碎屑锆石年龄和Nd-Hf同位素组成对扬子基底演化的制约

The South China craton was formed by the collision of the Yangtze and Cathaysia blocks during the Neoproterozoic Jiangnan orogeny (also termed as the Jingnin or Sibao orogeny in Chinese literature). Basement rocks within the Yangtze block consist mainly of Proterozoic sediments of the Lengjiaxi and Banxi Groups. U-Pb ages of detrital zircons obtained by the LA-ICP-MS dating technique imply that the deposition of the Lengjiaxi Group continued until the Neoproterozoic. The youngest detrital zircons suggest a maximum deposition age of ~830 Ma for the Lengjiaxi Group, consistent with the initiation time of the deposition of the overlying Banxi Group, likely indicating continuous deposition of these two groups and a short temporal hiatus (~10 Ma) between the Neoproterozoic sedimentary rocks distributed in the South China craton. Detrital zircons from both the Lengjiaxi and Banxi Groups have a wide range of εHf(t) values from -12 to 14.2 and a continuous Nd and Hf model age spectrum from ~820 Ma to 2200 Ma. Some grains have model ages ranging up to ca. 2.9-3.5 Ga, indicating that both juvenile mantle material and ancient crust provided sedimentary detritus. This is also consistent with the Nd isotopic signature of sedimentary rocks recorded in the Lengjiaxi Group, suggesting a back-arc tectonic setting. The Banxi Group has slightly enriched Nd isotopic signatures relative to the Lengjiaxi Group, implying a higher percentage of old continental material in the sedimentary source. Combined with previously published data, new results can help us to reconstruct the Neoproterozoic tectonic evolution of the South China craton. The age spectrum of detrital zircons and Nd-Hf isotopic composition suggests a two-stage collision: Between 1000 Ma to 870 Ma, a continental magmatic arc was build up along the eastern margin of the Yangtze block. Convergence led to continent-based back-arc extension, subsidence and formation of a back-arc basin. Detritus originating from arc-related magmatic and old basement rocks was transported into this back-arc basin resulting in formation of the Lengjiaxi Group and its equivalents. At around 870 Ma, a second (oceanic) arc was formed by extension of an inter-arc basin, subduction subsequently led to the first collision and the emplacement of the blueschist mélange. Accretion of the magmatic arc lasted until the closure of an oceanic basin between the Yangtze and Cathaysia blocks at about 830 Ma. Shortly after the collision, subsequent uplift, further extension of the former back-arc basin and post-collisional granitoid magmatism caused a tilting of the Lengjiaxi sediments. Between 830 Ma and 820 Ma, subsequent closure of the oceanic back-arc basin and formation of the Jiangnan orogen took place, leaving a regional unconformity above the Lengjiaxi Group. Above this unconformity the Banxi Group was immediately deposited during the post-tectonic stage.

特提斯喜马拉雅带晚白垩世-始新世沉积源区分析及其构造意义

Tethyan Himalayan Sequence (THS) is located at the frontier of the India-Asia collision zone, which can preserve critical information about collision. This paper reports detailed petrology, geochemistry, spinels electron microprobe data, and in situ U-Pb ages and Lu-Hf isotopic data on detrital zircons from the late Cretaceous to early Eocene strata in Gyantze and Gamba area, south Tibet that provide important constraints on the early tectonic evolution of the India-Asia collision. In Gyantze, the lithic arkose in Zongzhuo mélange is characterized by, SiO2 =80.4%, Al2O3=8.6%, Na2O=1.6%, K2O=1.1%, LaN/YbN=8.90, and εNd (0) =-10.27. Spinels compositions are characterized by low TiO2 (generally <0.1%) and a Cr number mainly between 70 and 80. The largest population of detrital zircons is within the 73-169Ma range with high εHf (t) and > 500 Ma with complex εHf (t) values. The lithic arkose in Rilang conglomerate is characterized by, SiO2 =56.5%, Al2O3=15.6%, Na2O=4.7%, K2O=0.6%, LaN/YbN=5.00-5.29, and εNd (0) =1.92. Spinels of 2006T98 display high TiO2 (generally >0.2%) and a Cr number mainly between 70 and 85, other spinels are characterized by low TiO2 (generally <0.2%) and a Cr number mainly between 60 and 90. The largest population of detrital zircons is within 90-146 Ma range with high εHf (t). The lithic arkose in Jiachala formation is characterized by, SiO2 =64.6%, Al2O3=12.1%, Na2O=1.9%, K2O=1.8%, LaN/YbN=7.73-9.13, and εNd (0) =-5.52~-8.43. Spinels in the Jiachala formation have low TiO2 (generally <0.2%) and a Cr number between 39 and 88. Detrital zircons have a wide range of age distribution of 82-3165Ma with complex εHf (t). In Gamba, The quartze sandstone in Jidula formation is characterized by, SiO2=97.4%, Al2O3=0.9%, Na2O=0.03%, K2O=0.18%, LaN/YbN=18.70-21.684, and εNd (0) between -13.1~-7.4. While the lithic arkose in Zhepure formation is characterized by, SiO2=68.4%, Al2O3=7.3%, Na2O=1.15%, K2O=0.52%, LaN/YbN=6.09-8.99, and εNd(0)=-5.8~-6.3. Based on our geochemical analysis, spinles electron microprobe data, U–Pb ages and Hf isotope data for detrital zircons of the late Cretaceous-Eocene strata in Gyantze and Gamba, southern Tibet, the following major conclusions can be drawn: 1. In Gyantze, the Zongzhuo mélange was mainly derived from accretionary prism/THS of continental slop and Gangdese arc. Rilang conglomerate was totally from Gangdese arc. The Jiachala formation was derived from THS, suture zone and Gangdese arc. 2. In Gamba, the Jidula formation was from India craton, while the Zhepure formation was derived from THS, suture zone and Gangdese arc. 3. The deposite of Zongzhuo mélange and Rilang conglomerate (73-55Ma) marks the collision between India and Asia. 4. Late Paleocene-Eocene tectonic evolution is consistent with foreland basin system.

