碧溪岭超高压石榴橄榄岩的流变学研究

从组构、位错、滑移系及古应力计算等方面综合研究了大别山超高压石榴榄榄岩的流变学特征（１）对橄榄岩中单斜辉石和斜方辉石的且构分析表明,碧溪岭地区超基岩经历了塑性变形,形成了ＬＰＯ组构：碧溪岭超基性岩的变形特征既淡类似于蛇绿岩,也不完全等同于幔源包体,它有十分独特遥变形的图象。（２）利用费氏台可观测到的滑移系有如下两种：「００１」（１００）为中高温滑移系,「０１０」（１００）为低温滑移系,低温滑移系和     

云南景洪南联山橄榄岩—闪长岩型岩体的特征及地质意义

岩相学和地球化学特征表明,南联山岩体是岩浆侵位的,岩石的分布显示环带构造;从中心向外依次为角闪橄榄岩、辉绿(辉长)岩和闪长岩。它们的结构和化学特征指示,这些岩石是由辉长-闪长岩质的岩浆结晶分异作用而形成的,角闪橄榄岩和部分辉绿岩为堆晶岩,其它的岩石为堆晶作用后分异而成的岩浆共结结晶作用所形成。原始岩浆的成分类似于高铝玄武岩和(或)玄武质安山岩。     

大别山北麓尖晶石橄榄岩中石榴辉石岩包体的成因矿物学信息

大别山北坡霍山饶拔寨等地的超基性岩中含有石榴辉石岩的包体。石榴辉石岩为草绿色致密块状 ,呈分米级的块体出现于蛇纹石化强烈的橄榄岩中。运用成因矿物学的方法 ,研究对比了石榴辉石岩的主要矿物组成石榴子石 ( Prp2 5— 3 5 )和钠质普通辉石 ( Jd1 0— 2 5 )等。岩石结构显示退变质作用有两期 :榴辉岩相退变形成的麻粒岩相矿物组合明显地被角闪岩相所切割。石榴辉石岩的寄主岩是尖晶石橄榄岩类 ,包括尖晶石方辉橄榄岩和尖晶石二辉橄榄岩。由于强烈的蛇纹石化 ,残余的橄榄石 ( Fo92— 93 )仅占 5%～ 4 0 % ,斜方辉石富镁 ( En87— 93)并有解理弯曲等韧性变形现象。采用 Ellisand Green的石榴子石单斜辉石 Fe-Mg交换平衡温度计 ,可计算出石榴辉石岩的 Fe-Mg分配系数 ( KD)为 4 .0 6～ 5.2 8。变质温度 t=84 1～ 94 3℃ ,估算压力 p=1 .5GPa,可以推测该橄榄岩体是从深度约 60 km的地幔 ,固态侵位于下地壳 ,而后与之一起隆升到地表。显然 ,此种石榴辉石岩应属 Coleman所划分的 A型榴辉岩 ,它与地幔岩浆作用有密切关系。石榴辉石岩和橄榄岩的岩石化学特征和稀土配分形式 ,说明它们的化学性质相当于地幔部分熔融所形成的玄武岩熔体及其残留体。在侧重探讨石榴辉石岩及其有关岩石中主要造岩矿物的成因矿物?     

新疆坡北杂岩体西端镁铁-超镁铁质岩体成因的稀有气体同位素制约

新疆坡北镁铁-超镁铁质杂岩体由一个辉长岩体以及二十多个超镁铁质侵入体组成,其中坡一超镁铁质岩体稀有气体同位素组成揭示存在地幔柱的贡献。坡北杂岩体西端的坡一、坡四、坡十和坡十四等几个超镁铁质岩体的稀有气体同位素对比分析结果表明,岩浆矿物的³He/⁴He值（0.26~2.79Ra）分布于地壳与地幔值之间,较高的²⁰Ne/²²Ne和较低的²¹Ne/²²Ne值分布于Ne质量分馏线（MFL）和L-K线之间,⁴⁰Ar/³⁶Ar=295~598。³He/⁴He与⁴⁰Ar/³⁶Ar比值揭示坡北杂岩体西端不同超镁铁质岩体形成过程中地幔（柱）、地壳和大气组分的贡献不同,岩体成因也可能不同。其中,坡一岩体具有地幔柱作用的贡献,其他三个岩体的岩石圈地幔及地壳流体组分的贡献较大。岩浆地幔源区由深部地幔柱物质叠加俯冲流体交代的岩石圈地幔物质所组成,大气与地壳物质组分可能由俯冲再循环洋壳带入到岩浆地幔源区以及围岩物质的混入。     

