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1.
<正>洋岛玄武岩(OIB)和洋中脊玄武岩(MORB)的组成能够用来了解地球的内部演化。亏损强不相容元素的MORB被认为起源于上地幔。而一些来自地幔柱的OIB被认为起源于下地幔,这为我们了解地球长期的地球化学分异以及下地幔的组成提供了难得的机会。尽管大多数OIB相比MORB具有较为富集的同位素与不相容元素 相似文献
2.
新疆东准噶尔克拉麦里蛇绿岩地球化学:洋脊俯冲的产物 总被引:5,自引:5,他引:5
新疆东准噶尔克拉麦里蛇绿岩中的镁铁质岩兼具有洋中脊玄武岩(MORB)和岛弧拉斑玄武岩(IAB)的特征,岩石地球化学特征表现为轻稀土(LREE)亏损、平坦或略微富集,不同程度地亏损高场强元素(HFSE)而富集大离子亲石元素(LILE),成分上非常相似于受洋脊俯冲影响的 Chile Ridge 和 Cocos Ridge 玄武岩。可以认为其可能形成于受洋脊俯冲影响的岛弧或弧前扩张环境。相对较高的ε_(Nd)(t)(7.2~9.8)、低 Nb/Zr、Ta/Yb 比值,说明在洋脊俯冲的影响下,其源区可能存在有至少三种组分:弧下地幔、来自消减板片流体和俯冲沉积物、MORB 地幔。 相似文献
3.
大陆板内玄武岩数据挖掘:成分多样性及在判别图中的表现 总被引:7,自引:4,他引:3
通常认为,大陆溢流玄武岩(CFB)、裂谷玄武岩(CRB)、板内玄武岩(WPB)均产于板内构造环境,其地球化学特征与OIB类似,源于富集的下地幔,与地幔柱的活动有关。本文利用GEOROC数据库对全球CFB、CRB和WPB数据进行挖掘,发现上述三类玄武岩判别图投图几乎落入了全部的构造环境域,有些甚至主要落入MORB和IAB区,而不是落入WPB区。结果表明原先的玄武岩判别图的判别功能值得商榷,尤其对大陆玄武岩来说,许多判别图都存在问题。全体CFB、CRB和WPB的地球化学成分变化巨大,暗示其源区具有强烈的不均一性:部分CFB、CRB和WPB来自富集的地幔柱,仍然具有经典的OIB的特征;部分来自MORB的源区,与MORB的再循环作用有关;部分来自岛弧岩石圈之下的亏损地幔源区,以强烈亏损Nb-Ta为特征,类似岛弧玄武岩的地球化学特征。许多地区的大陆玄武岩可分为低钛和高钛两类,低钛玄武岩大多是亏损或强烈亏损的,而高钛玄武岩通常是富集型的。本文的研究表明,富集型大陆玄武岩可能来自富集的下地幔,而亏损的和强烈亏损的玄武岩可能来自具有MORB或岛弧特征的软流圈地幔。进一步指出,源区性质可能是大陆玄武岩多样性的主控因素,其次为部分熔融程度、熔融深度、结晶分离、陆壳混染以及AFC过程。 相似文献
4.
弧后盆地玄武岩(BABB)数据挖掘:与MORB及IAB的对比 总被引:6,自引:0,他引:6
Yang Jing Wang Jinrong Zhang Qi Chen Wanfeng Pan Zhenjie Jiao Shoutao Wang Shuhua 《地球科学进展》2016,31(1):66-77
弧后盆地玄武岩(BABB)全球分布有限,与板块俯冲有关,位于岛弧外侧,规模小,寿命短,现代BABB主要分布于西太平洋。通常认为,BABB地球化学成分变化较大,包括正常洋中脊玄武岩(N-MORB)、富集洋中脊玄武岩(E-MORB)、岛弧玄武岩(IAB)及少量洋岛玄武岩(OIB)组分。在玄武岩构造判别图中,BABB大多在洋中脊玄武岩(MORB)范围内,说明BABB类似MORB。新的全球MORB数据研究表明,MORB包含了从MORB到OIB及IAB的组分,而BABB相对于MORB更富集Cs,Rb,U,Ba,Th和Pb等不相容元素,有明显的Nb-Ta负异常,表明BABB兼具MORB和IAB的地球化学特征,是俯冲流体及沉积物参与其岩浆作用过程所致,大多是在湿的条件下部分熔融形成的。弧后盆地可分为初始弧后盆地和成熟弧后盆地,前者玄武岩具有明显的岛弧玄武岩的地球化学特征,而后者玄武岩更接近MORB的特征。 相似文献
5.
