Fore‐arc evolution in the Tasman Geosyncline: The origin of the southeast Australian continental crust

A new general model describing the extended evolution of fore‐arc terrains is used to analyse the evolution of the southern Tasman Geosyncline and the concomitant growth and kratonisation of the continental crust of southeast Australia during the Palaeozoic. The southern Tasman Geosyncline comprises ten arc terrains (here defined), most of which are east‐facing, and several features formed by crustal extension. Each arc terrain consists of several strato‐tectonic units: a volcanic arc, subduction complex and fore‐arc sequence formed during subduction; and an overlying post‐arc sequence which post‐dates subduction and is composed of flysch, neritic sediments or subaerial volcanics.

When these materials attained a thickness of c. 20 km their internal heat‐balance caused partial melting of the subduction complex and the hydrated oceanic lithosphere trapped beneath it, to yield S‐ and I‐type granitic magma. The magma rose, inducing pervasive deformation of each arc terrain and emplacement of granitoid plutons at high levels in the evolving crust. Transitional basins then developed in many terrains on top of their volcanic arcs or the thinner parts of the buried accretionary prisms. After deformation of the transitional sequences, platform cover accumulated, marking the completion of kratonisation.

Analysis of each arc terrain in terms of the above units leads to a predicted ‘stratigraphy’ for the continental crust of southeast Australia. The crust is complexly layered, with lateral discontinuities reflecting the boundaries of arc terrains which were successively accreted, principally back‐arc to fore‐arc, during crustal development.     

Fine structure beneath the Tohoku district, northeastern Japan arc, as derived by an inversion of P-wave arrival times from local earthquakes

Three dimensional P-wave velocity structure beneath the Tohoku district, northeastern Japan arc, is investigated by an inversion of arrival times from local earthquakes using the method originally due to Aki and Lee (1976).In the crust (0–32 km depth) a low-velocity region is found along the volcanic front and its vicinity. Velocities at depths of 32–65 km are low beneath the regions where many Quaternary volcanoes and geothermal areas are distributed. In the region deeper than 65 km, the subduction of the Pacific plate is clearly revealed, and the mantle structure above the descending plate is rather uniform. These features suggest that volcanic activities have relation to the upper mantle structure. The results obtained in this study will be helpful in investigating the mechanism of magma generation in a subduction zone.     

北京平原沙河凹陷第四纪磁性地层学研究及其新构造运动的沉积响应

北京地区在古近—新近纪时呈"两隆一凹"的构造格局。由于南口—孙河断裂北段第四纪以来的强烈活动,在上述格局上分化出新的第四纪凹陷盆地——沙河凹陷。本次工作在沙河凹陷内开展了钻孔ZK3的第四纪磁性地层研究,结合14C同位素测年结果获得钻孔剖面早更新世、中更新世、晚更新世和全新世地层底板埋深分别为493.8 m、157.4m、87.7 m和7.2 m,建立了钻孔剖面的第四纪地层序列。通过计算ZK3钻孔剖面第四系沉积速率分别为0.19 mm/a、0.11 mm/a、0.70 mm/a和0.63 mm/a。对比分析控盆断裂南口—孙河断裂的活动规律及北京西山的隆升特点,第四纪以来,受到北京西山隆升的影响,控制沙河凹陷的同生断裂南口—孙河断裂强烈活动,并控制了沙河凹陷的演化形成。钻孔地层平均沉积速率所体现的变化规律与山体隆升速率及断裂活动速率具有较好的响应关系。     