东喜马拉雅构造结新生代碰撞变形与岩石圈演化

The Eastern Himalayan Syntaxis (EHS) is one of the strongest deformation area along the Himalayan belt resulted from the collision between Indian plate and the Eurasian Plate since the 50～60Ma, and has sensitivity tracked and preserved the whole collisional processes. It should depend on the detail geological investigations to establish the deformational accommodate mode, and the uplift history, to elucidate the deep structure and the crust-mantle interaction of the Tibet Plateau of the EHS. The deep-seated (Main Mantle Thrusts) structures were exhumed in the EHS. The MMT juxtapose the Gangdese metamorphic basement and some relic of Gangdese mantle on the high Himalayan crystalline series. The Namjagbawa group which is 1200～1500Ma dated by U/Pb age of zircon and the Namla group which is 550Ma dated by U/Pb age of zircon is belong to High Himalayan crystalline series and Gangdese basement respectively. There is some ophiolitic relic along the MMT, such as metamorphic ocean mantle peridotite and metamorphic tholeiite of the upper part of ocean-crust. The metamorphic ocean mantle peridotites (spinel-orthopyroxene peridotite) show U type REE patterns. The ~(87)Sr/~(86)Sr ratios were, 0.709314～0.720788, and the ~(143)Nd/~(144)Nd ratios were 0.512073～0.512395, plotting in the forth quadrant on the ~(87)Sr/~(86)Sr-~(143)Nd/~(144)Nd isotope diagram. Some metamorphic basalt (garnet amphibolite) enclosures have been found in the HP garnet-kynite granulite. The garnet amphibolites can be divided two groups, the first group is deplete of LREE, and the second group is flat or rich LREE, and their ~(87)Sr/~(86)Sr, ~(143)Nd/~(144)Nd ratios were 0.70563～0.705381 and 0.512468～0.51263 respectively. Trace element and isotopic characteristics of the garnet amphibolites display that they formed in the E-MORB environment. Some phlogolite amphibole harzburgites, which exhibit extensive replacement by Phl, Amp, Tc and Dol etc, were exhumed along the MMT. The Phl-Amp harzburgites are rich in LREE and LILE, such as Rb, K etc, and depletes Eu (Eu~* = 0.36 ～ 0.68) and HFSE, such as Nb, Ta, Zr, Hf, P, Ti etc. The trace element indicate that the Phl-Amp harzburgites have island arc signature. Their ~(87)Sr/~(86)Sr are varied from 0.708912 to 0.879839, ~(143)Nd/~(144)Nd from 0.511993 to 0.512164, ε Nd from- 9.2 to - 12.6. Rb/Sr isochrone age of the phlogolite amphibole harzburgite shows the metasomatism took place at 41Ma, and the Amp ~(40)Ar/~(39)Ar cooling age indcate the Phl-Amp harzburgite raising at 16Ma. There is an intense crust shortening resulted from the thrust faults and folds in the Cayu block which is shortened more 120km than that of the Lasha block in 35～90Ma. With the NE corner of the India plate squash into the Gangdese arc, the sinistral Pai shear fault and the dextral Aniqiao shear fault on the both sides of the Great bent of Yalun Zangbu river come into active in 21～26Ma. On the other hand, the right-lateral Gongrigabu strike-slip faults come into activity at the same period, a lower age bound for the Gongrigabu strike-slip fault is estimated to be 23～24Ma from zircon of ion-probe U/Pb thermochronology. The Gongrigabu strike-slip faults connect with the Lhari strike-slip fault in the northwestern direction and with the Saganing strike-slip at the southeastern direction. Another important structure in the EHS is the Gangdese detachment fault system (GDS) which occurs between the sedimental cover and the metamorphic basement. The lower age of the GDS is to be 16Ma from the preliminary 40Ar/39Ar thermochronology of white mica. The GDS is thought to be related to the reverse of the subducted Indian crust and the fast uplift of the EHS. Structural and thermochronology investigation of the EHS suggest that the eastern Tibet and the western Yunnan rotated clockwise around the EHS in the period of 35～60Ma. Later, the large-scale strike-slip faults (RRD, Gaoligong and Saganing fault) prolongate into the EHS, and connect with the Guyu fault and Gongrigabu fault, which suggest that the Indianchia block escape along these faults. Two kind of magmatic rocks in the EHS have been investigated, one is the mantle-derived amphibole gabbro, dioposide diorite and amphibole diorite, another is crust origin biotit-garnet adamellite, biotit-garnet granodiorite and garnet-amphibole-biotite granite. The amphibole gabbro dioposite diorite and amphibole diorite are rich in LREE, and LILE, such as Ba, Rb, Th, K, Sr etc, depleted in HFSE, such as Nb, Ta, Zr, Hf, Ti etc. The ratio of ~(87)Sr/~(86)Sr are from 0.7044 to 0.7048, ~(143)Nd/~(144)Nd are from 0.5126 to 0.5127. The age of the mantle origin magamatic rocks, which result from the partial melt of the raising and decompression anthenosphere, is 8Ma by ~(40)Ar/~(39)Ar dating of amphibole from the diorite. The later crust origin biotite-garnet adamellite, biotite-garnet granodiorite and garnet-amphibole-biotite granite are characterized by aboudance in LREE, and strong depletion of Eu. The ratios of ~(87)Sr-~(86)Sr are from 0.795035 to 0.812028, ~(143)Nd/~(144)Nd from 0.51187 to 0.511901. The ~(40)Ar/~(39)Ar plateau age of the amphibole from the garnet-amphibole-biotite granite is 17.5±0.3Ma, and the isochrone age is 16.8±0.6Ma. Their geochemical characteristics show that the crust-derived magmatic rocks formed from partial melting of the lower curst in the post-collisional environment. A group of high-pressure kaynite-garnet granulites and enclave of high-pressure garnet-clinopyroxene grnulites and calc-silicate grnulites are outcroped along the MMT. The peak metamorphic condition of the high-pressure granulites yields T=800～960 ℃, P=1.4～1.8Gpa, corresponding the condition of 60km depth. The retrograde assemblages of the high-pressure grnulites occur at the condition of T=772.3～803.3 ℃, P=0.63～0.64Gpa. The age of the peak metamorphic assemblages are 45 ～ 69Ma indicated by the zircon U/Pb ion-plobe thermochronology, and the retrograde assemblage ages are 13～26Ma by U/Pb, ~(40)Ar/~(39)Ar thermochronology. The ITD paths of the high-pressure granulites show that they were generated during the tectonic thickening and more rapid tectonic exhumation caused by the subducting of the Indian plate and subsequent break-off of the subducted slab. A great deal of apatite, zircon and sphene fission-track ages, isotopic thermochronology of the rocks in the EHS show that its rapid raising processes of the EHS can be divided into three main periods. There are 35～60Ma, 13～25Ma, 0～3Ma. 3Ma is a turn in the course of raising in the EHS which is characterized by abruptly acceleration of uplifting. The uplift ratios are lower than 1mm .a~(-1) before 3Ma, and higher than 1mm .a~(-1) with a maximum ratio of 30mm .a~(-1) since 3Ma. The bottom (knick point) of the partial anneal belt is 3.8km above sea level in the EHS, and correspond to age of 3Ma determined by fission-track age of apatite. The average uplift ratio is about 1.4 mm .a~(-1) below the knick point. The EHS has raised 4.3km from the surface of 2.36km above sea level since 3Ma estimated by the fossil partial anneal belt of the EHS. We propose a two-stage subduction model (B+A model) basing on Structural, thermochronological, magmatical, metamorphic and geophysical investigations of the EHS. The first stage is the subduction of the Indian continental margin following after the subduction of the Tethys Ocean crust and subsequent collision with the Gangdese arc, and the second stage is the Indian crust injecting into the lower crust and upper mantle of the Tibet plateau. Slab break-off seems to be occurred between these two stages.

