青藏高原北羌塘新生代火山岩中的麻粒岩捕虏体

北羌塘枕头崖地区新生代火山岩主要岩石类型为安山岩和英安岩类。其中,安山岩在一定程度上显示了埃达克质火山岩的特征,如高Sr(>1000×10-6)、Sr/Y>50以及低Yb(<2×10-6),表明其应源于榴辉岩相的青藏高原加厚陆壳中下部(>45km深度)。而英安岩类富集LILE,如Rb、Ba、Th、U和K等,亏损HFSE,如Ti、Nb、Ta和Sr等,尤其是Sr显著亏损,表明其应源于斜长石稳定的麻粒岩相源区。该区新生代安山岩和英安岩中麻粒岩捕虏体可分为两种类型,即二辉石麻粒岩和单斜辉石麻粒岩。二辉石麻粒岩平衡温度为783~818℃,单斜辉石麻粒岩形成压力在0·845~0·858GPa之间,来源深度约为27·9~28·3km,表明它们是来自青藏高原加厚陆壳中部的岩石样品,代表了本区英安岩类火山岩的源区物质组成。     

华北克拉通北部古-中元古代富碱侵入岩的Nd、Sr、Pb同位素地球化学：岩石圈地幔富集的证据

华北克拉通北部古-中元古代富碱侵入岩主要分布在燕辽三叉裂堑系和辽吉拗拉谷中及附近,为一套高碱高钾的基性-中性岩,以正长岩类为主。本文通过开展系统的 Nd、Sr、Pb 同位素研究,发现所有岩体岩石均以高负ε_(Nd)(t)为特征,ε_(Nd)(t)=-3.4～-7.5,平均值为～4.8,这与研究区古-中元古代基性-超基性岩石的 Nd 同位素特征(ε_(Nd)(t)=-4～-8) 一致,与燕辽裂堑系发育的偏碱性火山岩 Nd 同位素特征(ε_(Nd)(t)=-4.3～-8.9)也比较相似,表明它们的物质来源相似,都与富集地幔有关。Sr 同位素初始比值(~(87)St/~(86)Sr)_i比较低,主要变化在0.7028～0.7053之间,平均值为0.7041。钾长石铅同位素组成普遍较低,~(206)Pb/~(204)Pb、~(207)pb/~(204)Pb、~(208)Pb/~(204)Pb 比值变化范围(梁屯-矿洞沟岩体除外)分别为14.500～15.70l、14.887～15.150和34.178～36.537,平均值分别为14.968、14.984和35.057。在ε_(Nd)(t)-ε_(Sr)(t)图解上,所有岩体的投影点均在地幔演化趋势线附近,比较接近 EMI 型富集地幔端员,暗示它们的物质来源与 EMI 型富集地幔有关;钾长石 Pb 同位素模式图也说明这些岩体物质来源与地幔和下地壳有关。通过两端员混合模拟,揭示了岩浆演化过程中存在少量的下地壳物质混染,平均约14%左右。从2.5Ga 左右开始华北克拉通岩石圈地幔的亏损程度逐渐变小,在2.2Ga 左右局部呈现富集性特征,1.85Ga时整个岩石圈地幔已经完全转变为富集性,之后富集程度越来越高。推测早期俯冲携带的壳源物质以及后期地幔流体的交代作用可能是岩石圈地幔逐渐转变为富集性的原因。     

青藏高原新生代埃达克质岩的厘定及其意义

常量、微量及Sr-Nd-Pb同位素研究表明,青藏高原藏北石水河—浩波湖—多格错仁北部分布的一套新近纪(9.4～26.9 Ma)安山质-英安质-流纹质火山岩具有埃达克岩的地球化学特征。岩石ω(SiO_2)>58％,ω(Sr)>350×10~(-6),低Y和Yb,高La/Yb比,无铕异常。岩石N(~(87)Sr)/N(~(86)Sr)=0.706 365～0.708 156,N(~(208)Pb)/N(~(204)Pb)=38.955～39.052,N(~(207)Pb)/N(~(204)Pb)=15.651～15.672,N(~(206)Pb)/N(~(204)Pb)=18.679～18.839,N(~(143)Nd)/N(~(144)Nd)=0.512 411～0.512 535,ε(Nd)=—2.01～—4.43,充分表明它们为一套典型的壳源中酸性火山岩系,源自高原加厚陆壳下部的一个榴辉岩质源区的部分熔融。     

