Geochronology and Petrogenesis of Late Carboniferous to Early Permian Basalts in the Central Lhasa Subterrane, Southern Tibet: Implications for the Evolution of the Sumdo Paleo-Tethys Ocean

Basalts from the Late Carboniferous to Early Permian are extensively developed in the central Lhasa subterrane, southern Tibet. Studying the petrogenesis of these rocks may have implications for the late Paleozoic arc magmatism along the central Lhasa subterrane uncovering more of the evolution of the Sumdo Paleo-Tethys Ocean and its dynamic mechanism. Basalt samples from the Luobadui Formation in the Leqingla area, NW of Linzhou City in the central Lhasa subterrane, southern Tibet exhibit arc-like geochemical signatures in a subduction-zone tectonic setting characterized by high Al_(2)O_(3) and low TiO_(2) contents, fractionated REE patterns with low Nb/La ratios and high LREE concentrations, and negative HFSE anomalies. Based on their higher Th/Ce, Nb/Zr, and lower Ba/Th, Pb/Nd ratios, slightly negative to positive ε_(Nd)(t) values, and the relatively high Sr-Pb isotopic compositions, these samples were probably derived from partial melting of a depleted mantle source of garnet + spinel lherzolite, metasomatized by subducted sediments around 297 Ma. Modeling of the trace elements indicates that these basalts experienced fractional crystallization of olivine, clinopyroxene and minor plagioclase during magma ascent and eruption. It is proposed that these Late Carboniferous–Early Permian basalts are associated with the northward subduction of the Sumdo Paleo-Tethys Ocean seafloor along the southern margin of the central Lhasa subterrane.

Rutile to Titanite Transformation in Eclogites and its Geochemical Consequences:An Example from the Sumdo Eclogite,Tibet

The formation of titanite coronae after rutile is common in retrograde high-to ultrahigh-pressure meta-mafic rocks,which provides a good opportunity to address the geochemical behavior of HFSE in crustal environments.In the Sumdo eclogite,titanite occurs either as a corona around rutile grains or as semi-continuous veins cross-cutting the major foliation,whereas rutile grains occur either as inclusions in garnet or omphacite or as a relict core surrounded by titanite.Textural relationships and trace elements characteristics of rutile and titanite with different occurrences indicate that both minerals preferentially incorporate Nb and Hf over Ta and Zr in aqueous fluid.Moreover,the breakdown of omphacite and epidote could release substantial amounts of aqueous fluids enriched in Ca,Si,Fe and REE,which would react with rutile to form titanite coronae and veins.During this process,water-insoluble elements,like HFSE and HREE,behave like mobile elements,but they do not migrate substantially out of the system,instead,tending to react in situ.This suggests that the aqueous fluids released during the retrograde metamorphic reactions in mafic rocks could not substantially transfer fluidimmobile elements into the overlying mantle wedge in subduction environments.