海山是一个地貌术语,通常分为出露于海平面以上和淹没于以下的两类。海山具有复杂的成因,可产于各种不同的构造环境,其出露的岩性主要有:洋岛玄武岩(OIB)、大洋中脊玄武岩(MORB)、弧后盆地玄武岩(BABB)、岛弧玄武岩(IAB)和大陆边缘玄武岩(CMB)等。本文的研究表明,CMB 和OIB 的地球化学性质大体相似,但是,二者的成因可能既有相似性,也存在某些差异性。OIB 产于板块内部,属于板内岩浆活动的产物,通常认为与“热点”或“地幔柱”有关;而CMB 则可能是古大陆岩石圈与年轻洋壳发生浅部再循环的结果。所以,除“热点”理论外,古大陆岩石圈和年轻洋壳的浅部再循环在海山和洋岛火山形成过程中也扮演了重要的角色。来自IAB 的样品明显亏损Nb、Ta和富集K、Pb、Cs、Rb等大离子亲石元素,表明IAB 的形成与俯冲作用有关。研究表明,全球可能存在3 种类型的热点:第一类是原生的热点,来自深部地幔;第二类是次生的热点,可能形成在地幔柱的浅部,来自超级地幔柱的上部;第三类来自上地幔,可能是大洋岩石圈伸展的产物。因此,海山的成因不可能用地幔柱一种模式予以解释,还应当考虑板块活动中其他各种因素(洋壳再循环、古老陆壳再循环、消减带物质以及水的加入,部分熔融程度、岩浆混合作用、不同地幔端元混合等)的影响。 相似文献
6.
中国南方新生代地幔柱活动的地球化学证据 总被引:7,自引:0,他引:7
中国南海海盆、海南岛、雷琼和龙海—明溪地区新生代玄武岩的总体相当于洋岛玄武岩(OIB),富集高场强元素(HFSE),尤其是富集Nb、Ta、U、Ti。南海海盆新生代玄武岩是玻利尼西亚型(Polynesian)、夏威夷型(Hawaii)和MORB型共存,可能是在扩张洋脊上面形成的OIB,下地幔成因的超地幔柱上升致使上地幔物质加入,海南岛和雷琼地区玄武岩具有与南海海盆玄武岩大致相似的成因。大陆板内同时代的龙海—明溪地区玄武岩具特别高的Nb/Zr和Nb/Y值,均表现为地幔柱成因的玻利尼西亚型玄武岩,其形成既可能有古老俯冲洋壳熔融后榴辉岩质残余下沉至下地幔成因,也可能有包括下地壳在内的岩石圈物质的贡献。 相似文献
7.