北祁连与块状硫化物矿床有关的早古生代火山岩的地球化学研究

Different conclusions from previous work are made from the geochemical study for the early Paleozoic volcanic rocks hosting massive sulfide deposits in the north Qilian Orogen. The main points are: (1)The geochemical characteristics of the basalts and rhyolites from the Baiyin deposit are not consistent with that of the volcanic rocks in the continental rift setting, but show the relationship with subduction. The basalts and rhyolites from the Baiyin deposit are probably individual tectonic slice piled by subduction, and there is no bimodal volcanic rock suite occurred in the Baiyin deposit. Zircon U-Pb dating constrains the magmatic emplacement of basalts and rhyolites at 475±10Ma and 453±12Ma, respectively. The basalts are characterized by enriched Th and Sr, and depleted Nb, Ta and Ti. They have relatively high Th/Nb ratios between 0.9 and 1.3. Their εNd(T) values vary from -1.2 to +3.4. The chemical and isotopic compositions display a typical subduction-related signature, and they suggest that an enriched component with the isotopic composition of EMII might have contributed to the generation of the Baiyin basalts. The basalts were likely formed in a mature island-arc or a volcanic arc built on comparatively young or thin continental crust in an active continental margin. The rhyoIites have low concentrations of LILE compared to the basalts. They do not seen to have a relationship with the basalts, because of their significantly higher εNd(T) values (+4.3～+7.7). The high and positive εNd(T) values also rule out their derivation from anatexis of the continental crust. A modeling study suggests that the source.of the Zhe-Huo and Xiaotieshan rhyolites is similar to boninite and IAT (island-arc tholeiite), and hence indicating an intra-oceanic arc environment. (2) The formation of the Shangliugou volcanic rocks from .Qilian area is also related to subduction. The basaltic andesite have low TiO_2(0.45～0.63%) and P_2O_5(0.04～0.09) content, and high Th/Nb ratios (0.3～0.6). They show flat REE patterns. Their εNd(T) values vary in a narrow range from +4.8 to +6.4. The chemical and isotopic compositions indicate that they are derived from a slightly depleted mantle source and are fromed in intra-island arc setting. The rhyolites show calc-alkaline trend. They show enriched LREE and fiat HREE patterns with obvious negative Eu anomaly. They have high Th/Ta ratios (5.0 ～ 11.7) and large negative εNd(T) values (-2.6 ～ -8.4). The rhyolites are formed in active continental margin and result from a mixed process of two endmembers, or crust assimilation. (3) The metal elements of the volcanic-hosted massive sulfide deposit have two sources, the copper and zinc are derived from rhyolitic magmas whereas the lead are probably related to old sediments overlying the rhyolites. (4) It is suggested here that the volcanic rocks hosting massive sulfide deposit in the north Qilian orogen, which are previously considered as a bimodal suite of Neo-proterozoic to middle Cambrian age in a continental rift, are virtually related to subduction magmatism in Ordovician age, and there might have no continental rift magmatism of Neo-proterozoic to middle Cambrian in the north Qilian.