秦岭造山带主要大地构造单元的新划分

根据近年来的地层、沉积、岩浆-火山和构造变形及岩石地球化学等方面研究新进展,结合前人的成果,按照大地构造相单元划分原则,将秦岭造山带分为13个主要构造单元: ①华北南缘陆坡带,包括第一层序的青白口系大庄组、震旦系罗圈组和寒武系,与之对应的豫西栾川群;第二层序的奥陶纪陶湾群;②北秦岭弧后杂岩带,以宽坪群和部分二郎坪群中的基性火山岩与碳酸盐岩的构造块体与变质的古生代深海碎屑岩混杂为特征;③秦岭岛弧杂岩带,由丹凤群不同的古洋隆块体、富水幔源岛弧基性岩浆杂岩、云架山群、斜峪关群和草滩沟群的岛弧钙碱性岩浆岩和火山岩及深海沉积物及秦岭群弧基底杂岩等构成,时间跨度为奥陶纪-石炭纪;④秦岭弧前盆地系,泥盆系及其它晚古生代地层是其主要充填物,同沉积断裂控制了一系列的次级盆地;⑤秦岭增生混杂带,由泥、砂岩组成的基质和基性、超基性岩、火山岩、灰岩、硅质岩等岩块构成,最终形成于二叠纪末-三叠纪初;⑥南秦岭岛弧杂岩带,碧口群的基性-中酸性火山岩和岩浆岩组成,称碧口弧;由三花石群的中基性火山岩以及西乡群的中酸性火山岩共同构成,称西乡弧;由耀岭河群和郧西群中基性熔岩和中酸性火山岩组成,称安康弧;⑦南秦岭弧前盆地系,碧口弧前盆地充填物是以碎屑岩为主的横丹群和关家沟群;西乡弧前沉积主要由三花岩群包括王家坝组砂岩以及由泥岩、砂岩和中酸性火山岩变质而成的片岩、片麻岩和石英岩组成.安康弧前盆地具有明显的深海扇沉积特征梅子垭群和大贵坪组;⑧南秦岭弧后盆地系,包括后龙门山的茂县群和上古生界及三叠系,大巴山的洞河群和部分耀岭河群的火山岩;⑨南秦岭弧后陆坡带,只保留大巴山弧后陆缘,是高川-毛坝以南的下古生界;⑩南秦岭前陆褶冲带,包括龙门山北段、米仓山和大巴山前陆褶冲带.三带形成于印支-燕山期,但构造线不同,且在出现的时间上,由西到东由早到晚;(11)三叠纪残余海盆;(12)中-新生代走滑拉分和断陷盆地;(13)基底断块.     

Crystalline rocks of the Spinatizha area, Pakistan

During the Cretaceous an andesitic arc developed across south Asia facing the Tethys Ocean. Remnants of this arc are preserved in Iran, Afghanistan, and the Chagai Hills and Kohistan, Pakistan. West of the Chaman fault near Spinatizha, Pakistan (33° 33′N, 66° 23′E) a terrain of crystalline rocks is exposed that links the Chagai Hills portion of this arc with the Kandahar portion of it in Afghanistan. Four units are present. (1) The Spinatizha Metamorphic Complex includes orthogneiss, greenschist, amphibolite, metavolcanics, marble and foliated muscovite granite. Extreme variation in rock type and degree of metamorphism characterises the entire complex. It is the oldest unit west of the Chaman fault in Pakistan. (2) The Bazai Ghar Volcanics consist of weakly deformed tuffs, flow breccias, and other coarse-grained pyroclastics of andesitic-arc type. Andesite flows and at least one silicic welded tuff are also present. The Bazai Ghar Volcanics are everywhere separated from the Spinatizha Metamorphic unit by granitic intrusions and a major fault. (3) Both the above units are intruded by a series of calc-alkaline granitic plutons ranging from diorite to granite. The silicic plutons generally intrude the more mafic ones. The Bazai Ghar Volcanics and related intrusions are probably equivalent to the Cretaceous (?) Sinjrani volcanics and the Cretaceous and younger intrusions of the Chagai Hills. (4) Along the fault zone between the volcanic and metamorphic rocks is a small area of previously unknown clastic sedimentary rocks: conglomerates and slates. The unit is of Palaeogene age but cannot yet be correlated with known units. The Spinatizha crystalline terrain extends south along the Chaman fault into Afghanistan and is covered by the Helmund desert to the west. It is the eastern continuation of the calc-alkaline arc terrain of the Chagai Hills dragged by oroclinal flexing into the Chaman transform zone. To the north it connects with the Kandahar volcanic arc. The metamorphic complex may represent the basement on which the arc terrain rests, only exposed due to strong vertical uplift near the Chaman fault.     

小兴安岭逊克地区第四纪高镁安山岩的岩石学、K-Ar年代学及火山地质特征

黑龙江省小兴安岭北段逊克地区出露大面积的第四纪火山岩,分布面积约3000km~2。岩性主要为玄武安山岩和玄武质粗面安山岩,还有少量的粗面安山岩和安山岩。逊克火山岩的Si O2含量为54.3%~57.4%,MgO含量变化为3.82%~5.80%,镁指数(Mg#=100×Mg/(Mg+Fe~(2+))变化于49.6~57.8之间,属于高镁安山岩。逊克高镁安山岩火山口的位置分布在火山岩区的南面,根据火山岩区南高北低的地势,推测北边的火山岩是由南侧的岩浆向北流动形成的。岩浆流动形成了具有特征性的火山地貌,如沿河谷形成数公里长的石垄以及大面积的翻花熔岩形成的石海景观。火山岩的K-Ar测年结果表明,逊克高镁安山岩可以划分为早更新世(1.12~1.00Ma)和中更新世(0.68~0.25Ma)两期。在第四纪熔岩和河湖相沉积之间还夹有薄层火山灰,推测在岩浆溢流形成大面积熔岩之前有小规模岩浆爆发活动。     