汪洋 《矿物岩石地球化学通报》2001,20(4):225-227
洋岛玄武岩 (OIB)氦同位素组成 (3 He 4 He)在地理分布上具有非均匀性特征。3 He 4 He值为 5~ 6Ra 的OIB主要分布在南半球 ,而分布于冰岛和夏威夷 (包括Loihi)等地的OIB3 He 4 He值为 10~ 35Ra。低3 He 4 He值OIB具有富集大离子亲石元素U、Th的源区 ,由于U、Th衰变释放的4He同位素的积累导致其3 He 4 He值降低。该源区的形成是俯冲作用导致深海沉积物与地幔混合 ,其地理分布受Pangea大陆周边的古俯冲带制约。高3 He 4 He值OIB的源区则是亏损U、Th的地幔胞 (mantleblob) ,该地幔胞是由极度亏损U、Th的再循环洋壳或大陆下地壳与未排气的地幔胞混合形成的。经过 1~ 2Ga的演化形成即相对亏损4He同位素而3 He 4 He值高的源区。同时 ,这种地幔胞富集难融组分 ,所以较洋中脊玄武岩 (MORB)的源区更为稳定 ,即高3 He 4 He值源区的部分熔融需要更高的地幔温度。超级地幔柱上升可以导致地幔升温和高3 He 4 He值源区的熔融。3 He 4 He值OIB地理分布的非均匀性反映出全球地幔对流系统复杂的半球非对称性格局。 相似文献
8.
9.
对扬子地块西缘康滇裂谷北段的丹巴变质玄武岩进行了系统的岩石学、元素-Nd同位素地球化学研究,结果表明该岩石为碱性玄武岩,样品相对富MgO、富TiO2,Mg#值介于0.51~0.59之间.稀土总量较高,轻重稀土分馏较明显,Th、Nb、Ta、Zr、Hf和LREE等不相容元素富集,Y和HREE明显亏损,地球化学特征与洋岛玄武岩(OIB)类似.岩浆形成于板内裂谷环境,起源于类似OIB的地幔源区,并在上升过程中受到了大陆岩石圈地幔(SCLM)物质不同程度的混染,同时还可能有少量下地壳物质的混染.样品在岩石化学上表现出地幔柱岩浆作用的痕迹,很可能与导致Rodinia超级大陆裂解的新元古代地幔柱事件有关. 相似文献
10.
阿尔金茫崖地区早古生代蛇绿岩的地球化学特征 总被引:5,自引:0,他引:5
阿尔金茫崖地区基性火山岩属拉斑玄武岩系列,稀土配分模式均为LREE略富集型,Ti/V值为37~62,Th/Ta值接近1,少数大于1.5, Nb/Th值为7.7~16.8,显示了EMORB或OIB的特征。[HT5]ε[HT5\"]Nd(t)值为3.95~4.12,表明其源区来自亏损 地幔,但又有富集地幔物质的加入。茫崖基性火山岩的微量元素特征与冰岛Galapagos群岛Alcedo玄武岩的一致,说明阿尔金茫崖蛇绿岩产出在洋脊环境中,其源区是上地幔亏损物质和与地幔柱有关的富集地幔物质混合作用的结果。 相似文献
11.
Global Correlations of Ocean Ridge Basalt Chemistry with Axial Depth: a New Perspective 总被引:4,自引:0,他引:4
The petrological parameters Na8 and Fe8, which are Na2O andFeO contents in mid-ocean ridge basalt (MORB) melts correctedfor fractionation effects to MgO = 8 wt%, have been widely usedas indicators of the extent and pressure of mantle melting beneathocean ridges. We find that these parameters are unreliable.Fe8 is used to compute the mantle solidus depth (Po) and temperature(To), and it is the values and range of Fe8 that have led tothe notion that mantle potential temperature variation of TP= 250 K is required to explain the global ocean ridge systematics.This interpreted TP = 250 K range applies to ocean ridges awayfrom ‘hotspots’. We find no convincing evidencethat calculated values for Po, To, and TP using Fe8 have anysignificance. We correct for fractionation effect to Mg# = 0·72,which reveals mostly signals of mantle processes because meltswith Mg# = 0·72 are in equilibrium with mantle olivineof Fo89·6 (vs evolved olivine of Fo88·1–79·6in equilibrium with melts of Fe8). To reveal first-order MORBchemical systematics as a function of ridge axial depth, weaverage out possible effects of spreading rate variation, local-scalemantle source heterogeneity, melting region geometry variation,and dynamic topography on regional and segment scales by usingactual sample depths, regardless of geographical location, withineach of 22 ridge depth intervals of 250 m on a global scale.These depth-interval averages give Fe72 = 7·5–8·5,which would give TP = 41 K (vs 250 K based on Fe8) beneathglobal ocean