Development of the Sumdo Suture in the Lhasa Block, Tibet, China

The Qinghai–Tibet plateau is a composite continental fragment formed by collision of multiple terranes and island arcs.The Lhasa terrane,which is located in the central part of the plateau,is bounded by the Yarlung–Zangbo suture to the south and Bangong-Nujiang suture to the north.An E–W–trending belt of(ultra)-high pressure eclogite was discovered in the Sumdo region of the Lhasa terrane.Careful field studies combined with petrological,geochemical and isotopic analyses show that the Sumdo eclogites mark a Carboniferous–Permian suture zone,at least 100 km long,containing ophiolite fragments,eclogites and Indosinian post–orogenic granitoids.This suture divides the Lhasa block into a northern and southern segment.Sumdo eclogite occurs about 200 km east of Lhasa city,and extends over 100km in an E–W direction.Sumdo eclogites were accompanied by garnet amphibolite and plagioclaseamphiboliteformedbyretrograde metamorphism of the eclogites.The eclogites were derived from oceanic basalts.LA–ICPMS U–Pb dating of zircon from the Sumdo eclogites indicates a Permian metamorphic age(260–270 Ma)and a Carboniferous protolith age of 303±4.8 MaThe ophiolite fragments in the Sumdo suture zone are composed of the ultramafic rocks,MORB–type basalt,OIB–type basalt and island arc basaltic andesite,some of which are intruded by post-collisional granites.The ultramafic body,a typical tectonic block in the suture zone,is completely serpentinized.Its geochemical features suggest that it is composed of harzburgite,typical of depleted mantle peridotite.The MORB and OIB–type basalts crop out in the Chasagang Formation,and the basaltic andesite crops out in the Leilongku Formation,both of which make up the Sumdo Group.Zircons from the OIB–type basalt with typical magmatic characteristics yield an average U–Pb age of306(95%)Ma,suggesting formation in a Paleo–Tethyan basin in the Carboniferous.U–Pb dating of zircon from the basaltic andesites yielded a concordant age of 265±3.1Ma,similar to the metamorphic age(266–270 Ma)of the eclogites,suggesting formation during subduction of the oceanic crust.Indosinian granodiorite with an age of194±4.3 Ma crops out north of the Sumdo suture.These granodiorites are similar to the late Indochina granites in the Lhasa block,and most likely formed during continent-arc collision or during closure of the Paleo-Tethyan Ocean.A four–stage model for the evolution of the Sumdo Paleo–Tethyan suture is proposed:1)From the Ordovician to the Devonian Gondwanaland was part of an epicontinental sea;2)In the Carboniferous,continental rifting produced a local basin,which then evolved into a Paleo-Tethyan ocean basin,dividing the Lhasa block into two segments;3)From the Permian to the early Triassic,Paleo-Tethyan oceanic crust was subducted northward and;4)In the middle Triassic and early Jurassic,the two fragments collided to form the modern Lhasa block.

The Metamorphic Evolution and Tectonic Significance of the Sumdo High and Ultrahigh Pressure Metamorphic Terrane, Central-South Lhasa Block, Tibet

Asthemaintectoniccomponentofthe Himalayan–Tibetan orogen,the Lhasa terrane has received much attention as it records the entire history of the orogeny.The occurrence of high pressure eclogite in the Sumdo complex in central Lhasa terrane has a significant importance on the understanding of the Paleo-Tethys subduction and plate itineration processes in this area.The petrological,geochemical and geochronological data of eclogite and associated blueschist and garnet-bearing mica schist from Sumdo,Jilang and Bailang area have been briefly reviewed to explore the origin and metamorphic evolution of this suture.Eclogites from the Sumdo complex have experienced low temperature,high pressure to ultrahigh pressure metamorphism,revealing a fastsubduction and exhumation process in a typical oceanic subduction zone.The large P-T range between different eclogites in the literature may be affected by the big error of unappropriated using geothermobarometry and may also because of slices of subducted blocks derived from different depths juxtapose together during exhumation.By summarizing the U-Pb,Lu-Hf and Sm-Nd ages of eclogites,the eclogite facies metamorphism is likely to occur in early Triassic during 245-225 Ma,but not the previously accepted late Permian at ca.260 Ma by the reinterpretation of the former geochronological data from literature.The opening of Paleo-Tethys Ocean between the Lhasa terrane initiate prior to ca.280 Ma and ultimate closure to integrate the Lhasa terrane was no earlier than225 Ma and may triggered by the initial subduction of Bangong-Nujiang Tethys Ocean in the north.

