再论花岗岩按照Sr-Yb的分类:标志

2006年作者曾经按照Sr=400×10~(-6)和Yb=2×10~(-6)作为标志将花岗岩分为埃达克岩、喜马拉雅型花岗岩、浙闽型花岗岩和广西型花岗岩,在浙闽型中又分出南岭型(Sr100×10~(-6)和Yb2×10~(-6)),于是花岗岩被分为5类。Sr=400×10~(-6)和Yb=2×10~(-6)是根据阿留申群岛中的Adak岛的资料得出来的。本文统计了全球花岗岩6000多个数据(其中,埃达克型花岗岩为2810个,喜马拉雅型花岗岩636个,浙闽型花岗岩1183个,南岭型花岗岩1518个,广西型花岗岩142个,总共6289个),统计的结果,各类花岗岩的地球化学特征大致如下:(1)埃达克型花岗岩富Al_2O_3和Sr,贫Y和Yb,具较高和变化的铕异常,绝大多数样品的Sr300×10~(-6),Yb2.5×10~(-6)(当Sr=400×10~(-6)～600×10~(-6)时Yb值最大,Sr超过600×10~(-6),Yb降低至2×10~(-6)),Al_2O_3在14%～18%之间,Eu/Eu~*大多在0.6～1.2范围;(2)喜马拉雅型花岗岩贫Sr和Yb,具中等的Al_2O_3和变化的Eu/Eu~*,Sr300×10~(-6)和Yb2×10~(-6)(少数Sr300×10~(-6)),Al_2O_3为13%～17%,Eu/Eu~*为0.2～1.0;(3)浙闽型花岗岩贫Sr富Yb,Sr在40×10~(-6)～400×10~(-6)之间,Yb1.5×10~(-6),Al_2O_3和Eu/Eu~*的变化类似喜马拉雅型花岗岩,Al_2O_3为12%～17%,Eu/Eu~*为0.4～1.0;(4)南岭型花岗岩以很低的Sr、Al_2O_3和Eu/Eu~*以及很高的Yb而不同于上述各类花岗岩,通常Yb1.5×10~(-6),Sr100×10~(-6)(Yb变化大,绝大多数2×10~(-6);当Yb在2×10~(-6)～8×10~(-6)时,部分样品Sr可100×10~(-6),但很少200×10~(-6));Al_2O_314%,集中在11%～13%之间,Eu/Eu~*0.7,大多0.4;Yb越大,Sr越低,负铕异常越明显。文中讨论了花岗岩Sr-Yb分类的意义,指出本分类适用于产于大陆和海洋的绝大多数中酸性岩浆岩(可能不适用于一部分特别富铁和钾的花岗岩,如具有高Sr和Yb特征的广西型花岗岩)。不同类型的花岗岩主要反映了源区压力的不同,而源区成分、温度、部分熔融程度、水和挥发分的加入以及岩浆混合等的影响可能是次要的。文中指出,该分类的依据、其实质,是熔体与残留相平衡的理论。与浙闽型花岗岩平衡的残留相是斜长石,与喜马拉雅型花岗岩平衡的是斜长石+石榴石,与埃达克型花岗岩平衡的是石榴石,与南岭型花岗岩平衡的是富钙的斜长石。文中指出,加强实验岩石学研究,将年代学和地球化学研究密切结合起来是深化花岗岩研究的关键。     

三论花岗岩按照Sr-Yb的分类:应用

在"再论"中我们提出了花岗岩按照Sr-Yb分类的新标志(张旗等,2010a),本文进一步讨论该分类的应用。文中举了国内外许多实例(包括柴达木、北祁连、内蒙古、松潘-甘孜、大别、太行、华北古元古代和华南新元古代以及土耳其、俄罗斯、巴西、刚果、波西米亚、意大利等),着重讨论了花岗岩Sr和Yb含量与其形成压力和深度的关系,指出本分类最重要的地球动力学意义在于与其形成的深度有关,并在一定条件下与其产出地区的地壳厚度有关。例如应用本方法分析华北克拉通古元古代花岗岩,很难得出该带在古元古代发生过碰撞的结论,华北克拉通是否分为东西两块也需要重新认识。又如对华南新元古代花岗岩的分析表明,华南地块内部在新元古代时地壳较薄,但是,与Rodinia大陆的裂解似乎无关。文中还对花岗岩与成矿的关系进行了讨论,提出成矿与压力有关的概念。如金铜与地壳厚度大的埃达克型和喜马拉雅型花岗岩有关,钨锡与地壳厚度薄的南岭型花岗岩有关,而不论矿床是什么类型的,只要它们与花岗岩有关,必定受矿液源区深度的控制,要么是在加厚地壳的地球动力学背景下,要么是在地壳减薄的地球动力学背景下。花岗岩无比复杂,我们用Sr和Yb两个元素对花岗岩重新进行了分类,只是一个探索性的尝试,问题肯定不少,需要广泛的实践的检验,需要深入的实验研究的检验,需要理论的探讨,需要经过一系列否定-肯定-否定的过程,才能逐渐臻于完善。     