ridges. The lack of Fe72–Si72 and Si72–ridgedepth correlations provides no evidence that MORB melts preservepressure signatures as a function of ridge axial depth. We thusfind no convincing evidence for TP > 50 K beneath globalocean ridges. The averages have also revealed significantcorrelations of MORB chemistry (e.g. Ti72, Al72, Fe72,Mg72, Ca72, Na72 and Ca72/Al72) with ridge axial depth. Thechemistry–depth correlation points to an intrinsic linkbetween the two. That is, the 5 km global ridge axial reliefand MORB chemistry both result from a common cause: subsolidusmantle compositional variation (vs TP), which determines themineralogy, lithology and density variations that (1) isostaticallycompensate the 5 km ocean ridge relief and (2) determine thefirst-order MORB compositional variation on a global scale.A progressively more enriched (or less depleted) fertileperidotite source (i.e. high Al2O3 and Na2O, and low CaO/Al2O3)beneath deep ridges ensures a greater amount of modal garnet(high Al2O3) and higher jadeite/diopside ratios in clinopyroxene(high Na2O and Al2O3, and lower CaO), making a denser mantle,and thus deeper ridges. The dense fertile mantle beneath deepridges retards the rate and restricts the amplitude of the upwelling,reduces the rate and extent of decompression melting, givesway to conductive cooling to a deep level, forces melting tostop at such a deep level, leads to a short melting column,and thus produces less melt and probably a thin magmatic crustrelative to the less dense (more refractory) fertile mantlebeneath shallow ridges. Compositions of primitive MORB meltsresult from the combination of two different, but geneticallyrelated processes: (1) mantle source inheritance and (2) meltingprocess enhancement. The subsolidus mantle compositional variationneeded to explain MORB chemistry and ridge axial depth variationrequires a deep isostatic compensation depth, probably in thetransition zone. Therefore, although ocean ridges are of shalloworigin, their working is largely controlled by deep processesas well as the effect of plate spreading rate variation at shallowlevels. KEY WORDS: mid-ocean ridges; mantle melting; magma differentiation; petrogenesis; MORB chemistry variation; ridge depth variation; global correlations; mantle compositional variation; mantle source density variation; mantle potential temperature variation; isostatic compensation 相似文献
12.
通过对西太平洋海山玄武岩和玄武质火山角砾岩的岩石学特征及其气孔充填物成分变化的研究,讨论了海山玄武岩与上覆富钴结壳的关系。富钴结壳的基岩火山岩主要为碱性玄武岩和玄武质火山角砾岩。碱性玄武岩中气孔充填物为S型和C型,S型和C型气孔充填物不共存在同一个气孔中。S型气孔充填物的物质成分富Si、Fe、K、Mg、Al,Co含量一般为0.17%~0.46%,其成分与碱性玄武岩的组成类似,其物质来源可能与碱性玄武岩有关。C型气孔充填物为O、Ca、C及少量Si、Al、Mg、Fe、K等元素,C型气孔充填物可能与海水中物质的沉积有关。由Si、Al、Fe、Mg、K等元素变化曲线反映出的S型气孔充填物沉积过程与富钴结壳早期的沉积过程具有相似的趋势,说明富钴结壳早期沉积物的物质来源可能与碱性玄武岩有关,富钴结壳物质来源可能是碱性玄武岩和海水共同作用的结果。 相似文献
13.