Ultramafic Blocks in Sumdo Region, Lhasa Block, Eastern Tibet Plateau: An Ophiolite Unit

Recently, an over 100 km long MORB-type eclogite belt of Permian was discovered in the Sumdo （松多） region of the Lhasa block, Tibet. A critical question thus is： what is the tectonic setting of the eelogite belt and is it related to an unrecognized suture in the region？ Further investigations show that there are some mafic and ultramafic rocks spacially associated with the eclogite belt in the region. Three ultramafic massifs were recognized in the Sumdo region, and called the Luomaling （罗马岭）, Gongbupala （贡布爬拉） and Qiazhasumdo （卡扎松多） massifs. All the massifs are fault-contacted with greenschist （Chasagang （岔萨岗） Formation） or muscovite-quartz schist （Mabuku （马布库） Formation）, and individuals are about 100 m×50 m in size extending in EW as the regional structure. All the ultramafic rocks have been entirely serpentinized, and the Gongbupala massif has been selected for study in geochemistry. Eleven chemical analyses of the rocks from the Gongbupala massif show a narrow range in contents： SiO2 （35.97-40.63） wt.%, MgO （37.02-38.60） wt.%, TiO2 （0.01-0.08） wt.%, Al2O3 （0.80-1.64） wt.%, （Na2O＋K2O） less than 0.1 wt.%, with high volatile contents （H2O＋CO2） （11.24-14.91） wt.%. After recalculation without H2O＋CO2, the mean values are SiO2 45.24 wt.%, MgO 43.54 wt.%, FeOT （7.45-9.97） wt.% （8.55 wt.% in average）, （MgO＋FeOT） 52.09 wt.%, Mg# （100×Mg/（Mg＋Fe＊）, where Fe＊ represents total Fe）=89.42-90.08, （m＋f）/Si （（atomicity Mg＋atomicity Fe） /atomicity Si）=1.53-1.75 （1.59 in average）, respectively. The mean M/F （atomicity Mg/atomicity Fe） ratio of the rocks is 9.05, which is classified as magnesium enriched-type of ultramafic rocks. The compositional features, depleted in K, Na, Ca, AI and Ti and enriched in Mg#, indicate the characteristics of peridotite originated from a depleted mantle. The rocks have low REE with ∑（1.60-2.68）×10^-6 similar to those of the primitive mantle. The chondrite-normalized REE patterns of all samples show slightly enrichment in LREE, with （Ce/Yb）N 1.03-2.46, but a little depleted in HREE. Most samples show a slight negative anomaly in Eu, a feature in REE from a relic mantle and common features in highly serpentinized ultramafic rocks in the Yarlung-Zangbo （雅鲁藏布） ophiolite and the Bangong （班公）-Nujiang （怒江） ophiolite in Tibet. The primitive mantle-normalized spiderdiagram of trace elements for Gongbupala ultramafic rocks yields uniform distributed pattern. They are relatively enriched in Rb, Ba, La, P element （LHSE） and depleted in Sm, Ti, Y, Yb element （HFSE）, a feature of metasomatic mantle peridotite. The geochemical features of the rocks suggest that the protolith of Gongbupala serpentinite in Sumdo region is harzburgite, a typical depleted mantle rock, and may represent a dismembered ophiolite unit in the region.

Metamorphism and Oceanic Crust Exhumation——Constrained by the Jilang Eclogite and Meta-Quartzite from the Sumdo (U) HP Metamorphic Belt

The Sumdo eclogite-bearing (U)HP metamorphic belt extends over 100 km across the middle part of the Lhasa terrane in southern Tibet, which forms a Permian-Triassic oceanic subduction zone between the south and the north Lhasa sub-terranes, leading to the reinterpretation of the tectonic evolution of the Lhasa terrane in the Tibetan-Himalayan orogeny. Previous studies show that there are significant differences in temperature and pressure conditions of the eclogites in four areas, e.g., Sumdo, Xindaduo, Bailang and Jilang areas. Studying the peak metamorphic P-T conditions and path of eclogite in the Sumdo belt is of great significance to reveal the subduction and exhumation mechanism of Paleo-Tethys Ocean in the Lhasa terrane. In this contribution, eclogite in the Jilang area of the Sumdo belt is chosen as an example to study its metamorphic evolution. The mineral assemblage of the eclogite is garnet, omphacite, phengite, hornblende, epidote, quartz and minor biotite. Garnet has a “dirty" core with abundant inclusions such as epidote, amphibole, plagioclase and a “clear" rim with few inclusions of omphacite and phengite.From the core to the rim, pyrope content in garnet increases while grossular content decreases, showing typical growth zoning. The rim of garnet is wrapped by the pargasite+plagioclase corona, showing amphibolite facies overprint during retrogression. Three stages of metamorphism are inferred as (1) prograde stage, represented by the core of garnet and mineral inclusions therein;(2) peak stage, represented by the garnet rim, omphacite, lawsonite, phengite, and quartz;(3) retrograde stage characterized by decomposition of lawsonite to zoisite, followed by symplectite of omphacite and corona rimmed garnet. A P-T pseudosection contoured with isopleths of grossular and pyrope contents in garnet is used to constrain the near peak P-T condition at 2.85 GPa, 575 °C. In general, the Jilang eclogite shows a clockwise P-T path with a near isothermal decompression process during exhumation. Combined with the age peaks of 583, 911, and 1 134 Ma from the detrital zircons of the country metaquartzite, a continental margin material involving exhumation process at shallow depth after the subduction channel exhumation is inferred for the Jilang eclogite and may further indicate that the subduction direction of the Sumdo eclogite belt is from north to south.