Metamorphism of a Late Jurassic volcano-plutonic arc, northern California, USA

Abstract The metamorphic history of the Middle to Upper Jurassic volcanic and hypabyssal rocks exposed in the Klamath Mountains and Sierra Nevada of California is related, in part, to the rifting of a volcano-plutonic arc. The Callovian to Kimmeridgian rocks exposed in the region consist of, from north-west to south-east, a back-arc ophiolite, a rifted volcanic arc and a volcanic arc complex. All of these units have been metamorphosed and contain various combinations of the phases chlorite, amphibole, epidote, prehnite and pumpellyite. Projection of coexisting phases onto the composition plane MgO/(MgO + FeO) and Al₂O₃+ Fe₂O₃ - 0.75 CaO - Na₂O through quartz, water, albite and epidote results in consistent mineralogical compatibilities within each region, but crossing tie-lines between regions. This suggests that the volcanic and hypabyssal rocks from each region have equilibrated under different intensive conditions. The back-arc ophiolite in the north has suffered subseafloor high-T/P hydrothermal metamorphism with geothermal gradients on the order of 100° C km^?1. The rifted volcanic arc has undergone synchronous burial, hydrothermal and contact metamorphism. Metamorphic field gradients in the region pass through the prehnite-pumpellyite and greenschist facies suggesting geothermal gradients on the order of 30° C km^?1. The southernmost volcanic arc complexes contain metavolcanics of the pumpellyiteactinolite and greenschist facies suggesting moderate- to high-P/T metamorphism and geothermal gradients on the order of 20° C km^?1. The apparent increase in rifting and calculated geothermal gradients from south-east to north-west suggest that the observed very low- and low-grade metamorphism may be a response to enhanced thermal gradients during extension of the volcanic arc. This correlation between the extent of rifting and metamorphism is consistent with a model of diastathermal metamorphism of a propagating rift along the western margin of North America during the Late Jurassic. The plate tectonic setting may be analogous to the present-day Andaman Sea region.     

从自贡盐矿地球化学特征成盐模式看其找矿方向及含钾性

自贡自流井构造盐矿规模小,呈透镜状,厚度薄,变化大。但盐矿咸化程度高,盐溶水K+、Mg2+含量高;K·103/Cl、K/Br、Br·103/Cl地球化学特征优异。盐矿为潮上蒸发坪上预为浓缩的古卤水聚集于相对低凹的盐沼,再经蒸发而形成,具有成钾条件。盐矿受蒸发坪古地貌控制。在古地貌低洼处及“X”棋盘格式构造交叉处、TM遥感图象上环形影象的点,部署钻探验证,可望找到新的盐矿体。这为进一步开展自流井构造探盐找钾工作可具有重要现实指导意义,对其它地区也有一定启示意义。     

黑龙江北部多宝山矿区奥陶系的岩石特征和构造意义

黑龙江北部多宝山矿区广泛发育奥陶系,因含有铜、钼矿源层而受到地质界的注意.本文概述了其生物地层和沉积特征,重点探讨了其火山岩的岩石化学特征.该套火山岩总体上属钙碱性系列,部分（主要是酸性岩）可能属拉斑玄武岩系.下旋回（窝里河组）火山岩以相对低K、La和Eu负异常为特征,总体属大陆边缘岛弧,局部显示出大洋岛弧安山岩的性质.上旋回（多宝山组）的弧则属大陆边缘岛弧与安第斯型山弧的过渡类型,部分地区可能有安第斯型山弧发育.分5个阶段重塑了该区奥陶纪大地构造演化,早古代洋壳向东偏北消减于布列亚一佳木斯地块之下,因后退式的消减而火山弧向西偏南迁移,构造线方向为北北西向.     