HOOPER P. R.; KLECK W. D.; KNOWLES C. R.; REIDEL S. P.; THIESSEN R. L. 《Journal of Petrology》1984,25(2):473-500
The Columbia River volcanic episode began with the eruptionof the coarsely porphyritic Imnaha Basalt between 17.0 and 16.5m.y. B.P. Lava poured from NNW trending vertical fissures andlocal vents north and south of the Seven Devils-Wallowa Mountainsdivide, covering a deeply dissected topographic surface of morethan 30, 000 km2, with an estimated volume of 6000 km3. A minimumof 26 flows or flow units are represented in 14 or 15 members.These include 11 chemical types and are exposed in sectionsranging to 577 m in thickness. All flows have normal polaritywith the exception of the youngest and oldest whose polarityis either reversed or transitional. The petrologic and majorelement chemical features of the Imnaha Basalt have much incommon with those of the Picture Gorge Basalt exposed in theJohn Day Basin of north-central Oregon, but the latter is younger,equivalent in age to part of the Grande Ronde Basalt formation. Using major and trace elements, the flows of Imnaha Basalt areclearly distinguished from those of all other formations ofthe Columbia River Basalt Group. Imnaha Basalt has lower SiO2,K2O, Ba and Rb than does Grande Ronde Basalt and differs frommost Wanapum and Saddle Mountains Basalt flows in its lowerTiO2 and P2O5 contents. The 11 Imnaha chemical types fall into two subgroups, the AmericanBar (AB) and Rock Creek (RC) subgroups, which differ in thecoarseness of their groundmass, the abundance of olivine, theirphenocryst assemblages, their SiO2 contents, CaO/Al2O3 ratio,and in their Sc, V, Sr, and Ni contents. Flows of the two subgroupsinterdigitate, but AB flows are predominant at the base of thesequence and RC flows at the top. One flow is a hybrid of thetwo magma types. Neither subgroup displays a significant variation in SiO2 content,but each does show systematic variation in K2O, P2O5, TiO2,Ba, Zr, Rb, and the REE, all of which vary inversely with MgO/(MgO+ FeO + Fe2O3). AB flows show a systematic increase in contentsof the incompatible elements upward in the succession, whileRC flows show a less obvious decrease upwards. Modelling of major and trace elements indicates that the chemicalvariations within each subgroup can be explained by simultaneouscrystal fractionation and assimilation of lower crustal material,in which the mass assimilated is only slightly less than thatlost by crystal fractionation; the mass fractionated varyingup to 50 per cent and the mass assimilated up to 42 per centof the original magma mass. These processes alone cannot explainthe relationships between the two Imnaha subgroups, nor thatbetween either subgroup and the overlying aphyric Grande Rondebasalt. The value of more complex quantitative models, in whichrecharge by more primitive magma, a variable composition forthe lower crustal contaminant, and the partial melting of aheterogeneous source, is limited by lack of data. Some suchprocess, or combination of processes in addition to a combinationof crystal fractionation and lower crustal assimilation, wouldseem to be required to account for the diversity in the earliestColumbia River basalts. 相似文献
14.
新疆北部晚古生代埃达克岩、富铌玄武岩组合:古亚洲洋板块南向俯冲的证据 总被引:50,自引:0,他引:50
地球化学研究结果表明,新疆北部富蕴县境内的晚古生代下泥盆统托让格库都克组的安山质岩石具有与埃达克岩非常相似的地球化学特征,它们具有较高的Al2O3,Na2O和Sr含量以及Sr/Y比值;明显亏损重稀土和Y,它们的MORB标准化微量元素蛛网图表现为明显的Nb,Ta负异常和Sr正异常,同时强烈亏损高场强元素。与埃达克岩共生的玄武岩的地球化学特征则与富铌玄武岩一致,表现为Si过饱和及富Na的特征,同时具有较高的Nb,TiO2和P2O5含量,并富集高场强元素。由于埃达克岩和富铌玄武岩的形成均与板块俯冲有关,因此,它们的存在表明,古亚洲洋在早-中泥盆世向南(哈萨克斯坦-准噶尔板块)发生了一次洋壳俯冲作用。 相似文献
15.