青海省共和盆地周缘晚古生代镁铁质火山岩Sr-Nd-Pb同位素地球化学及其地质意义

青海省共和盆地周缘晚古生代镁铁质火山岩分属阿尼玛卿蛇绿混杂带,宗务隆构造带和苦海-赛什塘带。阿尼玛卿带正常洋中脊玄武岩(N-MORB)样品具有较高的~(87)Sr/~(86)Sr(t)比值(0.7066～0.7084)、高的ε_(Nd)(t)(12.2～12.8)和较低的~(206)Pb/~(204)Pb初始值(17.72～17.79)。这些同位素特征类似于秦岭勉略蛇绿岩带的N-MORB以及印度洋低~(206)Pb/~(204)Pb高~(143)Nd/~(144)Nd N-MORB。该带中的洋岛玄武岩(OIB)的~(87)Sr/~(86)Sr比值为0.7036～0.7044,ε_(Nd)(t)=4.4～4.8,~(206)Pb/~(204)Pb=17.45～17.62。其Sr和Nd同位素比值可与印度洋代表热点构造的洋岛玄武岩对比,但~(206)Pb/~(204)Pb低于印度洋的热点构造玄武岩,因此,具有类似印度洋低~(143)Nd/~(144)Nd比值MORB同位素特征。宗务隆构造带的N-MORB的Sr同位素比值在0.7041～0.7058,ε_(Nd)(t)=6.1～8.4,~(206)Pb/~(204)Pb=17.51～17.90,划归高~(143)Nd/~(144)Nd比值的N-MORB。苦海大陆裂谷玄武岩显示了高的~(87)Sr/~(86)Sr同位素比值(0.7115和0.7104)和低的ε_(Nd)(t)值(-1.7和-2.5),其~(206)Pb/~(204)Pb(17.64和17.46)与上述大洋玄武质岩石无显著区别。上述各岩类的同位素特征反映了它们生成的构造环境和陆壳组分混染的程度。阿尼玛卿带的N-MORB代表了典型的来自亏损地幔源区的洋中脊产物。与勉略带同类岩石可能来自同一源区。OIB可能属于热点构造成因的洋岛产物并与MORB一起构成了阿尼玛卿洋洋壳。宗务隆带MORB同样代表了主要源自相对亏损地幔的洋脊产物并指示宗务隆带曾开裂成洋。苦海大陆裂谷玄武岩极高的Sr和低的Nd同位素比值是陆壳物质组分的强烈印记,这与该类火山岩发育在前寒武纪基底之上不无关系。结合本区大洋玄武岩普遍低的Nb/U和Ce/Pb比值,推测它们可能源自EMII与DMM物质的交代混合。按照习惯的想法,明显的Dupal异常(△~(208)Pb/~(204)Pb值=46～103和△~(207)Pb/~(204)Pb值=4～18;大多样品~(87)Sr/~(86)Sr>0.704)指示这些岩石在空间上代表了来自南半球印度洋位置的古洋壳残余。但是,北半球愈来愈多的Dupal异常的发现有可能指示它们是类似现今东南亚多洋岛构造历经"汇聚式(focused)俯冲"的产物。此外,宗务隆带MORB的Dupal异常指示本区古特提斯域的北界较先前所定还要北推200km。     