论金矿床成矿年代的研究——以丹东地区成岩成矿Rb—Sr、U—Pb同位素年代为例

丹东地区是中国重要的金矿集中区，到目前为止还没有较准确的成岩成矿年代学数据。本文采用Rb-Sr等时线法和单颗粒锆石U-Pb法分别测出了丹东三股流花岗岩成岩年龄为131±5Ma和129±3Ma。五龙金矿主成矿阶段石英流体包裹体Rb-Sr等时线年龄为120±3Ma。这一组年龄数据理顺了该地区构造-岩浆-成矿的时序关系，对中国东部金矿成矿对比研究提供了有效的年龄数据。

锆石的成因和U—Pb同位素定年的某些进展

锆石是岩浆岩，变质岩，沉积岩和月岩中最重要的副矿物，本文分别从锆石的形态，以及影响锆石形态的因素，锆石的主量，微量，稀土元素地球化学和氧同位素特征等方面进行系统综述，同时，论述了目前国内外有关锆石U－Pb法定年的研究进展，并对各种方法的局限性加以总结。

内蒙古白云鄂博矿区元古代非造山岩浆岩及其对成矿的制约

白云鄂博矿区广泛分布着元古代非造山岩浆岩.主要岩性是粗面岩、镁铁钠闪石-长石岩、钾质流纹岩、英安岩、流纹岩、石英斑岩和中长玄武岩,并有大量高钾辉绿岩脉(墙)出露.这些非造山岩浆岩来源于地幔,它们的ε_(Sr)(t)值都较低,ε_(Nd)(t)主要集中在4.52～5.88,钕模式年龄T_(DM)~(Nd)集中在1.54～1.92 Ga.它们的Nd同位素组成和钕模式年龄都与矿石一致,意味着成矿物质来源于这些岩浆岩.这些岩浆岩的锆石U-Pb年龄为1.8 Ga年左右.各种研究结果表明矿床是与非造山岩浆岩有关的热液交代白云鄂博群的产物.

硒、锌同位素MC-ICP-MS分析方法研究及其在生物和环境样品中的应用

一定元素的同位素组成被认为是该元素特有的“指纹”，同位素组成测量是地球化学、生命科学、环境化学、地质科学和核科学等领域重要的研究手段。利用同位素技术开展生命过程，地球系统中的物理、化学、生物过程及其资源、环境与灾害效应，资源勘探，污染物溯源等方面的研究，既是该技术的前沿研究主题，也使相关领域的研究更加“精细量化”，从而在新的科学纵深揭示出更加清晰的规律。 1992年多接收电感耦合等离子体质谱仪(MC-ICP-MS)的问世，为同位素分析提供了一种强有力的技术手段，与传统的热电离同位素质谱相比，MC-ICP-MS具有测量速度快、操作简便、灵敏度高等优点。而且，由于等离子体源产生的高温，在理论上能测量所有的金属元素和一些非金属元素，并已很好地解决了一些高电离电位元素同位素测量的难题（如Se, Zn, Hf等），用MC-ICP-MS准确、精密测量各种元素同位素组成的方法正在逐渐得到发展和完善。目前，MC-ICP-MS比较成熟的方法主要是针对核和地质科学研究中应用较多的U, Pb, Sm, Nd, Sr, Hf, B, Li等，在硒和锌同位素测量方法学的研究还相对较少（尤其是硒），对一些测量中受各种干扰较为严重的、原子量小于80 的元素同位素的测量技术还有待进一步深入探索和研究。锌、硒元素不仅与人类健康息息相关，而且随着质谱分析技术的发展，使其在环境地球化学、生命科学等领域有着广泛的应用前景。准确测量生物、食品、环境、地质等样品中的锌、硒元素含量、各种形态及其同位素组成受到越来越多的关注。锌、硒同位素准确测量的方法学研究，不仅可以广泛应用于各相关领域，也为锌和硒同位素基、标准物质研制奠定技术基础，从而为锌、硒元素含量和同位素测量提供量值溯源保障。 本工作针对锌和硒元素同位素组成以及生物、环境等样品中成分量准确测量存在的问题，通过使用六极杆碰撞室MC-ICP-MS进行准确测量锌和硒元素同位素的技术研究，结合在化学计量研究中的长期实践及相关文献，从方法学角度和应用方面得出以下结论： 1.MC-ICP-MS仪器测量主要参数，如炬管轴向位置、载气流量、碰撞气流量、仪器稳定性等对测量结果影响很大，要获得高精度的测量结果，须优化和固定参数设置，保持仪器的稳定状态。在六极杆碰撞室MC-ICP-MS测量锌同位素时，高纯氩气碰撞气模式是较为理想的模式，64Zn/66Zn、67Zn/66Zn、68Zn/66Zn同位素丰度比测量精度达到0.002－0.008％，70Zn/66Zn 测量精度达到0.01％；在高纯氢气和氩气碰撞气按一定比例混合的模式下， 76Se/80Se、77Se/80Se、78Se/80Se、82Se/80Se同位素丰度比测量精度达到0.004－0.005%。 2.采用高纯、高浓缩64Zn和66Zn配制了8个校正样品 (64Zn/66Zn：0.6－2.2)；用高纯、高浓缩同位素76Se和82Se配制了16个校正样品（76Se/82Se： 0.05－11.8），用这些样品分别测量并计算了仪器系统误差校正系数K，这些校正样品的K64/66 和 K76/82的相对标准偏差分别为0.034％和0.03％，均在仪器的测量不确定度范围内，说明在校正样品同位素变化范围内，仪器测量同位素丰度比的校正系数没有发生明显变化。 3.在硒同位素丰度比值测量中，氢气碰撞气的使用是SeH产生的重要原因之一，Ar/H在2－7之间都可以满足硒同位素比值测量的要求，即保证较高的硒灵敏度、较小的SeH生成比例、稳定的同位素比值测量结果。本工作建立了SeH的校正计算公式，在对测量结果的质量歧视进行校正时，77Se和78Se的校正更为复杂，因为它们除自身产生的SeH外，还分别受到了来自76SeH和77SeH的影响，故校正质量偏移时应首先对SeH进行校正。对于不同的SeH生成比例，经过校正后，硒的同位素丰度比校正值是一致的，并不受SeH生成比例变化影响。 4.通过对IDMS过程中的关键技术研究，明确了如何正确使用该方法以获得准确测量结果。IDMS方法在测量步骤中引入的不确定度影响因素相对于其它化学分析方法较少，并且可以被明确地表达出来，测量结果可直接溯源到国际单位，因此，该方法对化学计量学研究具有十分重要的意义。 5.建立了适用于ICP-MS测量血清、大豆粉、金枪鱼等多种复杂基体中锌和硒元素的样品前处理方法，建立了锌和硒的ICP-IDMS测量方法。将建立的方法应用于人血清标准物质研制、国家计量院之间的国际比对和合作研究中，取得的优异成绩验证了所建方法的可靠性和可比性。IDMS方法在样品前处理上不怕样品损失和高精度同位素丰度比测量的优点，使其在复杂基体中硒、锌的准确测量方面较其它分析方法具有独特的优势，可在生物、临床、环境、食品等方面的分析研究中广泛应用。