拉萨地块东部石炭——二叠系地层碎屑锆石年代学研究及启示

拉萨地块东部连续出露石炭—二叠系海相地层,研究其物源对揭示松多古特提斯洋演化过程具有重要意义。文章对工布江达娘蒲和林芝龙得地区石炭—二叠系地层开展碎屑锆石年代学研究,定年结果表明该套地层最年轻的年龄簇为314 Ma~322 Ma,指示其沉积时代不早于晚石炭世。综合对比前人报道的澳大利亚Canning和Perth盆地石炭—二叠系地层碎屑锆石年龄谱、拉萨地块内松多古特提斯洋演化岩浆作用记录和增生杂岩碎屑锆石年龄谱,笔者认为该套地层中石炭纪年龄的碎屑锆石主要来源于松多古特提斯洋演化过程中岩浆作用;工布江达娘蒲松多群(AnOs)地层与直孔—松多地区的松多组(C2P1s)为同一套地层,是松多古特提斯洋增生杂岩的一部分;林芝龙得地区诺错组(C1n)地层与当雄来姑组(C2P1I)地层类似,是松多古特提斯洋边缘稳定沉积。

西藏拉萨地块松多榴辉岩的锆石Lu／Hf同位素研究及LA-ICPMS U-Pb定年

最近在青藏高原拉萨地块中发现一条榴辉岩带。榴辉岩带位于拉萨北东近200km 处的松多乡一带,呈近东西方向延伸,至少长60km,宽2km～3km。锆石样品选自新鲜的榴辉岩样品,共测了39个数据点,其中前19个数据点仅做 Lu-Hf同位素分析,后20个数据点既做了锆石原位 Lu-Hf 同位素分析,同时也做了锆石原位 LA-MC-ICPMS U-Pb 定年。结果表明,松多榴辉岩锆石 Hf 同位素组成比较均一,具有高^(176)Hf/^(177)Hf 和低^(176)Lu/^(177)Hf 特征,^(76)Hf/^(177)Hf 和^(176)Lu/^(177)Hf 值分别变化在0.2829651～0.2830295和0.000002～0.000008之间,其可能代表全岩体系在变质作用发生时的平均 Hf 同位素组成。松多榴辉岩的高^(176)Hf/^(177)Hf 和低^(176)Lu/^(177)Hf 组成特征可能跟其高压变质作用以及在变质作用过程中形成石榴子石矿物有关。ε_(Hf)(0)变化于6.8～10.0,表明在其变质过程中,变质流体有亏损地幔物质的加入。LA-ICPMS 锆石 U-Pb 定年,所获得加权平均年龄260Ma±16Ma,为变质年龄。从而进一步确定了松多榴辉岩变质事件发生在二叠纪。