吉林东南部晚中生代中酸性火山作用成因的地球化学制约

详细的主、微量元素和Sr-Nd-Pb同位素研究结果显示,延吉地区晚中生代(早白垩世)中酸性火山岩具有岛弧型微量元素特征(富集轻稀土(LREE)、大离子亲石元素(LILE)和亏损高场强元素(HFSE)),和中等放射成因Sr、Pb及类似于硅质地球的Nd同位素组成(~(87)Sr/~(86)Sr(i)=0.70437～0.70525;~(206)Pb/~(204)Pb(i)=18.19～18.37,~(207)Pb/~(204)Pb(i)=15.54～15.57,~(208)Pb/~(204)Pb(i)=38.13～38.22;ε_(Nd)(t)=-2.75～+1.61)。其Sr-Nd-Pb同位素组成特征类似于区域同期基性火山岩和大兴安岭地区同时代火山岩。这些广泛分布于吉林南部的晚中生代中酸性火山岩是岩石圈地幔来源岩浆经分离结晶或地壳物质混染/AFC过程的产物。吉林省东南部晚中生代不同区域火山岩的Sr-Nd-Pb同位素对比结果显示,辽源-延吉与通化地区分属不同构造单元,其中辽源-延吉一带则为中亚造山带的东段,而通化地区为华北克拉通的一部分,夹皮沟-松江断裂可能是华北克拉通东北缘的边界。     

庐枞早白垩世火山岩的地球化学特征及其源区意义

从中生代到新生代,华北东部岩石圈地幔发生了减薄以及地球化学性质置换, 而扬子地块东部中生代岩石圈地幔也表现出类似的过程,对中生代火山岩的地球化学研究有助于了解这一变化过程以及发生置换时的时空关系。庐枞火山岩出露于扬子地块东部,为一套包括粗玄岩–玄武粗安岩–粗面岩的富碱橄榄安粗岩系。研究了双庙组基性火山岩,这些岩石富集Rb,K,Sr,Th和轻稀土元素,亏损高场强元素。(87Sr/86Sr)i = 0.7060~0.7063,εNd(t )=-3.9~-6.2,(206Pb/204Pb)i=17.788~18.125,(207Pb/204Pb)i= 15.511~15.546,(208Pb/204Pb)i =37.735~38.184。在喷出地表过程中,火山岩没有受到明显的地壳物质混染,因此元素和同位素组成反映了地幔源区的地球化学特征。 其地幔源区具有同位素富集特征,表明火山岩源区曾受到地壳物质的影响,是富集地幔部分熔融的产物,并经历明显的结晶分异作用。庐枞火山岩的岩浆成分和源区特征反映该地区在晚中生代岩石圈地幔的伸展和软流圈地幔上涌的演化过程。     

西藏措勤-赛利普地区新生代火山岩同位素组成及源区性质探讨

对赛利普地区新生代火山岩Sr,Nd,Pb同位素资料分析,揭示了赛利普新生代火山岩同位素组成在时代和岩石组合上存在的规律性变化.总体上,随时代变新,Sr,Pb同位素呈递增,Nd同位素呈递减趋势,火山岩中地壳物质贡献明显增加.本区新生代火山岩与青藏高原北部(班公湖-怒江缝合带以北)相比,Sr,Nd和Pb同位素组成存在一定差异,尤其是新近纪以来钾质火山岩显著高87Sr/86Sr、极低143Nd/144Nd值,208Pb/204Pb值普遍偏高,古近纪火山岩这种差别则不明显.揭示了新生代以来,在印度大陆岩石圈向北俯冲过程中,拉萨地块比青藏高原北部融入了更多喜马拉雅大陆地壳端元成分.中新世早中期,印度大陆板块向北A型俯冲到拉萨地块基底西段,并发生岩石圈不同层次部分熔融、岩石圈断离等作用.     

青藏高原拉萨地块西部中新世赛利普超钾质岩石的地球化学与岩石成因

西藏拉萨地块西部赛利普中新世碰撞后超钾质火山岩由中国地质调查局地质填图首次发现,露头呈残丘状集中分布于中新世赛利普盆地,为一套含地幔包体的粗面岩,SiO_2含量中等(55.36%～6.70%),高K_2O含量(6.70%～7.50%)和K_2O/Na_2O比值(3.34～4.93)。岩石高MgO(6.4%～7.95%)、Cr(174×10~(-6)～421×10~(-6))、Ni(268×10~(-6)～337×10~(-6))和Mg~#(68～72),岩石为地幔部分熔融的原始岩浆。岩石高度富集大离子亲石元素(LILE)和轻稀土元素(LREE)、具有明显的Nb、Ta、Ti的负异常、富集放射性成因Sr、Pb及Nd同位素(~(87)Sr/~(86)Sr=0.727327～0.727803,~(206)Pb/~(204)Pb=18.705～18.779,~(207)Pb/~(204)Pb=15.731～15.761,~(208)Pb/~(204)Pb=39.775～39.919,~(143)Nd/~(144)Nd=0.511848～0.511861)、较低的ε_(Nd)值(≈15)和古老的Nd模式年龄(t_(DM)=2.2～2.4 Ga),这些地球化学特征揭示出赛利普的岩浆源区为富集地幔(EMⅡ)。将赛利普与拉萨地块西部其他地点和青藏高原北部的北羌塘和西昆仑地区出露的超钾质岩石进行综合对比表明,赛利普超钾质岩石可能为尖晶石相含金云母橄榄岩及少量石榴石相含金云母橄榄岩地幔的低度部分熔融的产物。拉萨地块超钾质岩石的形成可能与印度大陆岩石圈俯冲,或是俯冲的印度大陆地壳前缘撕裂和分段俯冲有关。     