滇东南老君山变质核杂岩地球化学和年代学初步研究

本文通过对滇东南老君山变质核杂岩各组成单元的地质特征、地球化学、热年代学等详细而系统的研究，得到了如下结论： （1）老君山地区存在古元古代结晶基底和中、新元古代岩浆活动，其中新元古代岩浆活动与华南（超级）地幔柱侵入、罗德里亚大陆裂解有关。 （2）南捞片麻岩与南温河花岗岩同属加里东期扬子板块与华夏板块同碰撞造山环境产物，两者同属变质泥岩、砂岩及中基性岩上壳岩部分熔融的S型花岗岩。 （3）老君山变质核杂岩基本形成时限在印支期260-160Ma，之后经历了不断隆升并在第三纪末出露剥蚀的过程。 （4）在老君山变质核杂岩韧-脆性基底拆离断层系和韧性核部剥离断层系各存在一次大规模的成矿作用，前者形成了南秧田、新寨等大型矿床，后者形成了都龙超大型矿床。时代分别为晚印支期的220-200Ma左右和晚燕山期80Ma左右。 （5）越北古陆的构造属性属于扬子和华夏板块拼贴前的华夏板块，即属于华南板块构造单元而非印支板块构造单元；Song Ma和Day Nui Con Voi剪切带之间的部分是从扬子板块西缘走滑剪切600km的杂岩体，亦非印支板块构造单元。 （6）较为详细论证了老君山地区的构造演化过程，并对滇东南泥盆纪-三叠纪末的构造演化提出了新的模式，即Song Ma古缝合线是印支板块与华南板块陆陆碰撞的残留形迹，八布蛇绿岩是大陆边缘前陆盆地局部海盆化的产物，其构造位置在俯冲期位于弧后盆地位置，在陆陆碰撞其位于前陆褶皱冲断带位置。 此外，本文还对利用都龙锡锌多金属矿床矿石中的锡石TIMS U-Pb定年方法进行了探索，确定了行之有效的锡石溶解的实验流程及方法，并首次获得都龙锡锌多金属矿床矿石中锡石TIMS U-Pb年龄为79.1±1.6Ma，证实了锡矿化主要与燕山晚期岩浆热液活动有关。

云南中甸普朗斑岩铜矿矿床地球化学

中甸格咱地区是在晚三叠世甘孜-理塘洋盆向西俯冲过程中所形成的中甸弧的主弧带，区内岛弧火山活动和岩浆侵入活动均非常强烈，广泛分布有印支期斑岩体，同时发育有众多的与其有关的斑岩型和矽卡岩型矿床或矿点。普朗斑岩铜矿就是近年来在该区发现的一个大型乃至超大型矿床，目前已圈定5个矿化体，7个工业矿体，其中，主矿体探明铜资源量436.5万吨。 本论文主要从区域地质背景、矿床地质特征、元素地球化学、同位素地球化学、流体包裹体地球化学、矿床年代学及成矿机理等角度对普朗斑岩铜矿进行了较为系统的研究，主要获得如下认识： 普朗复式岩体具明显的多次脉动侵入特征，可分为三期：第一期为大面积分布的石英闪长玢岩（部分为二长闪长玢岩），第二期为岩体中心的石英二长斑岩和花岗闪长斑岩，第三期为岩脉状闪长玢岩。岩体具有典型的斑岩铜矿蚀变分带特征，由内向外依次为强硅化带（局部）→钾化硅化带→绢英岩化带→青磐岩化带。 矿化石英二长斑岩的锆石离子探针U-Pb年龄约为226～228Ma；钾化硅化带中黑云母的40Ar-39Ar坪年龄约为210～216Ma；含矿石英脉中辉钼矿Re-Os等时线年龄约为214Ma。 普朗岩体总体显示I型花岗岩类特征，属典型的钙碱性系列岩石。锶、钕、铅同位素特征显示其岩浆源区具有幔源物质（占主要地位）与壳源物质较为均匀混合的特征。金属硫化物的硫、铅同位素特征显示成矿元素与岩体具有密切的亲缘关系。脉石矿物的氢、氧、碳同位素特征和流体包裹体特征显示成矿流体自钾化阶段至网脉状矿化阶段均具岩浆流体特征。 根据不同期次的含矿石英脉中的流体包裹体特征，主要发现有四种流体：高盐度岩浆流体（盐度：34～54wt%NaCl）、含CO2低盐度流体（盐度：2.7～6.4wt%NaCl，XCO2：0.04～0.25）、中等盐度流体（盐度：19～25wt%NaCl）以及低盐度水溶液（盐度：＜10wt%NaCl）。这些流体可能主要是原始岩浆流体演化至不同阶段的产物。 原始岩浆流体可能有两种来源：其一是斑岩侵入过程中自身分异的流体，其二是岩浆房中分异的流体。其中，岩浆房来源的岩浆流体对普朗岩体的蚀变及矿化作用起到了主导性作用。主成矿期金属硫化物的沉淀主要与流体系统开放后因其物理化学条件的变化而产生的流体相分离作用及流体对围岩的蚀变作用有关。