西藏拉萨地块MORB型榴辉岩的岩石地球化学特征

松多榴辉岩的SiO2、Al2O3含量分别为45.3%～50.6%、12.93%～14.27%,K2O+Na2O为1.3%～2.8%,TFeO/MgO为1.11～2.02,CaO为10.4%～14.47%,K2O<0.3%,Na2O为0.97%～2.47%。总体上具有玄武质或辉长质岩石的成分特征,属于钙碱性系列,具有MORB的特征,表明其原岩来自大洋环境。松多榴辉岩大多数样品的稀土元素配分模式显示轻稀土元素亏损,无明显的Eu异常,重稀土元素平坦。微量元素蛛网图均显示从Zr到Yb属于平坦型,基本上未发生分馏。松多榴辉岩的LaN/YbN比值为0.19～0.56,LaN/CeN为0.75～0.81,LaN/SmN为0.37～0.81,三者均小于1;Hf/Th除了石英榴辉岩中的06Y-344样品为6.81外,其他样品为11.10～33.97,均大于8;Ce/Nb为2.72～19.02,均大于2;Th/Yb为0.01～0.10,均小于或等于0.1,也说明其原岩具有典型MORB的特征。锆石SHRIMPU-Pb定年获得松多榴辉岩的变质年龄为261Ma±5.3Ma,推测其原岩可能为古特提斯洋盆的残留。

西藏松多地区早侏罗世变质辉长岩的成因及其构造意义

冈底斯岩浆岩带中东部松多地区新发现的变质辉长岩对于讨论松多古特提斯洋演化历史具有重要约束意义。在详细野外地质调查基础上,本文报道了松多变质辉长岩的LA-ICP-MS锆石U-Pb年龄、锆石Hf同位素成分分析和全岩地球化学组成,并探讨了岩石的成因及其对松多古特提斯洋构造演化的启示。结果表明,松多变质辉长岩原岩形成于195±6Ma^202±2Ma之间;Si O2含量为45. 56%~53. 69%,MgO含量较高为6. 04%~11. 75%,Mg#为66~77;高Cr(209×10-6~746×10-6)和Ni(80×10-6~234×10-6)含量。该岩石富集轻稀土元素,平滑右倾的稀土配分模式介于E-MORB和OIB之间;富集大离子亲石元素和Nb、Ta等高场强元素;具有较低的(La/Yb)N=2. 06~4. 81、(La/Sm)N=1. 50~2. 48、(Gd/Yb)N=1. 21~1. 67和(Ce/Y)N<2。锆石εHf(t)值为-1. 9~3. 9,具相对古老Hf模式年龄(988~1361Ma)。综合对区域地质、年代学、岩石地球化学以及锆石Hf同位素等资料的全面分析,认为松多早侏罗世变质辉长岩原岩的岩浆可能起源于下地壳改造的亏损岩石圈地幔的部分熔融,形成于松多古特提斯洋壳板片断离事件所引发岩石圈减薄的伸展构造背景。

拉萨地块松多榴辉岩的变质演化过程：NCKMnFMASHTO体系中的相平衡关系

拉萨地块松多榴辉岩主要矿物组合为石榴子石、绿辉石、角闪石、多硅白云母、绿帘石、金红石。石榴子石环带不明显,核部成分均一,从核部到边部,镁铝榴石和钙铝榴石含量降低,可能分别记录了榴辉岩峰期及退变质过程信息。绿辉石显示微弱的成分环带,硬玉含量从核部到边部略有升高,部分绿辉石边部发育韭闪石退变质边,反映了在减压过程中外来流体进入体系的过程。多硅白云母具有高的Si含量（3.5~3.6）,其中石榴石包体中的多硅白云母相对基质中的白云母有更高的Si值。本文利用Thermocalc变质相平衡模拟软件,结合详细岩相学观察,在NCKMn FMASHTO体系下,模拟松多含多硅白云母榴辉岩的变质演化过程。其中,榴辉岩峰期矿物组合为g＋o＋law＋phn＋ru,石榴石核部最大镁铝榴石值和石榴子石包体中多硅白云母最大Si值确定的榴辉岩峰期温压条件约为620℃,32×105Pa,榴辉岩经历了近等温降压的退变质过程。相平衡模拟结果表明拉萨地块松多榴辉岩经历了超高压变质作用过程,并经历了相对快速的折返过程到中部地壳层次。