西秦岭新生代钾霞橄黄长岩的地球化学及其岩浆源区性质

西秦岭礼县地区新生代钾霞橄黄长岩具有贫SiO_2和Al_2O_3,富CaO、Mgo、TiO_2及K_2O Na_2O的特征,矿物组合中除橄榄石、辉石外,普遍含有霞石、黄长石、白榴石和磁铁矿等矿物。火山岩的∑REE为97.82×10~(-6)～639.1×10~(-6)。岩石以强烈富集大离子亲石元素(LILE,如Rb、Ba、K、Sr)和高场强元素(HFSE,如Nb、Th、Ta、P、Zr、Hf等)为特征具有Pb和Ti的负异常。火山岩具有相对高的~(143)Nd/~(144)Nd比值(0.512007～0.512130,ε~(Nd)= 3.4～ 5.8)和相对低的~(87)Sr/~(86)Sr比值(0.703374～0.704726)。~(206)Pb/~(204)Pb、~(207)Pb/~(204)Pb和~(208)Ph/~(204)Ph的比值范围分别为18.088～19.112,15.476～15.626和38.071～39.680。岩石的微量元素和Sr、Nd和Pb同位素特征显示其与洋岛玄武岩(OIB)的地球化学特征相似。源区组成显示了亏损地幔端元DM、HIMU端元和富集地幔端元EMII这三种地球化学端元混合的特征。     

华北龙岗第四纪玄武岩：岩石成因和源区性质

华北克拉通东北缘龙岗第四纪玄武岩的地球化学研究为大陆碱性玄武岩的成因以及源区的性质提供了重要的依据。龙岗第四纪玄武岩为碱性玄武岩,具有类似 OIB 的 REE 和微量元素分配特征。岩石的 Sr-Nd 同位素轻度亏损(~(87)Sr/~(86)Sr=0.7044～0.7048,ε_(Nd)=0.6～2.1),具有 Dupal 异常的高放射性成因 Pb 同位素组成(~(206)Pb/~(204)Pb:17.734～18.194,~(207)Pb/~(204)Pb=15.553～15.594,~(208)Pb/~(204)Pb=38.322～38.707)。这种地球化学特征指示了原始岩浆起源于<70km 深度的地幔,并经历了一定程度的橄榄岩、单斜辉石和钛-铁氧化物的结晶分异。岩浆源区中以来类似 MORB 软流圈物质的熔体为主,另外有少量来自 EM Ⅰ性质的富集岩石圈地幔以及俯冲流体/熔体的物质贡献,显示了深部岩石圈-软流圈一定程度的相互作用以及太平洋板块俯冲的影响。岩浆源区多种端元组分的存在表明该地区岩石圈的减薄/置换受到多种因素的影响。     