大别山碰撞后的石榴橄榄岩——南山岭岩体成因讨论

南山岭石榴橄榄岩岩体位于大别山罗田穹隆东南侧,面积很小(173×133 m2),与著名的碧溪岭榴辉岩岩体相距仅3 km.南山岭岩体以橄榄岩为主体,碧溪岭则是以榴辉岩为主体.南山岭石榴橄榄岩由贵橄榄石(75%)、透辉石(10%)和镁铝榴石(15%)组成,除上述三种矿物外,后者还含斜方辉石.     

碧溪岭石榴异剥橄榄岩的显微构造及成因机制

对超高压变质带中橄榄岩变形显微构造的研究, 有助于了解板块边界构造环境中地幔物质的流变性质和变形机制, 进而探讨其在深俯冲/折返过程中的地球动力学过程的作用.采用光学显微镜、电子探针、红外光谱、电子背散射衍射(EBSD)、位错氧化缀饰等多种方法系统研究了来自中国大别碧溪岭的石榴异剥橄榄岩中的变形显微构造.研究结果表明: (1)碧溪岭石榴异剥橄榄岩发育较好的形状优选方位, 但只有单斜辉石显示了强晶格优选方位, 而橄榄石晶格优选方位很弱, 与常见上地幔橄榄岩中单斜辉石组构弱而橄榄石组构强的特点差异显著, 反映了单斜辉石经历位错蠕变而橄榄石经历位错调节的颗粒边界滑移变形; (2)碧溪岭异剥橄榄岩中单斜辉石和橄榄石均含有一定量的结构水, 其中单斜辉石含水量124×10-6~274×10-6, 橄榄石含水量38×10-6~80×10-6, 高于常见造山带橄榄岩中各矿物的含水量, 可能反映了壳源物质混染引起的高含水量变形环境; (3)橄榄石中发育显著位错显微构造, 根据位错显微构造计算的变形差异应力为230~600 MPa, 高于正常上地幔稳态流变应力, 反映了俯冲带中的相对低温变形环境.综合分析研究表明, 超高压变质带中的高压、低温、高差异应力和高结构水含量是形成碧溪岭相对独特的橄榄石、单斜辉石变形显微构造的原因.      

新疆东天山天宇、白石泉杂岩体岩石学、矿物学特征对比研究

天宇和白石泉铜镍矿区含矿镁铁-超镁铁质杂岩体是东疆铜镍成矿带的重要组成部分。天宇矿区杂岩体以角闪辉长岩、角闪单辉橄榄岩、橄榄辉石岩、二辉辉石岩为主;白石泉矿区杂岩体则以辉石闪长岩、角闪辉长岩、橄榄辉石岩、辉石辉长岩、辉石橄榄岩、橄长岩为主;天宇矿区含矿超基性岩中SiO2,Al2O3,CaO,K2O,Na2O的质量分数比白石泉岩体低,Fe2O3,MgO相对较高;两个杂岩体的主要造岩矿物均以橄榄石、辉石、斜长石为主;铜镍矿石的矿物组成都较简单,金属矿物种类基本一致;两个杂岩体基性-超基性岩的成分接近原始岩浆,均来自于地幔,均属含铜镍中等的镁铁质岩石。     