西藏松多榴辉岩变质作用研究

西藏拉萨地块松多附近新发现一条榴辉岩带,长约100 km,宽约2-3 km。松多榴辉岩主要经历了进变质的绿帘石榴辉岩相—峰期的榴辉岩相—退变质的角闪岩相3个阶段。岩石学研究表明,峰期的特征矿物组合是石榴子石-绿辉石-多硅白云母-金红石,峰期温压条件是760-800℃,3.3-3.9 GPa。这表明松多地区可能曾经历超高压变质作用,之后快速返回,p-T轨迹呈＂发卡＂状,后期退变质经历了角闪石榴辉岩相阶段。研究松多榴辉岩表明,拉萨地块内部有一条新的缝合带,这对于了解拉萨地块和古特提斯洋的演化有重要意义。

拉萨地块松多超高压变质带含石榴石云母石英片岩的变质演化相平衡模拟

拉萨地块松多超高压变质带含石榴石白云母石英片岩为榴辉岩的围岩,岩石的矿物组合为石榴石、白云母、钠长石、绿泥石、石英及少量金红石、榍石。石榴石具有明显的成分环带,从核部到幔部Xprp=[Mg/(Mg+Fe+Mn+Ca)]缓慢升高,Xsps=[Mn/(Mg+Fe+Mn+Ca)]逐渐降低,表明石榴石从核部到幔部的成分记录了温度逐渐升高的进变质过程;幔部到边部,Xprp=[Mg/(Mg+Fe+Mn+Ca)]略微降低,Xgrs=[Ca/(Mg+Fe+Mn+Ca)]明显升高,Xsps=[Mn/(Mg+Fe+Mn+Ca)]先升高后降低,表明石榴石边部成分受到了退变质作用改造,呈现扩散环带的特征。利用Thermocalc变质相平衡计算软件在Mn NCKFMASHO体系下计算出含石榴石云母石英片岩的P-T、P-M(H2O)视剖面图,结合石榴石镁铝榴石等值线、钙铝榴石等值线及饱和水含量等值线限定出含石榴石云母石英片岩的峰期变质条件为约27×105k Pa,523/580℃,对应的峰期矿物组合为(g-Jd-Cr-Law(+Phn+q/Coe+H2O)。石榴石核部到幔部成分记录了主要的进变质演化,结合饱和水等值线的变化,判断进变质阶段为升温升压的冷俯冲过程,岩石经历了蓝片岩相至榴辉岩相的变质演化;P-M(H2O)视剖面图及饱和水等值线反映了岩石在减压中的流体行为,通过其变化特征可以确定岩石在峰期之后先经历近等温降压的早期退变质过程,晚期降温降压的退变轨迹则由石榴石边部成分所确定,此过程中,岩石发生了角闪岩相至绿帘角闪岩相变质,并在后期经历了绿片岩相变质叠加。近等温降压的退变质过程反映了快速抬升的构造运动过程,早期硬玉转变为钠长石可能发生在这个阶段。对比含石榴石云母石英片岩与榴辉岩的P-T轨迹,峰期变质温压及变质演化特征,提出含石榴石云母石英片岩曾经历过高压变质,结合野外相互伴生的地质关系,认为该片岩与榴辉岩经历了相同或者相似的俯冲折返过程。