Late Cenozoic volcanic province in Central and East Asia

The paper presents materials on the inner structure of the Late Cenozoic within-plate volcanic province in Central and East Asia, in which two subprovinces are distinguished: Central Asian and Far Eastern, which comprise a number of autonomously evolving volcanic areas. Some of the volcanic areas are proved to have evolved for a long time, starting in the Late Mesozoic. In spite of differences in their age and structural setting, the volcanic areas evolved according to similar scenarios in the Late Cenozoic. Magmatism in the province was related to a mantle source of the within-plate type. The magmatic associations are dominated by mafic alkaline high-K rocks. The rocks are geochemically close to basalts of the OIB type, and their isotopic composition corresponds to a combination of mantle sources of the PREMA, EMI, and EMII types at the predominance of PREMA. Geological, geochemical, and isotopic lines of evidence suggest that magmatism in the province was related to mantle plumes. This is consistent with geophysical data, which testify that the volcanic areas are underlain by upwellings of the asthenospheric mantle or plumes. Seismic tomography data indicate that the “stems” of the plumes can be traced down to the upper and lower mantle. The province is thought to have been produced when the eastern margin of the Asian plate overlapped one of the branches of the Pacific superplume at approximately 160 Ma. This branch of the superplume is pronounced in the modern mantle structure as a cluster of mantle plumes that control (according to seismic tomography data) the interaction zone of the Pacific and Asian lithospheric plates.     

Formation of the Late Cenozoic volcanic complexes of the Lesser Caucasus

The paper considers the role of the lithospheric mantle and asthenosphere during the Late Cenozoic collision volcanism of the Lesser Caucasus. The results of petrogeochemical studies show that the products of volcanism of the West Volcanic Zone of Armenia and the calc-alkaline andesite–dacite–rhyodacite complex of the Neogene Kelbadzhar and Karabakh plateaus were formed from an enriched source in a suprasubduction setting. Late Pliocene–Quaternary moderately alkaline and alkaline volcanic rocks of the Lesser Caucasus differ in petrogeochemistry from suprasubduction volcanic rocks. In trace element contents and patterns, they are similar to rocks formed from an enriched mantle source. Comparative analysis of the geological and geophysical data suggests the model of lithospheric slab break-off of the thickened lithosphere as the triggering mechanism for Late Cenozoic magmatism of the Lesser Caucasus.     

可可西里湖地区新生代火山岩同位素地球化学特征及火山成因、源区性质讨论

在青藏高原腹地可可西里地区发育一套新生代碱性、高钾钙碱性——钾玄岩火山岩类．由于该时期正是亚洲大陆内部岩石圈发生剧烈变形，青藏高原强烈隆升的重大变革时期，火山岩的形成在这些重大事件中扮演什么角色?很值得探讨。通过对区内火山岩Rb、Sr、Sm、Nd、Pb同位素的研究，在火山岩的岩浆来源、成因等方面获得了大量信息。研究表明；新生代火山岩主要来源于富集Ⅱ型地幔区，部分为具极高εSr和极低εNd的酸性火山岩，它是与区内钾质熔岩同源的晚期分异产物；碱性火山岩在成因上与板内初始裂谷有关。研究成果为青藏高原特有的“壳-幔混合层”的形成提供了证据。     

Isotopic evidence for the origin of Cenozoic volcanic rocks in the Pinacate volcanic field, northwestern Mexico

Six volcanic rocks, reconnaissance samples representing most of the temporal and compositional variation in the Pinacate volcanic field of Sonora and Arizona, are characterized for major element and Nd---Sr isotopic compositions. The samples consist of basanite through trachyte of an early shield volcano, and alkali basalts and a tholeiite from later craters and cinder cones. With the exception of the trachyte sample, which has increased ⁸⁷Sr/⁸⁶Sr due to crustal effects, all ⁸⁷Sr/⁸⁶Sr values fall between 0.70312 and 0.70342, while ε_Nd values are all between + 5.0 and + 5.7. Clinopyroxene in a rare spinel-lherzolite nodule derived from the uppermost mantle beneath the field has ⁸⁷Sr/⁸⁶Sr of 0.70320 but ε_Nd of + 8.8, three ε_Nd units higher than the volcanic rocks. Both the volcanic rocks and the nodule record the presence of asthenospheric, rather than enriched lithospheric mantle beneath Pinacate. This is consistent with one or both of (a) proximity of Pinacate to the Gulf of California spreading center and (b) presence of similar asthenospheric mantle signatures in volcanic rocks over a wide contiguous area of the southwestern USA. We consider the comparison to other southwestern USA magma sources as the more relevant alternative, although a definite conclusion is not possible at this stage.     