雷州半岛局部地热异常及其形成机制

雷州半岛地热场主要受基底构造格局的控制和地下水活动的影响,隐伏花岗岩体放射性元素生热对盖层地温的贡献不可忽视,第四纪更新世火山喷发活动的岩浆余热已几乎完全散失,岩浆体和围岩温度已趋于平衡。由火山喷发而形成的雷北螺岗岭和雷南石峁岭两个玄武岩台地,为半岛地下水的主要补给区,由于冷水流下渗的地温效应,新生界盖层浅部地温梯度<3℃/100m,呈现地热负异常。在以传导传热为主的区域,地热场特点与华北盆地相似,新生界盖层地温梯度与基底岩面的埋深密切相关。由于地壳深部较均一的热流在地壳表部再分配的结果,若干凸起区盖层地温梯度为4—5℃/100m,呈现地热正异常。某些控制凸起区的边界断裂,当深层热水沿其上涌,造成附加热源,和传导传热相叠加,盖层地温梯度可高达5—8℃/100m,形成更鲜明的地热正异常。     

Thermal properties and coal rank in rocks and coal seams of the southern Sydney Basin,new South Wales: A palaeogeothermal explanation of coalification

Measurements of thermal conductivity on 106 disc specimens of rocks from 275 m of the Permian to Triassic section of the Southern Coalfield of the southern Sydney Basin have been carried out in an effort to explain a high rank gradient in the Permian coals. The samples came from six diamond drill holes north and west of Wollongong, although one hole only provided specimens of a syenitic sill (n = 17, mean thermal conductivity = 2.36 W/m°K, s.d. 0.03). When combined with previously published data on chip specimens, with which there is good agreement, from a further four drill holes the mean thermal conductivity for the late Permian and early Triassic sandstones and shales is 3.20 W/m°K.Heat generation by Permian volcanic rocks below the coal measures (from about 1 to 3 μW/m³), and by basement granitic rocks, appears to be consistent with previously reported heat flow for the southern Sydney Basin (about 80 mW/m²). This heat flow is a relatively high value for the east coast of Australia. Younger (Mesozoic and Tertiary) intrusive and extrusive igneous rocks produce local coal-rank anomalies, but do not appear to have any regional effect.The rank of coals above the Permian volcanic rocks appears to be little affected by the presence of the igneous rocks and the coal-rank decreases towards the major area of vulcanicity. Organic matter in sedimentary rocks interbedded with the volcanic rocks is of relatively high rank but it appears that these thermal effects do not extend more than about 100 m above the base of the coal measures. The area of high rank north and northwest of Wollongong seems likely to be a regional effect associated with a combination of high heat generation in basement and the Permian rocks, and high heat flow from the basement. Greater cover on the coal measures, together with an increase in the proportion of rocks of relatively low thermal conductivity in the cover, may also influence the rank in the Permian coal.     

Volcanic and Tectonic Framework of the Hydrothermal Activity of the Izu–Bonin Arc

In the Izu–Bonin Arc, hydrothermal activities have been reported from volcanoes along present‐day volcanic front, a rear arc volcano and a back‐arc rift basin as well as a remnant arc structure now isolated from the Quaternary arc. It is widely known that characteristics of hydrothermal activity (mineralogy, chemistry of fluid etc.) vary depending upon its tectonic setting. The Izu–Bonin Arc has experienced repeated back‐arc or intra‐arc rifting and spreading and resumption of arc volcanism. These characteristics make this arc system a suitable place to study the tectonic control on hydrothermal activity. The purpose of the present paper is, therefore, to summarize volcanotectonic setting and history of the Izu–Bonin Arc in relation to the hydrothermal activity. The volcanotectonic history of the Izu–Bonin Arc can be divided into five stages: (i) first arc volcanism (boninite, high‐Mg andesite), 48–46 Ma; (ii) second arc volcanism (tholeiitic, calc‐alkaline), 44–29 Ma; (iii) first spreading of back‐arc basin (Shikoku Basin), 25–15 Ma; (iv) third arc volcanism (tholeiitic, calc‐alkaline), 13–3 Ma; and (v) rifting in the back‐arc and tholeiitic volcanism along the volcanic front, 3–0 Ma. Magmas erupted in each stage of arc evolution show different chemical characteristics from each other, mainly due to the change in composition of slab‐derived component and possibly mantle depletion caused by melt extraction during back‐arc spreading and prolonged arc volcanism. In the volcanotectonic context summarized here, hydrothermal activity recognized in the Izu–Bonin Arc can be classified into four groups: (i) present‐day hydrothermal activity at the volcanic front; (ii) active hydrothermal activity in the back arc; (iii) fossil hydrothermal activity in the back‐arc volcanoes; and (iv) fossil hydrothermal activity in the remnant arc. Currently hydrothermal activities occur in three different settings: submarine caldera and stratocones along the volcanic front; a back‐arc rift basin; and a rear arc caldera. In contrast, hydrothermal activities found in the back‐arc seamount chains were associated with rear arc volcanism in Neogene after cessation of back‐arc spreading of the Shikoku Basin. Finally, sulfide mineralization associated with boninitic volcanism in the Eocene presumably took place during forearc spreading in the initial stage of the arc. This type of activity appears to be limited during this stage of arc evolution.     