青藏高原新特提斯蛇绿岩的地质特征及其构造演化

西藏雅鲁藏布江缝合带(YZSZ)和班公湖-怒江缝合带(BNSZ)蛇绿岩代表了新特提斯洋壳和岩石圈地幔残余,是我国铬铁矿和蛇绿岩型金刚石的重要原产地,目前这两条蛇绿岩带的成因和相互关系还存在着争论。本文总结了YZSZ、BNSZ、狮泉河-纳木错蛇绿混杂岩带(SNMZ)和松多缝合带蛇绿岩的时空分布、组成和构造背景,归纳了拉萨地块晚古生以来的岩浆岩分布,获得以下主要认识:(1) Panjal地幔柱活动可能促使怒江洋和雅江西洋在早二叠世空谷期(283~272Ma)打开;(2)雅江东洋由于松多洋的南向俯冲在晚三叠世打开,与雅江西洋以萨嘎-措勤为界,并形成冈底斯东部245~200Ma岩浆热事件;(3)~140Ma班怒洋闭合以及南羌塘与北拉萨地块碰撞,导致雅江洋扩张速率加快而引发了北向拉萨地块的平板俯冲,进而导致班怒洋的再次裂解形成133~104Ma"红海型"小洋盆;(4) YZSZ缝合带西段南带蛇绿岩为北带的逆冲推覆体;(5) BNSZ和SNMZ蛇绿岩隶属于一个洋盆,后者代表了班怒洋成熟洋盆扩张脊的残余。

西藏松多地区首次发现非金属矿——黑曜岩

最新区域地质调查发现,西藏工布江达县松多乡存在天然非金属矿——黑曜岩。该矿源地处青藏高原冈底斯板块上,发育于新生代年波组中。"球泡"状黑曜石清晰可见,部分达到宝石级别。初步研究显示,该黑曜岩是地壳部分熔融的产物。冈底斯成矿带上成矿种类以多金属为主,松多黑曜岩的发现不仅初步圈定了一个非金属矿点,还为区域后续找矿工作和考古学研究提供了重要线索。

青藏高原陆相火山岩区填图新进展——以松多地区新生代火山机构为例

20世纪90年代以来,为了区别传统的沉积岩区填图方法,中国陆相火山岩区地质调查工作普遍采用"火山构造-火山岩相-火山岩性"三位一体的思路与工作方法,并取得重要进展。以西藏松多地区1∶5万区域地质调查工作为例,探讨该方法在高原地区新生代火山岩研究中的应用。结合遥感影像与剖面测制,通过野外地质观察与镜下岩性特征分析,对火山机构进行相带划分,从而恢复古火山的基本格架、重溯火山作用过程。同时,松多地区新生代火山机构的建立,为冈底斯岩浆带发育的林子宗火山岩与下伏地层的区域性不整合提供了新的证据,进一步限定了印度-亚洲大陆碰撞的起始时间。

西藏松多地区超基性岩地球化学特征及对松多古特提斯洋演化的启示

唐加-松多古特提斯缝合带的提出改变了地学界对青藏高原古特提斯演化格局的认识。为进一步约束唐加-松多古特提斯缝合带中蛇绿岩的岩石成因及类型,以松多地区的超基性岩为研究对象,对其进行了岩石学和全岩地球化学研究。结果显示,松多地区超基性岩与原始地幔相比具有较高的MgO和TFe_(2)O_(3)含量,以及较低的Al_(2)O_(3)和TiO_(2)含量。样品稀土元素总含量介于4.04×10^(-6)~9.31×10^(-6)之间,大部分低于原始地幔值。稀土元素配分曲线呈较宽缓的“U”型,轻稀土元素较富集。微量元素分布形式与全球深海橄榄岩的微量元素分布形式基本一致,具有明显的Th、Nb负异常,大部分样品具有轻微的Zr、Hf负异常。定量模拟估算表明,研究区超基性岩主要为尖晶石二辉橄榄岩地幔批式熔融后的难熔残留体,熔融程度大于25%,并具一定程度石榴子石相熔融的特征,未受到后期岩石-熔体反应的改造,其原岩应为亏损的深海橄榄岩。结合区域研究成果,松多地区超基性岩可能形成于大洋中脊(MOR)环境,为典型的大洋中脊玄武岩(MORB)型蛇绿岩端元之一。