K—Ar Geochronology and Evolution of Cenozoic Volcanic Rocks in Eastrn China

Cenozoic volcanic rocks widespread in eastern China constitute an important part of the circum-Pacific volcanic belt.This paper presents more than 150K-Ar dates and a great deal of petrochemical analysis data from the Cenozoic volcanic rocks distributed in Tengchong,China‘s southeast coast,Shandong,Hebei,Nei Monggol and Northeast China.An integrated study shows that ubiquitous but uneven volcanic activities prevailed from the Eogene to the Holocene,characterized as being multi-eqisodic and multicycled.For example,in the Paleocene(67-58Ma),Eocene(57-37.5Ma),Miocene(22-18,16-19Ma),Pliocene(8-3Ma),and Early Pleistocene-Middle Pleistocene(1.2-0.5Ma) there were upsurges of volcanism,while in the Oligocene there was a repose period.In space,the older Eogene volcanic rocks are distributed within the region or in the central part of the NE-NNE-striking fault depression,while the younger Neogene and Quaternary volcanic rocks are distributed in the eastern and western parts.Petrologically,they belong essentially to tholeiite-series and alkali-series basalts,with alkalinity in the rocks increasing from old to youg.The above regularities are controlled by both global plate movement and regional inherent tectonic pattern.     

Petrography of Cenozoic volcanic rocks of Egypt (UAR)

The detailed petrographical characters of Cenozoic volcanic rocks of Egypt are given. Two pétrographic provinces have been identified: Abu Zaabal-Abu Rawash-Qatrani province and Cairo-Suez-El-Bahnasa-Tahna province. The rocks of the first one are doleritic basalts, while those of the second one are typical basalts. The weathering of the doleritic basalt, as especially observed in quarries, was also studied.

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Zusammenfassung Der detaillierte petrographische Charakter von känozoischen vulkanischen Gesteinen aus Ägypten wird dargestellt. Zwei petrographische Provinzen sind identifiziert worden: die Abu Zaabal-Abu Rawash-Qatrani-Provinz und die Cairo-Suez-El-Bahnasa-Tahna-Provinz. Die Gesteine der ersten sind doleritische Basalte, während die der zweiten typische Basalte sind. Die Verwitterung der doleritischen Basalte, insbesondere in Steinbrüchen beobachtet, wird ebenfalls dargestellt.

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Résumé Le caractère détaillé pétrographique de roches volcaniques cénozoiques d'Egypte est démontré. On a identifié deux provinces pétrographiques: la province Abu Zaabal-Abu Rawash-Qatrani et la province Caire-Suez-El-Bahnasa-Tahna. Les roches de la première sont des basaltes doléritiques, tandis que celles de la deuxième sont des basaltes typiques. L'altération des basaltes doléritiques, en particulier observée dans des carrières, a aussi été étudiée.

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. : Abu Zaabal-Abu Rawash- Qatrani, a -Cairo-Suez-EI Bahnasa-Tana. , — . .

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Dedicated to Professor Dr. A.Rittmann on the occasion of his 75th birthday     

长江源区新生代火山岩的年代学研究

长江源区的火山岩包含了青藏高原北部新生代火山岩形成及演化的全部信息，其年代学研究对查明青藏高原北部新生代火山活动时空演化具有重要意义。通过K—Ar同位素年代学研究，将长江源区新生代的火山活动划分为3期：第Ⅰ期(40．1-35．1Ma)火山喷发较弱，形成小范围分布的细粒安粗岩和斑状粗面岩；第Ⅱ期(26．5～17．6Ma)火山喷溢最为强烈，形成大面积厚层黑色气孔状安粗岩；第Ⅲ期(5．5-4．61Ma)由潜火山作用形成球粒状、斑状粗面岩岩丘。长江源区3个期次的火山喷发与青藏高原北部火山活动的阶段性相对应。长江源区新生代火山岩的演化特征为：从早到晚，岩石系列由高钾钙碱性系列→钾玄岩系列演化；岩性由安粗岩→粗面岩演化。     