狮泉河-永珠-嘉黎蛇绿混杂岩带的构造属性及其与班公湖-怒江缝合带演化的关系,是了解班公湖-怒江洋中生代构造演化的关键.对隆巴俄桑地区的玄武岩和安山玢岩脉开展了岩石地球化学研究.结果表明,玄武岩属拉斑玄武岩系列,富集LREE和大离子亲石元素Rb、Ba、K、Sr、Pb等,亏损高场强元素Nb、Ta、Ti,与岛弧拉斑玄武岩特征一致.安山玢岩脉属拉斑玄武岩系列,有向钙碱系列演化的趋势,富集大离子亲石元素Rb、Ba、K、Sr、Pb、U等,亏损高场强元素Nb、Ta,显示岛弧成因岩浆岩地球化学特征,低ΣREE(11.8×10-6~13.8×10-6),(La/Yb)N=0.37~0.43,亏损LREE,与N-MORB相似,具有岛弧岩浆岩(IAB)和正常洋中脊玄武岩(N-MORB)双重特征,与不成熟的弧后盆地玄武岩(BABB)特征一致.综合区域地质资料认为,隆巴俄桑玄武岩和安山玢岩形成的构造环境均与俯冲相关,可能分别形成于班公湖-怒江洋壳南向俯冲消减相关的洋内或者活动大陆边缘的岛弧环境和不成熟的弧后盆地环境,是中侏罗至早白垩世期间班公湖-怒江洋壳南向俯冲消减的再循环的产物. 相似文献
16.
17.
Geochemistry of Picritic and Associated Basalt Flows of the Western Emeishan Flood Basalt Province, China 总被引:21,自引:1,他引:20
ZHANG ZHAOCHONG; MAHONEY JOHN J.; MAO JINGWEN; WANG FUSHENG 《Journal of Petrology》2006,47(10):1997-2019
Picritic lava flows near Lijiang in the late Permian Emeishanflood basalt province are associated with augite-phyric basalt,aphyric basalt, and basaltic pyroclastic units. The dominantphenocryst in the picritic flows is Mg-rich olivine (up to 91·6%forsterite component) with high CaO contents (to 0·42wt %) and glass inclusions, indicating that the olivine crystallizedfrom a melt. Associated chromite has a high Cr-number (73–75).The estimated MgO content of the primitive picritic liquidsis about 22 wt %, and initial melt temperature may have beenas high as 1630–1690°C. The basaltic lavas appearto be related to the picritic ones principally by olivine andclinopyroxene fractionation. Age-corrected Nd–Sr–Pbisotope ratios of the picritic and basaltic lavas are indistinguishableand cover a relatively small range [e.g. Nd(t) = –1·3to +4·0]. The higher Nd(t) lavas are isotopically similarto those of several modern oceanic hotspots, and have ocean-island-likepatterns of alteration-resistant incompatible elements. Heavyrare earth element characteristics indicate an important rolefor garnet during melting and that the lavas were formed byfairly small degrees of partial melting. Rough correlationsof isotope ratios with ratios of alteration-resistant highlyincompatible elements (e.g. Nb/La) suggest modest amounts ofcontamination involving continental material or a relativelylow-Nd component in the source. Overall, our results are consistentwith other evidence suggesting some type of plume-head originfor the Emeishan province. KEY WORDS: Emeishan; flood basalts; picrites; mantle plumes; late Permian 相似文献
18.
峨眉山大火成岩省与玄武岩铜矿--以贵州二叠纪玄武岩分布区为例 总被引:25,自引:6,他引:25
贵州晚二叠世玄武岩是峨眉山大火成岩省的组成部分,并位于其东区。全属高钛玄武岩。它是地幔柱边部或消亡期局部熔融产物。产物我省玄武岩中的铜矿床(点),与北美大陆同类铜矿有相似之处,可统称为玄武岩铜矿,属于“与陆相镁铁质喷发岩有关的铜矿床成矿系列”。 相似文献
19.