内蒙古二连浩特北部阿仁绍布地区晚石炭世花岗岩Sr-Yb分类及其成因

对分布在内蒙古二连浩特北部阿仁绍布地区的晚石炭世花岗岩类,依据Sr、Yb含量,划分为低Sr高Yb型、极低Sr高Yb型和低Sr低Yb型花岗岩3种类型。低Sr高Yb型花岗岩类相对低Si、富Al,Na2O>K2O,稀土元素分馏中等,有或无负Eu异常,Sr含量低,平均为183×10-6,Ba含量较高,平均585×10-6,Y含量高,平均30.06×10-6,Rb/Sr比值较低,平均0.97;极低Sr高Yb型花岗岩富Si、REE,低Al、Sr、Ba,高的Rb/Sr比值(平均为7.47),具明显的负Eu异常等;低Sr低Yb型花岗岩富Si,贫Al、Ca、Mg,重稀土元素(Y、Yb)含量低,Y含量在(7.26～10.6)×10-6之间,平均9.76×10-6,Yb含量在(1.04～1.89)×10-6之间,平均1.44×10-6,δEu=0.64～0.94,具弱负Eu异常,微量元素Ba含量高,Rb/Sr比值低。3种类型的花岗岩类过铝指数(A/CNK)多小于1.0,说明它们均源自变质火成岩的部分熔融。由于源区的深度不同(pT条件不同)和残留的主要矿物相不同,它们的岩石地球化学特征存在差异。极低Sr高Yb型花岗岩形成深度最浅(中上地壳),熔融残留相以斜长石为主;低Sr高Yb型花岗岩类形成于中下地壳,熔融残留相为斜长石和辉石;低Sr低Yb型花岗岩形成深度最深,推测可能形成于加厚下地壳(>40km)底部,熔融残留相为石榴子石、斜长石和角闪石。     

内蒙古二连浩特北部阿仁绍布地区晚石炭世花岗岩Sr-Yb分类及其成因

对分布在内蒙古二连浩特北部阿仁绍布地区的晚石炭世花岗岩类,依据Sr、Yb含量,划分为低Sr高Yb型、极低Sr高Yb型和低Sr低Yb型花岗岩3种类型。低Sr高Yb型花岗岩类相对低Si、富Al,Na2O>K2O,稀土元素分馏中等,有或无负Eu异常,Sr含量低,平均为183×10-6,Ba含量较高,平均585×10-6,Y 含量高,平均30.06×10-6,Rb/Sr比值较低,平均0.97;极低Sr高Yb型花岗岩富Si、REE,低Al、Sr、Ba,高的Rb/Sr比值(平均为7.47),具明显的负Eu异常等;低Sr低Yb型花岗岩富Si,贫Al、Ca、Mg,重稀土元素(Y、Yb)含量低,Y含量在(7.26~10.6)×10-6之间,平均9.76×10-6,Yb含量在(1.04~1.89)×10-6之间,平均1.44×10-6,δEu=0.64~0.94,具弱负Eu异常,微量元素Ba含量高,Rb/Sr比值低。3种类型的花岗岩类过铝指数(A/CNK)多小于1.0,说明它们均源自变质火成岩的部分熔融。由于源区的深度不同(pT条件不同)和残留的主要矿物相不同,它们的岩石地球化学特征存在差异。极低Sr高Yb型花岗岩形成深度最浅(中上地壳),熔融残留相以斜长石为主;低Sr高Yb型花岗岩类形成于中下地壳,熔融残留相为斜长石和辉石;低Sr低Yb型花岗岩形成深度最深,推测可能形成于加厚下地壳(>40km)底部,熔融残留相为石榴子石、斜长石和角闪石。     