南阿尔金巴什瓦克石榴橄榄岩的变质演化

南阿尔金巴什瓦克地区石榴橄榄岩在空间上呈透镜体状与高压基性麻粒岩和含石榴子石长英质片麻岩伴生.基于矿物共生组合关系和变质反应结构特征,并结合矿物化学详细分析以及温压条件的估算,我们将该区石榴橄榄岩的变质演化划分为3个阶段:峰期变质阶段(Ml)、峰后早期退变质阶段(M2)和晚期角闪岩相-绿片岩相退变质阶段(M3).M1阶段的矿物组合为石榴子石(Grt)+橄榄石(O1)+斜方辉石(Opx)+单斜辉石(Cpx),所估算的温压条件为:T=891～ 1054℃、P=17.2 ～24.7kbar; M2阶段以石榴子石周围出现斜方辉石(Opx)+单斜辉石(Cpx)+尖晶石(Spl)的次生边为特征,在P=10kbar时,估算的温度条件为:T=711 ～ 796℃;M3阶段以形成角闪石(Amp)+蛇纹石(Srp)+金云母(Phl)+绿泥石(Chl)+磁铁矿(Mag)±滑石(Tlc)为特征.石榴橄榄岩具有与相邻的长英质麻粒岩和基性麻粒岩类似的P-T演化历史.结合成因矿物学和初步的地球化学特征,我们认为石榴橄榄岩的原岩可能为侵位于大陆地壳的镁铁质-超镁铁质杂岩,并在早古生代与长英质地壳物质一起俯冲,经历高压(超高压?)/高温变质作用以及随后的变质和地球动力学演化.     

中国大陆科学钻探（CCSD）主孔石榴石橄榄岩中发现Fe2P合金矿物

在东海大陆超深钻(CCSD)的钻孔橄榄岩岩屑(孔深603-683米深部)中,分离出的矿物有硅酸盐、氧化物、硫化物、碳化物、自然元素、金属互化物和合金,计50-60种矿物。多种特征表明其中有一些不寻常矿物,并且有些矿物具有球状外形,如自然铁、镍纹石、铁镍合金、磁铁矿等。本文报道通过成分和结构分析鉴定出的铁磷合金矿物(Fe,P),成分中含少量Cr,Ni和Co,成分均一,分子式为(Fe1.80Ni0.05Cr0.02)P。EDXD数据表明该矿物的晶系属六方晶系;格子类型为P;空间群为P62m;晶胞参数a=b=5.877Ac=3.437A,a:c=1:0.5848。通过ICDDPDF-2x射线粉晶衍射数据库2004年公布的最新版本搜索查询,发现与人工合成的同种矿物Fe2P(ICDD83-2337,Barringerite.syn)十分接近,类似的矿物已在陨石中发现(FeNi)P,故确定本文报道的铁磷合金(Fe2P)为地球上首次发现的天然合金矿物。其成因和形成条件的研究正在进行中。     

Petrogenesis of the garnet peridotite and garnet-free peridotite of the Zhimafang ultramafic body in the Sulu ultrahigh-pressure metamorphic belt, eastern China

The CCSD‐PP1 drillhole penetrated a 110‐m‐thick sequence of the Zhimafang ultramafic body in the Sulu ultrahigh‐pressure (UHP) metamorphic belt, east China. The sequence consists of interlayered garnet‐bearing (Grt) and garnet‐free (GF) peridotite. Eleven layers of Grt‐peridotite, ranging from 1.2 to 9.5 m in thickness, have an aggregate thickness of 54.49 m, whereas eight layers of GF‐peridotite, ranging from 2.2 to 14.2 m in thickness, have a total thickness of 57.53 m. The boundaries between the two rock types are gradational. The Grt‐peridotites have slightly higher contents of Al₂O₃, CaO and SiO₂, and lower Mg^#s (0.90–0.92) than the GF‐peridotites (Mg^#s 0.91–0.93). Both contain low TiO₂ (<0.05 wt%) and have higher modal abundances of enstatite (average 10 vol.%) than diopside (1–5 vol.%), typical of depleted‐type upper mantle. The diopside in these rocks has high and relatively uniform Mg^# members (0.93–0.95), but highly variable Al₂O₃ (0.2–2.3 wt%), Na₂O (0.5–2.5 wt%) and Cr₂O₃ (0.38–2.09 wt%). Enstatite (En_92?93) contains very low Al₂O₃ (0–0.3 wt%). Both porphyroblastic and equigranular garnet are present. The equigranular varieties are zoned, from core to rim in Cr₂O₃ (3.4–4.2 wt%), MgO (18.4–17.5 wt%) and Al₂O₃ (21.1–20.1 wt%). Titania is very low in all the garnet, mostly <0.05 wt%. Chromite or chromium (Cr)‐spinel occur both in the Grt‐ and GF‐peridotite, and are characterized by high contents of Cr₂O₃ (49–58 wt%) and FeO (24–43 wt%), similar to that in iron‐rich Alpine‐type peridotites. Based on the bulk‐rock MgO–FeO compositions, the Zhimafang Grt‐peridotite probably underwent 20–30% partial melting, whereas the GF‐peridotite may have undergone as much as 35–40% partial melting, suggesting that the two rock types owe their differences to different degrees of partial melting rather than to pressure differences during metamorphism.     

