Ga, Y, U) dominated by magmatic processes and metallization factors (Nb, Zr, Ga, U, Zn, Li and Sn, W, Rb, F, Th) which are dominated by postmagmatic processes. The two dominant types of mineralization (Nb-Sn and Sn-W), although characterized by the same pattern of trace-element enrichments, can be discriminated on the basis of Rb/Zr and Sn-Li-F relationships. 相似文献