内蒙古二连浩特北部阿仁绍布地区晚石炭世花岗岩Sr-Yb分类及其成因

对分布在内蒙古二连浩特北部阿仁绍布地区的晚石炭世花岗岩类,依据Sr、Yb含量,划分为低Sr高Yb型、极低Sr高Yb型和低Sr低Yb型花岗岩3种类型。低Sr高Yb型花岗岩类相对低Si、富Al,Na2O〉K2O,稀土元素分馏中等,有或无负Eu异常,Sr含量低,平均为183×10-6,Ba含量较高,平均585×10-6,Y含量高,平均30.06×10-6,Rb/Sr比值较低,平均0.97;极低Sr高Yb型花岗岩富Si、REE,低Al、Sr、Ba,高的Rb/Sr比值（平均为7.47）,具明显的负Eu异常等;低Sr低Yb型花岗岩富Si,贫Al、Ca、Mg,重稀土元素（Y、Yb）含量低,Y含量在（7.26～10.6）×10-6之间,平均9.76×10-6,Yb含量在（1.04～1.89）×10-6之间,平均1.44×10-6,δEu=0.64～0.94,具弱负Eu异常,微量元素Ba含量高,Rb/Sr比值低。3种类型的花岗岩类过铝指数（A/CNK）多小于1.0,说明它们均源自变质火成岩的部分熔融。由于源区的深度不同（pT条件不同）和残留的主要矿物相不同,它们的岩石地球化学特征存在差异。极低Sr高Yb型花岗岩形成深度最浅（中上地壳）,熔融残留相以斜长石为主;低Sr高Yb型花岗岩类形成于中下地壳,熔融残留相为斜长石和辉石;低Sr低Yb型花岗岩形成深度最深,推测可能形成于加厚下地壳（〉40km）底部,熔融残留相为石榴子石、斜长石和角闪石。     

花岗岩按照压力的分类

研究表明,中酸性火成岩大致按照Sr=400μg/g和Yb=2μg/g的标志可以划分为4种类型,即高Sr低Yb(Sr＞400×10-6,Yb＜2×10-6)、低Sr低Yb(Sr＜400×10-6,Yb＜2×10-6)、低Sr高Yb(Sr＜400×10-6,Yb＞2×10-6)和高Sr高Yb(Sr＞400×10-6,Yb＞2×10-6)型.其中,从低Sr高Yb型中还可以分出非常低Sr高Yb(Sr＜100×10-6,Yb＞2×10-6)的一类.着重探讨了这5类花岗岩形成的源区深度问题,指出按照残留相组成和花岗岩Sr、Yb含量,可以将花岗岩形成的压力分为3或4个级别:①高压下与石榴子石平衡的花岗岩具有高Sr低Yb的特征;②中等压力下,残留相为麻粒岩相(斜长石 石榴子石 角闪石 辉石),花岗岩具低Sr低Yb或高Sr高Yb的特点(取决于原岩成分);③低压下,残留相有斜长石无石榴子石的花岗岩为低Sr高Yb类型的;④与蛇绿岩有关的在洋壳剖面浅部由辉长岩部分熔融形成的M型花岗岩可能是非常低压(高温)条件下形成的.     

闽赣交界桃溪穹隆与外围印支期花岗岩岩石地球化学特征对比及地质意义

以桃溪穹隆与外围印支期花岗岩为研究对象,认为桃溪穹隆花岗岩更具壳源特征,表现为与壳源物质有关的矿物较多,岩石呈酸性和碱性程度更高,桃溪穹隆花岗岩高场强元素的亏损程度和亲石元素富集程度都大于穹隆外围,桃溪穹隆花岗岩δEu的亏损程度远大于穹隆外围.Sr-Yb元素特征还显示,印支时期地壳部分重熔形成花岗岩时,桃溪穹隆应处于地...     

变质核杂岩中高Sr低Y型花岗岩的发现及其地质意义

在星子变质核杂岩和武功山变质核杂岩中发现了高Sr低Y型花岗岩。这是变质核杂岩构造中高Sr低Y型花岗岩的首次报道。地球化学研究结果表明,它们具有与adakite相似的地球化学特性。在时空分布上,属于中国东部adakite。它们是由玄武岩岩浆底侵到加厚的陆壳底部导致下地壳麻粒岩部分熔融形成的。结合花岗岩的地球化学特片及现有的资料探讨高Sr低Y型花岗岩的形成与变质核杂岩构造之间的成因关系。     