早侏罗世新特提斯洋俯冲作用——来自松多高镁闪长岩锆石U-Pb定年及Hf同位素的制约

冈底斯岩浆岩带中东部松多地区新发现的高镁闪长岩对于探讨青藏高原新特提斯俯冲演化历史具有重要意义。通过松多高镁闪长岩的LA-ICP-MS锆石U-Pb年龄、锆石Hf同位素和全岩地球化学组成的研究,表明松多闪长岩的锆石U-Pb年龄加权平均值为186.8±1.3Ma。该类岩石具有高硅、高镁的特点,Si O2含量为54.17%~58.81%,Mg O含量较高,介于6.26%~7.29%之间,Mg~#值介于64~67之间,Cr和Ni含量高。该岩石富集轻稀土元素,具有平滑右倾的稀土元素配分曲线及弱负Eu异常。富集Rb、Ba、Pb、K等大离子亲石元素,亏损Nb、Ta、Ti等高场强元素。锆石负εHf(t)值(-5^-14.3)及远大于其侵入年龄的古老Hf模式年龄(1543~2129Ma),揭示松多早侏罗世闪长岩经历了古老地壳物质的部分熔融。Sr/Y-Y和(La/Yb)N-YbN判别图解显示,其形成可能与赞岐岩的岩浆作用过程相似,形成于消减带之上的地幔楔环境。综合研究表明,松多地区在早侏罗世处于雅鲁藏布新特提斯洋板片向欧亚大陆俯冲的活动陆缘构造背景。

西藏松多地区晚白垩世末期弧岩浆岩岩石成因及构造意义

新特提斯洋在晚白垩世末期(68Ma左右)的构造演化一直饱受争议。西藏松多地区晚白垩世末期弧岩浆岩包括花岗斑岩和二长花岗岩。锆石定年结果显示,二长花岗岩和花岗斑岩年龄均为68Ma。松多花岗斑岩和二长花岗岩的Si O_2含量为68.5%~80.6%,K_2O含量为4.1%~6.5%,P2O5含量为0.011%~0.058%。花岗斑岩Mg#值较低,为11.3~19.0,二长花岗岩Mg~#值为24.2~43.5。花岗斑岩和二长花岗岩样品均显示轻稀土元素富集、重稀土元素亏损和明显的Eu(δEu=0.15~1.21)负异常。两者均富集大离子亲石元素Rb、Th、U、K、Pb等,亏损高场强元素Nb、Ta、Ti。花岗斑岩εHf(t)值为-0.9^+2.9,二阶段模式年龄T_(DM)~C在955~1196Ma之间;二长花岗岩εHf(t)值为-17.1^+7.9(只有1个点为负值),二阶段模式年龄在633~2219Ma之间。最终认为,松多地区晚白垩世末期二长花岗岩和花岗斑岩岩浆源区为新生下地壳,但花岗斑岩更靠近古老下地壳。结合区域资料,认为新特提斯洋在晚白垩世末期68Ma左右属于洋脊俯冲结束阶段。

西藏唐加地区卓隆普斜长角闪岩锆石U-Pb年代学、地球化学及地质意义

本文以西藏唐加地区卓隆普斜长角闪岩为研究对象,通过岩相学、锆石U-Pb年代学和全岩地球化学组成分析,探讨了其岩石成因以及对松多古特提斯洋演化的地质意义。结果显示,卓隆普斜长角闪岩原岩形成于264.7±1.3 Ma(n=28,MSWD=0.88),属中二叠世。全岩地球化学特征显示该套岩石呈钙碱性,富集轻稀土元素(LREE/HREE=4.69~4.88),弱铕异常(δEu=0.81);样品富集大离子亲石元素(LILEs),具有强烈的Nb-Ta负异常,表现出岛弧玄武岩亲缘性。多种判别图解显示斜长角闪岩原岩形成于俯冲相关的岛弧环境,原岩岩浆由俯冲大洋板片和洋壳物质融熔体以及其脱水过程中形成的俯冲流体交代上覆地幔楔形成,岩浆上升过程中可能受到轻微的地壳物质混染。结合区域资料,本次研究认为唐加-松多古特提斯洋在265 Ma(中二叠世)之前已经发生俯冲。