新疆准噶尔A型花岗岩的年代学和地球化学研究

新疆北部地区属于中亚造山带的关键部位，有独特的构造岩浆活动和成矿作用，自二十世纪八十年代早期以来一直是国内外地质研究的热点地区之一。准噶尔盆地两侧大面积出露的A型花岗岩及相关矿床是该区的重要研究对象。尽管已有的研究积累了一定成果，但对一些关键问题，特别是对于A型花岗岩形成时代和成因的认识还存在较大争议。另一方面，传统观点认为锡矿床主要与演化的过铝质S型花岗岩有关，但在东准噶尔卡拉麦里构造带，多个中小型锡矿床产于A型花岗岩体内或岩体与围岩的接触带附近，花岗岩与锡矿的成因联系有待深入研究。 本论文以准噶尔盆地两侧的三条A型花岗岩带（包括东准噶尔的卡拉麦里和乌伦古河A型花岗岩带、西准噶尔的达拉布特A型花岗岩带）为研究对象，对其中的一些A型花岗岩体开展了详细的年代学和地球化学研究，并以这些资料为基础，探讨了A型花岗岩的岩石成因及其构造和成矿意义。概括起来，主要得到以下结论性认识： （1）锆石U-Pb年代学结果显示，卡拉麦里铝质和碱性A型花岗岩都形成于302~310Ma左右；乌伦古河碱性A型花岗岩形成于305~320Ma，而铝质A型花岗岩形成于270~280Ma；西准噶尔达拉布特铝质A型花岗岩形成于295~305Ma。这些高精度的同位素年龄资料进一步确证了准噶尔地区大面积发育的A型花岗岩是该区后碰撞阶段的岩浆作用产物。 （2）三个构造带的碱性花岗岩和碱长花岗岩都具有典型A型花岗岩的矿物学和地球化学特征。在主量元素上它们富硅、富碱、低铝、贫钙镁，在微量元素上它们明显富集Rb、K、Th等大离子亲石元素及Zr、Hf等高场强元素和稀土元素而亏损Ba、Sr、Eu。根据地球化学组成，苏吉泉黑云母碱长花岗岩是典型的铝质A型花岗岩，而不是前人提出的S型花岗岩。 （3）三个构造带的A型花岗岩均有较高的正Nd(T)值和大于成岩年龄的两阶段Nd同位素模式年龄，它们的地质特征和地球化学组成难以用幔源岩浆高度分异的成岩模式解释。这些A型花岗岩的岩浆很可能是花岗闪长质岩浆分异结晶作用的产物，而花岗闪长质岩浆则起源于具亏损地幔同位素组成的玄武质洋壳和少量陆壳物质的部分熔融。 （4）东准噶尔早二叠世A型花岗岩的发育表明该区后碰撞阶段的花岗岩浆作用持续时间较长（约60Ma），这些花岗岩与晚石炭世A型花岗岩在地球化学组成上的差异揭示了东准噶尔乃至新疆北部在早二叠世的陆壳垂向生长。 （5）萨惹什克锡矿石中辉钼矿的Re-Os同位素年龄值（307Ma）与赋矿的萨北碱性花岗岩中锆石的U-Pb年龄值（306Ma）有很好的一致性，而且辉钼矿的Re含量低，表明成矿物质可能主要源于地壳。时间和物源的证据反映该区A型花岗岩与锡矿床具有密切的成因联系。

四川省拉拉铜矿床岩石学及地球化学研究

拉拉铜矿床位于扬子地块西缘的康滇隆起中段，赋存于经历变质的古元古代河口群海相火山-沉积岩系中，是我国重要的受变质热液叠加或改造的火山成因块状硫化物矿床（VHMS）之一，也是四川省最大的铜矿生产基地。本论文以该矿床为研究对象，在系统整理前人资料的基础上，进行了深入细致的野外地质考察和系统采样，选取代表性样品，运用电子探针分析技术、元素地球化学、同位素地球化学（Rb-Sr、Sm-Nd、S）、锆石U-Pb定年等方法手段，对矿区新元古代大规模区域变质作用的变质条件、变质原岩、广泛分布于矿区多个赋矿层位的辉长辉绿岩脉、岩石及矿石性质、硫源、成矿时代等主要岩石学及矿床学问题进行了系统研究，并结合前人研究成果，探讨了矿床的成因机制。论文主要取得以下几点认识： （1）矿区变质火山岩的成岩年龄为1695±20Ma，岩浆在上升侵位的过程中捕获了古元古代早期地壳物质，后期变质改造的时代约为700-800Ma。 （2）基于石榴石黑云母片岩中石榴石黑云母矿物对的电子探针分析数据，利用石榴石-黑云母地质温度计和多硅白云母地质压力计确定了矿区新元古代大规模区域变质作用的变质条件：变质温度为530-580℃，变质压力上限为0.66-0.76GPa，对应于高绿片岩相。 （3）矿区出露的岩石类型以云母片岩类和钠长岩类岩石为主，二者共同构成了矿区的围岩及赋矿岩石，通过对代表性样品的元素地球化学、同位素地球化学研究，采用DF函数判别法、(Al/3-K)-(Al/3-Na)图解法、La/Yb-TR图解法，并结合岩矿鉴定及结构构造特征，恢复了矿区的变质原岩。其中，矿区的云母片岩类样品的变质原岩为沉积岩，以页岩为主，主要来自大陆岛弧及上地壳物质的风化；而钠长岩类样品的变质原岩为火山岩，源自富集地幔，包括“右倾型”钠长岩和“平坦型”钠长岩，前者为分离结晶作用早期并经历一定程度地壳混染的产物，后者主要形成于分离结晶作用晚期，Nb、Ta、Zr、Hf、P、Ti等达到饱和并以副矿物晶出。 （4）综合矿区变质沉积岩及变质火山岩的构造环境判别结果，确定了二者形成于大陆岛弧的弧后盆地环境。 （5）通过对矿区变质火山岩性质、形成机制及硫同位素研究，讨论了矿床中成矿元素可能的富集机制，即地幔中大量的亲铜元素及硫元素进入母岩浆并随之上升形成区域分布的火山岩，为矿床的形成提供了必要条件。 （6）侵入河口群地层并广泛出露于矿区多个赋矿层位的辉长辉绿岩脉的化学成分与板内碱性玄武岩类似且形成于大陆裂谷环境下的类似OIB源区，是高温地幔柱部分熔融的产物，幔源岩浆在上升侵位过程中受到了地壳物质尤其是上地壳物质较小程度的混染，表明新元古代Rodinia超大陆裂解对拉拉地区的成矿作用有重要影响。 （7）拉拉铜矿床主要存在两个成矿期次，即火山喷气-沉积成矿期（1700 Ma左右）和变质热液成矿期（700-800Ma）。矿区主要存在两种类型矿石，即条纹、条带状矿石和块状、浸染状矿石，前者主要赋存于变质火山岩中，可能形成于火山喷气-沉积成矿期，后者主要赋存于变质沉积岩中，可能为变质热液成矿期的产物。