赣东北蛇绿岩地幔橄榄岩岩石成因及其地质意义

赣东北蛇绿岩作为华南少有的前寒武纪蛇绿岩长期都是华南大地构造研究中的热点。该蛇绿岩地幔橄榄岩以方辉橄榄岩为主,稀土总量为0.83×10-6~2.62×10-6,远低于原始地幔的含量,而Mg O含量高于原始地幔。稀土元素表现为LREE相对富集,微量元素表现为大离子亲石元素(LILE)富集,高场强元素Nb明显亏损的特征,这表明赣东北地幔橄榄岩具有亏损地幔源区特征,同时也有不同程度的俯冲带流体的交代特征。HREE模拟的部分熔融程度为10%~30%;同时,赣东北蛇绿岩地幔橄榄岩中同时包含Cr#60和Cr#60两种不同成因的铬尖晶石,说明其经历了MOR(mid-ocean ridge)和SSZ(supra-subduction zone)两种构造环境。结合前人资料,笔者推测赣东北蛇绿岩早先可能形成于洋中脊环境(约1060 Ma),随后在洋内俯冲作用下(约970 Ma),位于俯冲带上部的地幔橄榄岩受到了来自俯冲带的流体/熔体的交代,经历了SSZ环境的改造。     

Super-silicic garnet microstructures from an orogenic garnet peridotite, evidence for an ultra-deep (>6 GPa) origin

We report the field, petrographic and mineral chemical characteristics of relict super‐silicic (=majoritic) garnet microstructures from the Otrøy peridotites in the Western Gneiss Region, Norway. The evidence for the former existence of super‐silicic garnet consists of two‐pyroxene exsolution microstructures from garnet. Estimates of the initial composition of the super‐silicic garnet imply pressures of 6–6.5 GPa, indicating that the Otrøy garnet peridotites were derived from depths >185 km. The garnet peridotites consist of inter‐banded variable compositions with c. 50% garnet peridotite and 50% garnet‐free peridotite. Two distinct garnet types were identified: (a) normal matrix garnet, grain‐size ≤4 mm, and (b) large isolated single garnet crystals and/or (polycrystalline) garnet nodules up to 10 cm in size. Large garnet nodules occur only within limited bands within the garnet peridotites. The relicts of super‐silicic garnet were exclusively found in some (not all) of the larger garnet nodules. Petrographic observations revealed that the microstructure of nodular garnet consists of the following four characteristic elements. (1) Individual garnet nodules are polycrystalline, with grain sizes of 2–8 mm. Garnet grain boundaries are straight with well‐defined triple junctions. (2) Some garnet triple junctions and garnet grain boundaries are decorated by interstitial orthopyroxene. (3) Cores of larger polycrystalline garnet contain two‐pyroxene exsolution microstructures. (4) Precipitation‐free rims (2 mm thick) surround garnet cores containing the exsolved pyroxene microstructure. Pyroxene exsolution from super‐silicic garnet was subsequently followed by brittle–ductile deformation of garnet. Both exsolved pyroxene needles and laths become undulous or truncated by fractures. Simultaneous garnet plasticity is indicated by the occurrence of high densities of naturally decorated dislocations. Transmission electron microscopy observations indicate that decoration is due to Ti‐oxide precipitation. Estimates of the P–T conditions for mineral chemical equilibration were obtained from geothermobarometry. The mineral compositions equilibrated at mantle conditions around 805±40 °C and 3.2±0.2 GPa. These P–T estimates correspond to cold continental lithosphere conditions at depths of around 105 km. From a combination of both depth estimates it can be concluded that the microstructural memory of the rock extends backwards to twice as great a depth range as obtained by thermobarometric methods. Available geochronological and geochemical data of Norwegian garnet peridotites suggest a multi‐stage, multi‐orogenic exhumation history.     