新疆巴里坤地区志留纪花岗岩的确定及其地质意义

准噶尔盆地东部巴里坤地区怪石山二长花岗岩体和县煤矿北花岗闪长岩体分别获得440.6±3.7 Ma和412.8±3.3 Ma的 LA-ICP-MS锆石U-Pb形成年龄,指示该区早志留世—早泥盆世一期重要的花岗岩浆活动。两岩体为准铝—弱过铝钙碱性及高钾钙碱性岩系,微量元素具有富集LILE、贫HFSE,亏损Nb、Ta、Ti、P以及Pb正异常的岛弧岩浆成因特征。其中,怪石山岩体高Si、富K,高Rb/Sr和Ga/Al比值、低K/Rb比值,强Eu负异常,代表其为岛弧演化较为成熟阶段岩浆演化的产物,县煤矿北二长花岗岩富Na、高Sr和Sr/Y比值,低Y和Yb,则指示其为岛弧演化晚期,洋盆俯冲消减闭合过程、岛弧区地壳增厚环境下部陆壳物质熔融的结果。此外,两个岩体正的锆石εHf(t)(+7.64～+13.86)和老于其形成年龄的Hf二阶段模式年龄(TDM2=1123～561 Ma)证明,它们主要源自新元古代晚期到早古生代早期的新生岛弧陆壳物质。     

Magnetic fabric and emplacement of the post-collisional Pomovaara Granite Complex in northern Fennoscandia

The Proterozoic Pomovaara Granite Complex in northern Finland comprises three separate highly magnetic granite stocks. They are discordant, apparently unfoliated and according to isotope data, a significant Archaean component characterizes the source of these granites. The three stocks are aligned in an array parallel to major trans-crustal faults as interpreted from both aeromagnetic and gravity data. Their younger age of 1.8 Ga, compared to the main tectonic events at 1.9 Ga in northern Fennoscandia, indicates their post-collisional nature with respect to these events. The anisotropy of magnetic susceptibility (AMS) was studied together with magnetic, gravity and geological data in order to assess the emplacement mechanisms of the Pomovaara Granite Complex, and the possible tectonic control of fault systems on the ascent and emplacement of granitic magma. The orientation of magnetic fabrics within the granite stocks indicates that the direction of the original magma upwelling was from the SW, parallel to the major fault zones that controlled, at the crustal scale, the ascent of granite magmas. The predominant NW–SE orientations of the minimum magnetic axes of the magnetic ellipsoid and the elongate shapes of the stocks indicate compression normal to the deep fault trend during the crystallization of the granite magma.     

Geochemistry of late paleoproterozoic Anjana and Amet granites of the Aravalli craton with affinities to sanukitoid series granitoids: Implications for petrogenetic and geodynamic processes

The Mangalwar Complex of the Aravalli craton is marked by the presence of late Paleoproterozoic granites referred to as Anjana Granite and Amet Granite. These granites occur as 1.64 Ga old plutons intruding greenstone sequences and migmatitic gneisses of Mangalwar Complex which comprises parts of BGC of the Aravalli craton. In the present contribution major, trace and REE data of these granites along with associated microgranular mafic enclaves (MMEs) are presented and discussed. Geochemically these granites are quartz monzonite, metaluminous, sub-alkaline and high-K calc-alkaline rocks. The most important characteristics of Anjana and Amet granites are low SiO₂, high MgO, Mg#, K₂O, Ba, and low Na₂O/K₂O ratios. In addition, the REEs show moderate to high fractionation, with (La/Yb) ratios up to 22 and 23 of the Anjana and Amet granites respectively, with no or positive europium anomalies. In the primitive mantle-normalized trace element diagrams both granites show depletion in high-field strength elements (HFSE) such as Nb, Ta, P, Ti and enrichment in LILEs. Most of these features are comparable to those of sanukitoid series rocks. Geochemically both granites are distinguished as high-Ti sanukitoids. Geochemical characteristics of MMEs suggest that they are similar to Anjana and Amet granites and in turn to sanukitoids with lower SiO₂ content. They display LREE enriched patterns with low values (avg. 13) of (La/Yb)_N, negative Eu anomalies and high HREE contents (58 ppm). It is suggested that the parental magma of Anjana and Amet granitic plutons originated through a four stage process (1) Generation of magmatic melts produced by partial melting of terrigeneous sediments of subducting slab in an arc setting; (2) interaction of those melts with the overlying mantle wedge, and total consumption of slab-derived melts during the reaction resulting in production of a metasomatized mantle; (3) tectonothermal event, possibly related to the slab break-off, causing asthenospheric mantle upwelling. This may have induced the melting of the metasomatized mantle and the generation of sanukitoid magmas. The parental magmas of Anjana and Amet granites and their mafic enclaves were generated at lower and higher lithospheric levels respectively (4) Granitic magma ascended due to viscosity and gravity instabilities and interacted with enclave magma at higher mantle level. Both magmas ascended towards upper crust and evolved through fractional crystallisation. Existing data suggest that in the Mangalwar Complex, the formation of sanukitoid magma started even during Mesoarchaean times and continued till late Paleoproterozoic. Formation of sanukitoid magma during this time indicates that in northern Indian shield the multi-stage subduction- accretionary orogenic processes continued for a protracted geological period and played a major role in the origin and evolution of early continental crust.     