Rapid Temporal Changes in Ocean Island Basalt Composition: Evidence from an 800 m Deep Drill Hole in Eiao Shield (Marquesas) 总被引:1,自引:1,他引:1
CAROFF MARTIAL; MAURY RENE C.; VIDAL PHILIPPE; GUILLE GERARD; DUPUY CLAUDE; COTTEN JOSEPH; GUILLOU HERVE; GILLOT PIERRE-YVES 《Journal of Petrology》1995,36(5):1333-1365
The Dominique drill hole has penetrated the volcanic shieldof Eiao island (Marquesas) down to a depth of 800 m below thesurface and 691•5 m below sea-level with a percentage ofrecovery close to 100%. All the lavas encountered were emplacedunder subaerial conditions. From the bottom to the top are distinguished:quartz and olivine tholeiites (800–686 m), hawaiites,mugearites and trachyte (686–415 m), picritic basalts,olivine tholeiites and alkali basalts (415–0 m). The coredvolcanic pile was emplaced between 5•560•07 Ma and5•220•06 Ma. Important chemical changes occurred during this rather shorttime span (0•34 0•13 Ma). In particular, the lowerbasalts differ from the upper ones in their lower concentrationsof incompatible trace elements and their Sr, Nd and Pb isotopicsignature being closer to the HIMU end-member, whereas the upperbasalts are EM II enriched. The chemical differences betweenthe two basalt groups are consistent with a time-related decreasein the degree of partial melting of isotopically heterogeneoussources. It seems unlikely that these isotopic differences reflectchanges in plume dynamics occurring in such a short time span,and we tentatively suggest that they result from a decreasingdegree of partial melting of a heterogeneous EM II–HIMUmantle plume. Some of the intermediate magmas (the uppermost hawaiites andmugearites) are likely to be derived from parent magmas similarto the associated upper basalts through simple fractionationprocesses. Hawaiites, mugearites and a trachyte from the middlepart of the volcanic sequence have Sr–Nd isotopic signaturessimilar to those of the lower basalts but they differ from themin their lower 206Pb/204Pb ratios, resulting in an increasedDMM signature. Some of the hawaiites-mugearites also displayspecific enrichments in P2O5, Sr and REE which are unlikelyto result from simple fractionation processes. The isotopicand incompatible element compositions of the intermediate rocksare consistent with the assimilation of MORB-derived wall rocksduring fractional crystallization. The likely contaminant correspondsto Pacific oceanic crust, locally containing apatite-rich veinsand hydrothermal sulphides. We conclude that a possible explanationfor the DMM signature in ocean island basalts is a chemicalcontribution from the underlying oceanic crust and that studiesof intermediate rocks may be important to document the originof the isotopic features of plume-derived magmas. KEY WORDS: alkali basalt; assimilation; mantle heterogeneity; Marquesas; tholeiile
*Corresponding author 相似文献
20.
Summary In this paper we present what is, to the best of our knowledge, the first comprehensive study of clinopyroxenes and plagioclases contained in the flows of the Grande Ronde Basalt member of the Columbia River Basalt Group (northwestern USA). The rocks have MgO(wt%)<6%, and trace amounts of Cr and Ni. About 56% of extracted solid containing normative clinopyroxene and plagioclase explains the liquid line of descent from the more mafic sample (MgO wt%=5.89) to the most evolved. The most ubiquitous phases in the basalts are plagioclase and augite. Ilmenite and magnetite are accessories in all rocks. Olivine is present in small amount only in one sample (RT 89-7). Based on principles of Ca–Na plagioclase–liquid exchange, estimates of pre-eruptive magmatic water are < 2.4wt%. From clinopyroxene–liquid equilibria, calculated pressures and temperatures of ascending magmas are between 1atm and 0.617GPa, and 1068°C and 1166°C, respectively. Compositions of magnetite–ilmenite pairs and olivine–clinopyroxene–oxide assemblages yield post-eruptive oxygen fugacities of NNO=–1.923, and one pre-eruptive value of NNO=– 2.455. A simple model of asthenospheric melting and magma ponding in the lower crust fits the physical parameters.Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s00710-003-0017-1 相似文献