中元古代昆阳群Fe-Cu-REE矿床地球化学研究-以武定迤纳厂矿床为例

稀土元素成矿与地壳的构造运动密切相关，稀土在中元古代具有大规模暴发性成矿特征。云南武定迤纳厂稀土铁铜矿床为昆阳群因民组出现稀土富集成矿的典型代表。本论文选择迤纳厂矿床为主要研究对象，系统研究矿床不同类型岩（矿）石和矿物的稀土元素地球化学特征，探讨富稀土的成矿流体、成矿物质来源和稀土元素成矿时代，揭示昆阳裂谷初期因民组稀土元素富集的地球化学机制。主要认识如下：1、迤纳厂矿床产于昆阳裂谷初期形成的禄丰一武定火山断陷盆地中。早中元古界昆阳群分布于绿汁江岩石圈断裂和小江一易门断裂的夹持地带，呈狭长状展布。迤纳厂矿床赋矿地层为昆阳群因民组上段的硅质白云岩和碱性火山岩（粗面安山岩）。矿体产出形态和矿石的结构构造等均显示矿体与赋矿地层同沉积特征；出现独立矿物氟碳饰矿、独居石及褐帘石，磷灰石、萤石、菱铁矿等矿物中也含有一定量的稀土，沿矿体走向和垂向稀土元素变化不大。2、矿体顶、底板围岩（石榴石黑云母片岩、钠长黑云母片岩等）的原岩为碱性火山岩（粗面安山岩），相对富集大离子亲石元素Ba、Cs、Rb、K、LRE日及贫Zr、Sr、Ti、Hf、HEE，为早元古代末期一中元古代早期交代富集地慢低程度部分熔融所形成的碱性火山岩。矿石稀土总量高（645-4443）×10-6，强烈富集轻稀土（（La/Tb）N＝17.3-81.1），稀土元素分布特征明显不同于矿区正常沉积的硅质白云岩和后期侵入的钠长石英斑岩及火山角砾岩，而与矿体顶、底板碱性火山岩中稀土元素配分特征基本一致，暗示稀土成矿物质来源与碱性火山岩有密切的关系；3、矿石中微量元素组合及变化特征与现代海底正在喷出的热液和热液沉积物中元素组合有较大的可比性，明显不同与火成碳酸岩型稀土矿床中的特征元素组合；在微量元素判别图解（Al-Fe-Mn、Fe／Ti-Al／（Al+Fe＋Mn）、U-Th、Y-P2O5等）中，逸纳厂矿石均投影在热水沉积区，矿石的Y／Ho值与黑烟囱值接近，表明成矿流体为高温、还原性质，稀土成矿可能以热水沉积作用方式为主；4、对矿石中主要矿物萤石、菱铁矿、磁铁矿、石英、方解石的稀土元素特征研究表明，矿石沉积时不同矿物中稀土元素分布特征基本相同，主要受成矿流体中稀土分布特征制约。而后期变质作用形成的矿物，其稀土元素分布主要受矿物晶体结构控制。同期成矿流体从早期到晚期（块状矿石→条带状矿石），轻重稀土分异变小，稀土总量增加，条带状矿石中稀土含量最高；矿石黄铜矿6345值变化在一任3％0到2g％。范围，显示慢源硫特征；菱铁矿6r3C（8％-9.1%）、δ18O（-11.17%-15.37）‰指示成矿流体具岩浆来源和有机质的脱梭酸分解作用参与；成矿流体中稀土元素可能主要以（RE（CO3）3F）4-、（既（CO3）3F2）、（RE（F，Cl万等形式迁移，当温度降低时沉淀出氟碳饰矿等稀土矿物；5、矿石和萤石单矿物 Sm-Nd等时线年龄分别为1621士110Ma和15：38士43Ma，与矿区碱性火山岩错石的U-Pb年龄1676Ma、因民组顶部石英正长斑岩的错石U-P1。年龄1685Ma基本一致，也与因民组地层年龄1765M。较为接近，反映成矿时代为早元古代晚期和中元古代早期：这一时间也与一早元古代晚期一中元古代早期昆阳裂谷初始裂陷阶段，大量来自于地幔的碱性火山岩喷发事件相吻合。矿石。Nd（t）:-2.87-3.60，萤石单矿物εNd（t）：-3.93-5.90，变化范围较窄并全为负值，接近0，指示源区为富集地幔。同时结合矿床形成的构造一地质环境及矿体产出的地质形态，认为逛纳厂稀土铁铜矿床可能是在昆阳裂谷初期，在碱性火山岩浆喷发的间歇期，来自地幔富稀土、挥发份的成矿流体由火山喷流一同生沉积方式形成的矿床。6、昆阳群因民组地层中出现的稀土富集、成矿与我国的白云鄂博稀土REE-Fe-Nb超大型矿一床和澳大利亚的olympic Dam Cu-U-Au-Ag-REE超大型矿床，在成矿时代、产出大地构造背景、成矿物质来源等方面具有较大的相似性，均体现成矿受控于中元古代1.5Ga超大陆聚合前或随后裂解初始阶段伴随的非造山型碱性岩浆或热液作用，稀土来源于超大陆拼合前因板块俯冲交代而形成的富集地幔。