Trace Element Geochemistry of Cenozoic Volcanic Rocks in Shandong Province

The Cenozoic volcanic rock of Shandong Province are mainly alkalic and strongly alkalic basaltic rocks.The Contents of major and trace elements including transitional,incompatible and rare-earth elements were determined.The chemical characterisitics of major and trace elements indicate that these basaltic rocks were derived from a mantle source and probably represent a primary magma,I,e.,unmodifiecd partical melts of mantle peridotite in terms of Mg values,correlatione between P2O5 and Ce,Sr,Ni and Rb concentrations,mantle xenoliths,etc.The abundances of trace elements vary systematically from west to east.The compatible transition elements such as Co,Ni,and Cr show a remarkable depletion,whereas the incompatible and rare-earth elements are abundant as viewed from the chondrite-nor-malized patterns.The chemical composition and correlation are consistent with the tectonic setting.According to the batch and fractional partial melting theory,the trace element contents of Shandong volcanic rocks can be calculated from the two-component mixing model.     

青藏高原北部新生代火山岩的成因机制

Based on the electron probe analyses result of the minerals and the bulk rock composition of the Cenozoic volcanic rocks from Yumen and Hoh Xil lithodistricts on the Qinghai-Tibet Plateau, the forming conditions including temperature and pressure of those rocks are studied.According to the thermodynamics calculation result of the mineral-melt equilibrium,the depth of the asthenosphere superface (about 75～130km) for the northern part of the Qinghai-Tibet Plateau during Cenozoic era is suggested. Finally, this paper indicates that the Cenozoic volcanic rocks in the northern part of the Qinghai-Tibet Plateau mainly consist of shoshonite series.Their forming temperature is 630～1039℃ and forming pressure is between 2.3～4.0 GPa and formed in the intracontinental orogenic belt,where the primary magma was originated from a particular enriched upmantle and accreted crust-mantle belt or directly originated from asthenosphere superface by partial melting of pyrolite.     

Magmatic evolution of Late Cenozoic volcanic rocks of the Lau Ridge,Fiji

Three main groups of lavas are exposed on islands of the Lau Ridge: the Lau Volcanic Group (LVG), 14.0–5.4 Ma, are predominantly andesite; Korobasaga Volcanic Group (KVG), 4.4–2.4 Ma, are predominantly basalt and Mago Volcanic Group (MVG), 2.0–0.3 Ma, are basalt-hawaiite. LVG and KVG lavas are mostly medium-K tholeiitic rocks with high LILE/HFSE ratios characteristic of islands ares, while MVG lavas are ne-normative alkalic rocks with high LILE and HFSE, characteristic of ocean island basalts. LVG lavas have high ?_Nd (+8.0–+8.4) and low ⁸⁷Sr/⁸⁶Sr (0.70273–0.70349) similar to N-MORB, whereas KVG lavas have slightly more radiogenic values (?_Nd=+7.5?+8.4; ⁸⁷Sr/⁸⁶Sr=0.70323-0.70397). MVG lavas form an isotopically distinct group having lower ?_Nd (+4.6–+4.9) and (⁸⁷Sr/⁸⁶Sr ranging from 0.70347–0.70375). LVG lavas were erupted in a primary oceanic island arc (Vitiaz arc) during the Miocene. Basaltic lavas were derived by approximately 19% partial melting of mantle wedge peridotite with only minor subduction component. Andesites and dacites were produced by low-pressure plagioclase-pyroxene-titanomagnetite dominated crystal fractionation. KVG lavas were erupted during the period immediately prior to or during the initial stages of rifting in the Lau Basin, and, like LVG lavas, show significant chemical differences at the northern and southern ends of the Lau Ridge. Lavas at the northern end (type (ii)) appear to be derived from a more depleted source than LVG but with a greater amount of subduction component. Those at the southern end (type (i)) probably came from a slightly more enriched source with less subduction component. MVG basalts and hawaiites were derived from an enriched mantle with little or no subduction input. The hawaiites (type (i)) could not have been derived from the basalts (type (ii)), and the two magma types must have come from different sources, indicating mantle heterogeneity. The lack of subduction influence indicates the MVG lavas are tectonically unrelated to the present-day Tonga arc, and the lack of depletion indicators suggests they have tapped a different (new?) part of the mantle wedge. This may reflect introduction of sub-Pacific mantle through the present Tonga-Lau subduction system.