左权-赞皇变质杂岩的地球化学特征及其构造意义

左权变质杂岩位于华北克拉通中部造山带的中南段,赞皇变质杂岩西南。两杂岩区出露的早元古代——晚太古代变质岩石类型主要有:长英质片麻岩、黑云斜长片麻岩、斜长角闪岩、石榴角闪岩、云母片岩和长石石英岩等。通过详细地野外地质调查、岩相学以及地球化学研究发现,左权变质杂岩与赞皇变质杂岩有类似的地球化学性质,其中,长英质片麻岩、黑云斜长片麻岩和角闪岩的原岩均有正、有副,按原岩性质可分为变质沉积岩、变质花岗质岩石和变质基性岩三类。变质沉积岩的原岩为粘土岩或杂砂岩,物源以上地壳的长英质成分为主,REE配分型式与PAAS以及上地壳平均成分类似,原岩在形成过程中经历了中——低等程度的风化作用,沉积背景为有演化岛弧发育的活动大陆边缘;变质花岗质岩石的原岩为中酸性侵入岩,形成于大陆边缘弧环境,与变质沉积岩呈侵入接触关系;变质基性岩的原岩是拉斑——钙碱玄武质岩石,其稀土总量较低、轻稀土轻微富集,地壳混染作用明显,总体形成环境类似于现代大陆边缘的岛弧构造环境。基于以上地球化学特征推测左权——赞皇变质杂岩形成于典型碰撞造山环境,卷入了华北克拉通东部陆块和西部陆块之间的俯冲——碰撞过程。     

Geochemistry of peridotite and granite xenoliths during the early stage of weathering in the Nyos volcanic region (NW Cameroon): Implications for PGE exploration

Peridotite and granite xenoliths, in the early stage of weathering, occur in the Nyos volcanic region (NW Cameroon). Geochemical data shows that peridotites are marked by high concentrations of MgO (42.30 wt.%, with SiO₂/MgO ∼ 1), chromium (2100 ppm), nickel (2100 ppm) and cobalt (104 ppm), as well as by low lanthanide contents (ΣREE: 7.41 ppm). Granites display SiO₂ contents (70–73 wt.%), and are mostly peraluminous (1.40 > A/CNK < 1.6). They are also characterized by low contents in chromium (<24 ppm), nickel (ranging from 6 to 15 ppm) and cobalt (ranging from 3 to 6 ppm). Granites possess high lanthanide contents (ΣREE varying between 248.00 and 463.00 ppm), particularly in light lanthanides (LREE/HREE ratios ranging from 21 to 32). The chondrite-normalized patterns of the studied xenoliths are characterized by: (i) LREE enrichments in both rock types; (ii) negative Eu anomalies ([Eu/Eu*] ranging from 0.45 to 0.64) and weak positive Ce anomalies ([Ce/Ce*] ranging from 1.06 to 1.46) in granites. The weathering process provokes a remobilization of several trace elements notably light lanthanides.The geochemical survey of Platinum-Group Elements (PGE) done in these rocks in the early stage of weathering shows that PGE contents are less than 7 ppb in the peridotites. The highly concentrated elements are ruthenium (6.26 ppb) and platinum (5.53 ppb). The total PGE content is 14.57 ppb. These concentrations normalized with respect to chondrites display a flat spectrum from iridium to platinum. PGE contents in the granites are below detection limit except for two samples (LNY01 and LNY02) whose platinum content is close to 0.23 ppb.     