内蒙古卓资县玛珥式火山群的发现和意义

玛珥式火山易被掩埋和不易识别,它们与人们常见的高出地面的锥状体火山口不同,而以负地形、圆形或椭圆形状、面积小和高度密集成群出现为特征。位于卓资县北部的玛珥式火山群无论在规模上和保存完好程度上都是世界上第一位的。进一步研究它们将填补我国地学界对负地形玛珥式火山口的认识、研究第四纪火山地质、推动当地旅游方面都具有意义。     

Hydrochemistry and thermal activity of damt region,Yemen

The aim of this study was to identify the complex hydrogeological and hydrochemistry conditions of Damt region, through determining hydrochemical properties of groundwater in the study area. According to the results of hydrochemical analyses, sampled waters can be divided into three groups: cold, thermal, and mixed waters. Thermal waters in the area are characterized by Na–HCO₃, while the cold waters by CaHCO₃ facies. HCO₃ indiscriminate cation and/or Na-indiscriminate anion are present in many places in the region and indicate generally mixing water. Only three villages with dental fluorosis observed using water elevated in F⁻ for drinking. Agricultural and liquid waste disposal are the main sources of pollution, leads to increase of Na, Cl, NO₃, Cd, and Iron. The groundwater flow is from north, northwest, and northeast to the south. Within this regional trend, structural controlling groundwater flow along Wadis and it flows from upper reaches of tributaries toward the main channel, then downward to the south of the study area. The similarity of TDS and Cl concentration at Qa’a Al Haql and Al Nadirah between aquifers indicates hydraulic continuity between alluvial and the underlying volcanic, while at Damt no hydraulic continuity found between alluvial, volcanic and Sandstone aquifers. The temporal variation shows slight decrease in the concentration of nitrate and sulfate of thermal water indicating previously high gas content of nitrogen, hydrogen sulfide in the thermal active region. The developed conceptual model of water circulation indicates flood waters infiltrate slowly through the wadi bottoms in the East where Sandstone aquifer outcrops. These waters flow westward, following the westerly dip of the Sandstone through the effects of gravity, gains heat and dissolve materials as it comes in contact with the numerous dykes, which are the feeders to the overlying volcanoes and sputter cones. All thermal water samples from Damt region fall into immature water field in NA–K–Mg diagram. Therefore, the results obtained from the cation geothermometers should be taken into account as doubtful.     

TRIASSIC SEQUENCE STRATIGRAPHY AND CORRELATION FROM POLY-ARC AND BACK-ARC SYSTEM IN EASTERN TIBET

TRIASSIC SEQUENCE STRATIGRAPHY AND CORRELATION FROM POLY-ARC AND BACK-ARC SYSTEM IN EASTERN TIBET     

Volcanic Sequences Related to Kuroko Mineralization in the Hokuroku District, Northeast Japan