Sheared peridotite xenolith from the V. Grib kimberlite pipe,Arkhangelsk Diamond Province,Russia: Texture,composition, and origin

The petrography and mineral composition of a mantle-derived garnet peridotite xenolith from the V. Grib kimberlite pipe (Arkhangelsk Diamond Province, Russia) was studied. Based on petrographic characteristics, the peridotite xenolith reflects a sheared peridotite. The sheared peridotite experienced a complex evolution with formation of three main mineral assemblages: (1) a relict harzburgite assemblage consist of olivine and orthopyroxene porphyroclasts and cores of garnet grains (Gar1) with sinusoidal rare earth elements (REE) chondrite C1 normalized patterns; (2) a neoblastic olivine and orthopyroxene assemblage; (3) the last assemblage associated with the formation of clinopyroxene and garnet marginal zones (Gar2). Major and trace element compositions of olivine, orthopyroxene, clinopyroxene and garnet indicate that both the neoblast and clinopyroxene-Gar2 mineral assemblages were in equilibrium with a high Fe-Ti carbonate-silicate metasomatic agent. The nature of the metasomatic agent was estimated based on high field strength elements (HFSE) composition of olivine neoblasts, the garnet-clinopyroxene equilibrium condition and calculated by REE-composition of Gar2 and clinopyroxene. All these evidences indicate that the agent was a high temperature carbonate-silicate melt that is geochemically linked to the formation of the protokimberlite melt.     

Amphibole—Bearing Peridotite Xenoliths from Nushan,Anhui Province：Evidence for Melt Percolation Process in the Upper mantle and Lithospheric uplift

The spinel peridotite xenoliths of Group I in Quaternary basanites from Nushan,Anhui province,can be classified as two suites:a hydrous suite characterized by the ubiquitous occurrence of (Ti-) pargasite and an anhydrous suite.The nineral chemistry reveals that the anhydrous suite and one associated phlogopite-bearing lherzolite are equilibrated under temperature conditions of 1000-1100℃,whereas amplhibole-bearing peridotites display distinct disequilibrum features,indicating partial reequilibration from 1050 to 850℃ and locally down to 750℃. The amplhbole-bearing peridotites were probably the uppermost part of the high temperature anhydrous suite which was modally modifed by fractionating H2O-rich metasomatic agent during regional upwelling.This relatively recent lithospheric uplift event followed an older uplift event recognized from pyroxene unmixing of domains in local equilibrium,as well as the dominant deformation texture in the anhydrous suite.The first thermal disturbance can be linked with the regional extension and widespread basaltic volcanism in Jiangsu-Anhui provinces since Early Tertiary and the formation of the nearby Subei(North Jiangsu) fault-depression basin during the Eocene,while the second event in association with the formation of amphiboles probably indicates the continuation but diminution of upwared mantle flux since Neogene in response to the change in tectonic regime for eastern china.     