青海省布青山早古生代末期埃达克岩的发现及其构造意义

在青藏高原北部阿尼玛卿蛇绿岩带布青山段首次发现了埃达克岩,它们多呈不规则岩脉状侵入于布青山地区北部早古生代蛇绿混杂岩中.其岩性为花岗-英云闪长岩,主矿物有斜长石、石英、黑云母、角闪石、少量钾长石和辉石;副矿物有榍石、磷灰石、锆石和磁铁矿等.属钙碱系列,具典型（Ⅰ类、O型、HSA）埃达克岩的地球化学特征,表现为：高SiO：（63.65%～71.59%）,高Al2O3（14.81%～16.11%）,高Na2O（4.68%～5.33%）和Na2O/K2O（1.48～3.08,平均2.39）,高Sr（444.08×10^-6～560.41×10^-6）和Sr/Y（50.8～105.3）,HREE强烈亏损,低Yb（0.38×10^-6～0.74×10^-6）,高La/Yb（44.93～90.97）,弱负Eu异常（δEu=0.74～0.90）,富集大离子亲石元素（LILE）,亏损高场强元素（HFSE）,Ba、Pb正异常而Nb、P负异常.获得布青山埃达克岩的锆石TIMS U-Pb年龄为402±24Ma.布青山埃达克岩熔体来自俯冲的昆祁秦洋壳（含海洋沉积物）在石榴石角闪岩相条件下部分熔融,主要残留相为石榴石（±角闪石）.布青山埃达克岩的发现指示早古生代末期洋壳（昆祁秦多岛洋的一部分）俯冲作用的存在,俯冲方向朝北（现在方位）,此前,俯冲带发生长时间的向洋迁移,早古生代末期俯冲带已后退到阿尼玛卿蛇绿混杂岩带以南;暗示典型埃达克岩也可以形成于洋壳俯冲晚期;提示阿尼玛卿蛇绿岩带可能有与典型埃达克岩有关的Au、Ag、Cu、Mo等热液和斑岩矿床.     

内蒙古乌拉山-大青山地区变泥质岩的地球化学特征及构造意义

乌拉山-大青山地区位于华北克拉通西北缘孔兹岩带的中段,该地区出露大面积的古元古代高级变质表壳岩系岩石,例如夕线(堇青)石榴二长片麻岩、石榴黑云二长片麻岩、黑云长英质片麻岩、石榴石英岩、大理岩、磁铁石英岩和钙硅酸盐岩等。其中该地区典型的变泥质岩石(夕线(堇青)石榴二长片麻岩和石榴黑云二长片麻岩)多以似层状产出,夕线(堇青)石榴二长片麻岩含有大量的石榴石、夕线石和/或堇青石,并保留典型的堇青石反应边结构。岩石地球化学研究结果表明上述变泥质岩石样品明显富Al2O_3,属于过铝质岩石,其平均化学成分与上地壳平均值较为接近。样品的稀土配分型式具有中等程度的轻重稀土元素分异,轻稀土明显富集和弱铕负异常的特征。微量元素蛛网图显示变泥质岩石样品富集大离子亲石元素如Rb和Ba,而高场强元素如Zr、Hf含量相对较低,且Nb、Ta、P和Ti呈明显亏损的特征。多种原岩判别图解显示其原岩为一套富铝粘土岩及杂砂岩,且成熟度较低,为近源沉积。多数样品的CIA值低于太古宙后澳大利亚平均页岩和北美页岩的CIA值,反映其源岩经历了中等程度的风化作用。物源以上地壳的长英质成分为主,可能有古老沉积物的加入。多种构造判别图解表明研究区样品形成于有演化岛弧发育的活动大陆边缘环境。结合前人对孔兹岩带出露的变泥质岩石的变质作用研究普遍得到近等温减压型顺时针P-T演化轨迹以及锆石同位素年代学研究结果,综合表明乌拉山-大青山变泥质岩石形成于有演化岛弧发育的活动大陆边缘环境,中元古代物质(2.1~2.0Ga)为其提供主要的沉积物源,随后卷入~1950Ma华北克拉通西部古老陆块之间的碰撞造山作用,经历了大规模麻粒岩相变质作用,并于1920~1850Ma碰撞后折返至近地表。     

Structure,petrology and geochemistry of the Abu Dom alkaline ring-complex,Bayuda Desert,Sudan

The Abu Dom complex is one of a cluster of Younger Granite ring-complexes piercing the Proterozoic gneisses of the Bayuda Desert of Sudan. Intrusive rocks predominate and range from early metaluminous syenites to later peralkaline syenites and granites. They are disposed as ring-dykes, nested intrusions, and cone-sheet swarms. Field evidence and geochemical variation indicate that the peralkaline rocks evolved from a metaluminous syenitic parent magma as a result of high-level fractionation. The suite carries a clear within-plate signature exemplified by marked enrichments in HFS elements such as Zr and Nb.