广西贺县龙水金矿床的同位素地球化学研究及成因探讨

广西贺县龙水金矿位于湘桂稳定区，桂粤交界山脉的北段，博白-茶陵深断裂的西侧，区内广泛发育加里东期到燕山期的花岗岩，出露的基底地层主要为震旦系到寒武系。本文主要研究龙水金矿II号矿化带。该带位于寒武系水口群清溪亚群和大宁花岗闪长岩体的接触带附近，围岩为寒武系的碳质板岩，矿脉为硫化物石英脉，主要有黄铁矿、方铅矿、闪锌矿和石英等矿物。金矿化与硫化物密切相关。主要的金矿物为银金矿，少许自然金。确定金矿床的成矿年龄一直是个比较刺手的问题。本文选择矿脉中信为是成矿期的石英作为Rb-Sr等时年龄测定的对象，是基于其纯净和其中的原生气液包体基本可代表成矿热液的特征。结果表明其Rb-Sr等时年龄为120.5Ma，并认为此年龄代表了成矿年龄。有石英Rb-Sr等时线的~(87)Sr/~(86)Sr初始比为0.732089, 与矿脉中碳酸相加矿物的Sr同位素比值（约为0.7337-0.7402）一起，表明Sr应是来自地壳的富Rb盐矿物的Sr源区。另外，为了与围岩的蚀变年龄对比，测定了近矿围岩的Rb、Sr同位素组成，结果形成两条等时线，年龄分别为245.9 Ma和173.6 Ma，表明成矿以前至少发生了两次地质事件，导致了Sr同位素的均一化。这两次地质事件分别与华南的东吴运动及燕山运动第一幕相对应。矿石Pb同位素的~(206)Pb/~(204)Pb、 ~(207)Pb/~(204)Pb 和~(208)Pb/~(204)Pb 分别在18.4-18.9、15.6-16.1和38.4-39.6的范围内，并在~(207)Pb/~(204)Pb vs ~(206)Pb/~(204)Pb坐标图上呈现出斜率为1左右的线性排布。只有个别数据点要以得出依据Doe模式的模式年龄，约为200 Ma。在Zart,am Pb构造模式中，矿石Pb同位素数据大部分位于上地壳Pb线以上，呈现出富放射性成因Pb的特征。为了解释异常Pb的成因，本文进行了定量计算。结果表明矿石Pb为古老的存留地壳Pb与少地幔源Pb的混合，即矿石Pb同位素经历了这样的演化过程：在39-29.8亿年间由地幔分异出的地壳 Pb，未参与壳幔循环作用，一直到燕山期，与少量幔源Pb混合，并加入成矿。混合μ值为9.85-10.22。矿石的地质情况及矿石Pb同位素的Δα-Δβ-Δγ示踪结果均支持这一结论。本文初次研究了脉石英中的U、Pb同位素组成。脉石英中Ｕ含量很低。Pb同位素组成基本可以划分为两组，一组为与方铅矿数据近似的普通Pb组成，另一组则较富放射性成因Pb，并向围岩的Pb同位素组成漂移，可能是随着热液的演化和大气降水的加入，受围岩Pb的影响所致。矿脉中硫化物样品的S同位素比值（加权平均为0.16‰）和碳酸盐矿物样品的C同位素比值（在-0.1～-4.1‰的范围内），表明其应为内生来源。根据脉石英的气液包体均一温度（180-250 ），计算与脉石英存在0同位素平衡的热液的同位素的同位素组成，结果为1.2～-4.8‰，表明有大气降水的参与。石英气液包体水溶液为弱碱性，其成分分析表明其中K_2O/Na_2和CaO/MgO（分别根据K~+/Na~+和Ca~(2+)/Mg~(2+)的换算）与围岩相差很大。另外，矿石中微量元素主要为Au、A2g、Cu、Pb、Zn、Co、Ni、Mo、Bi、Ga、As、Sb、和Hg，而围岩中微量元素则主要为Cu、Ni、Mn、V、Zr、Ti、Cr和Ba。因此，热液中成矿元素主要不是来自围岩。黄铁矿的Co/Ni、S/Se/的比值可以指示热液化的来源。龙水金矿矿脉中黄铁矿的Co/Ni > 1，S/Se < 15000，均在与岩浆作用有关的热液范围内。因此，热液活动应主要与岩浆岩有关。矿石、围岩和花岗闪长岩的稀土配分模式相似，均呈现向右倾斜的V字型，并且类似于太古代后沉积岩。结合Pb、Sr同位素的研究，推测花岗闪长岩的源岩主要为古老的地壳物质。概括起来，龙水金矿床为约120.5 Ma形成的中低温热液矿床；热液中成矿物质主要来自花岗闪长岩。由于围岩与矿床紧密的空间联系及围岩中的高Au含量，围岩可能提供了一部分Au及其他成矿物质。

内蒙、张宣地区麻粒岩相岩石同位素地质年代学和同位素体系特征的研究

本文通过对张宣地区西望山群、内蒙乌拉山群麻粒岩相岩石中系统的岩石学、岩石化学、稀土元素地球化学以及Sm－Nd、Rb－Sr、锆石U－Pb及全岩Pb－Pb同位素体系的工作，主要提出以下认识：内蒙、张宣两地麻粒岩均同火成岩类变质而来，基性麻粒岩类的的岩相当于拉斑玄武岩及碱性玄武岩类，中、酸性麻粒岩的原岩是与它们成份相同的花岗岩及花岗闪长岩类。