中国大陆科学钻探工程主孔石榴石单辉橄榄岩的岩石化学研究

中国大陆科学钻探工程主孔石榴石橄榄岩产出于603.20～683.53m之间,主要为石榴石单辉橄榄岩,内部还见有巨晶状角闪石岩(曾经是岩脉)和榴辉岩与橄榄岩之间厘米级的方辉辉石岩.石榴石橄榄岩多数含有钛斜硅镁石.从其内部所夹的榴辉岩条带可知,橄榄岩发生过褶皱等构造变形作用.其围岩和内部夹层榴辉岩中的锆石中舍柯石英的事实可能表明岩体经历过超高压变质作用.石榴石橄榄岩的主要造岩矿物橄榄石的Fo端员低(0.82～0.86)、全岩岩石化学的低Mg#值(77.26～85.07)和高易熔元素以及低于典型阿尔卑斯型橄榄岩的(Mg Ni)/(Fe Mn)比值,意味着该石榴石橄榄岩体的原岩为岩浆固结成因.石榴石橄榄岩的稀土元素总量低,配分型式有LREE富集型((La/Lu)N比值为9～16.6)、LREE适度富集型((La/Lu)N比值为1.47～8.22)和LREE亏损型或平坦型((La/Lu)N比值为0.62、1.19～1.92)三种,并构成从亏损或平坦型到富集型的韵律,反映了结晶分异的特点.微量元素蛛网图上,石榴单辉橄榄岩微量元素的丰度总体上低于N-MOBB的丰度.Cu、Ni和MgO的判别图表明,石榴石橄榄岩的原岩岩浆的固结成岩时期主要为镁铁质矿物的分离结晶作用而硫化物不是重要的矿物相.Ti和P的剧烈变化表明了有磁铁矿和磷灰石的堆积作用.微量元素判别图表明岩体受到了明显的地壳物质混染作用.铂族元素丰度总量低,其丰度分布型式图表明原岩岩浆的部分熔融程度高,而且元素的判别图表明岩浆具有S不饱和特点.硫化物残留在地幔中而使得岩浆中PGE相对Cu、Ni亏损,在Ni-PGE-Cu图上呈总体上的凹形分布.同属PPGE的Pt比Pd所显示的更高的相容性也表明了岩浆中S的不饱和特点.而Ir的负异常可能说明原始岩浆在侵入前的分离结晶作用其间发生了Ir的结晶析出,或者是在地幔部分熔融时Ir残留在地幔残留体中.因此,主孔石榴石橄榄岩的原始岩浆是上地幔适当部分熔融程度的产物((Pd/Ir)N≥1),可能在源区有硫化物的残余而造成了PGE相对Cu、Ni亏损而在Ni-PGE-Cu图上呈总体上的凹形分布.后S不饱和的岩浆经历分离结晶作用而造成了Pt相时于Pd亏损的特点.     

滇东南马关木厂新生代玄武岩中橄榄岩包体的含水性

对来自滇东南马关木厂的尖晶石二辉橄榄岩中名义上无水矿物(NAMs)进行显微傅里叶变换红外光谱(Micro-FTIR)分析,结果显示,单斜辉石、斜方辉石和橄榄石中均含有以羟基形式存在的结构水,单斜辉石的水含量为160×10~(-6)~557×10~(-6)(质量分数,下同),斜方辉石的水含量为85×10~(-6)~207×10~(-6),橄榄石的水含量为5×10~(-6)~12×10~(-6),根据矿物百分比含量估算的全岩水含量为46×10~(-6)~137×10~(-6);元素地球化学特征表明,本次研究的橄榄岩包体是岩石圈地幔经历较低程度部分熔融的残余;低(La/Yb)N值(0.22~0.57)以及高Ti/Eu比值(4 076~6 772)暗示橄榄岩可能经历了以硅酸盐熔体为交代介质的微弱地幔交代作用;单斜辉石的微量元素组成比较单一,整体表现出高场强元素、大离子亲石元素以及轻稀土元素的同步亏损;结合中国东部地区已经发表的橄榄岩包体含水量数据来看,滇东南马关木厂岩石圈地幔具有明显富水的特征,可能与该区自中生代以来遭受的新特提斯洋壳大规模俯冲流体交代作用有关;与华北克拉通含水量的明显差异有可能反映的是两地岩石圈地幔正处于不同的演化阶段。     

Petrochemistry of peridotites from North China: Significance for lithospheric mantle evolution

A petrochemical analysis was undertaken of peridotitic xenoliths in volcanic rocks that erupted from the Paleozoic to the Cenozoic within the eastern part of the North China craton, and the peridotites as tectonic intrusion in the Early Mesozoic from the Sulu orogen. The results show that the cratonic mantle, which was refractory and existed when the kimberlites intruded in the Paleozoic, had almost been replaced by the newly accreted fertile lithospheric mantle during the Mesozoic-Cenozoic. The erosion, metasomatism, and intermingling caused by the accreted asthenospheric material acting on the craton mantle along the weak zone and deep fault (such as the Tanlu fault) in the existing lithosphere resulted in the lithospheric thinning at a larger scale 100 Ma ago (but later than 178 Ma). The largest thinning would be in the Eogene. The upwelling asthenospheric material transformed into accreted lithospheric mantle due to the asthenospheric temperature falling in the Neogene (leading to relatively slight lithospheric incrassation), and finally accomplished mantle replacement. The peridotitic body in the Sulu orogen represents the products spreading from the modified cratonic lithospheric mantle. Translated from Earth Science—Journal of China University of Geosciences, 2006, 31(1): 49–56 [译自: 地球科学—中国地质大学学报]