Abstract. Kuroko deposits are a representative volcanic‐hosted massive sulfide deposit and the Hokuroku district is economically the most important Kuroko containing province in Japan. There are two cycles of the bimodal volcanic sequence in the Hokuroku district. The pre‐ore volcanism started with basaltic activity and was followed by intensive felsic hyaloclas‐tic activity under bathyal conditions. The post‐ore sequence also began with basaltic activity intercalated with mudstone and was followed by alternating beds of pumice tuff with several lava flows and mudstone. Kuroko deposits are situated in the final period of the pre‐ore felsic volcanic sequence of the first bimodal volcanic cycle. Based on a detailed investigation of existing age data, it was concluded that the felsic volcanic sequences in the pre‐and post‐Kuroko formation can be divided into a pre‐ore dacite group (16–13.5 Ma), a D2 dacite group (lower unit of the post‐ore volcanic sequence, 12.7±0.6～ ll Ma) and a Dl dacite group (upper unit of the post‐ore sequence including quartz‐porphyry and granitoid, 11sim;10 Ma) in ascending order. Field and microscopic observations show that the pre‐ore dacite is characterized by aphyric to plagioclase‐phyric lava and the post‐ore dacitic rocks are characterized by quartz‐plagioclase‐phyric aphanitic lava and dome. These three dacite groups are petrochemically discriminated by SiO₂‐Al₂O₃ and CaO‐TiO₂ diagrams, excluding altered specimens. The distribution of the normative compositions on the Q‐An‐Ab‐Or diagram suggests that the pre‐ore dacites trend on the 5 kb cotectic line (equilibrated to 10—15 km deep) and those of the post‐ore trend along the 1 kb line (a few km deep). The secular variation of the major elements indicates that the rhyolitic members genetically related to the Kuroko formation could be the most differentiated products in the pre‐ore felsic volcanism. The distribution of Nb against SiO₂ content in the pre‐ and post‐ore bimodal volcanic cycles indicates that these two volcanisms could have been generated by different magmatic origins. The difference would have been caused by the tectonic conversion from a back‐arc to an island‐arc setting.     

Neogene volcanism and Holocene earthquakes in the Tanlu fault zone, eastern China

In this paper, we study the relationship between Neogene volcanism and Holocene earthquakes in the Tanlu fault, eastern China. We find that fault segments through which Neogene and Quaternary magma have extruded do not show Holocene slip because they are covered by unfaulted basalts. In contrast, fault branches that are away from the Quaternary volcanic centers display Quaternary faulting and are responsible for earthquakes as recorded both historically and geomorphologically. Therefore, magma intrusion appears to modify fault activity in two different ways: (1) within the faults, the cooling magma serves as a cohesion or barrier, welding the faults so that they become stronger in resisting slip; (2) beneath the faults, the upwelling magma promotes slip of faults above the magma body, and hence generation of earthquakes. Physically, the first case results from contraction of the cooling magma, which causes a relative increase in fault-normal stress so that the fault failure resistance is enhanced. The second case results from the upward dynamic force and the heat brought in by the magma body, both of which cause the effective fault-normal stress to decrease so that the fault failure resistance is reduced. That could explain why earthquakes occur on faults bypassing the volcanic centers as typified in the Yishu fault zone and in the regions where heat flows are relatively high as shown in the Bohai Bay area.     

Petrochemical Investigation of the Antique Ophiolite (Philippines): Implications on Volcanogenic Massive Sulfide and Podiform Chromitite Deposits

Abstract: The Antique ophiolite, located in Panay island (west‐central Philippines), corresponds to several tectonic slices within the suture zone between the Philippine Mobile Belt (PMB) and the North Palawan Block (NPB). It includes dismembered fragments of a basaltic sequence, dominantly pillow‐lavas with minor sheet flows, rare exposures of sheeted dikes, isotropic gabbros, subordinate layered mafic and ultramafic rock sequences and serpentinites. Most of the ophiolite units commonly occur as clasts and blocks within the serpentinites, which intrude the whole ophiolitic body, as well as, the basal conglomerate of the overlying Middle Miocene sedimentary formation. The volcanic rock sequence is characterized by chemical compositions ranging from transitional (T)‐MORB, normal (N)‐MORB and to chemistry intermediate between those of MORB and island arc basalt (IAB). The residual upper mantle sequence is harzburgitic and generally more depleted than the upper mantle underlying modern mid‐oceanic ridges. Calculations using whole‐rock and mineral compositions show that they can represent the residue of a fertile mantle source, which have undergone degrees of partial melting ranging from 9‐22.5 %. Some of the mantle samples display chondrite‐nor‐malized REE and extended multi‐element patterns suggesting enrichments in LREE, Rb, Sr and Zr, which are comparable to those found in fore‐arc peridotites from the Izu‐Bonin‐Mariana (IBM) arc system. The Antique ultramafic rocks also record relatively oxidizing mantle conditions (Δlog f_O2 (FMQ)=0.9‐3.5). As a whole, the ophiolite probably represents an agglomeration of oceanic ridge and fore‐arc crust fragments, which were juxtaposed during the Miocene collision of the PMB and the NPB. The intrusion of the serpentinites might be either coeval or subsequent to the accretion of the oceanic crust onto the fore‐arc. Volcanogenic massive sulfide (VMS) deposits occur either in or near the contact between the pillow basalts and the overlying sediments or interbedded with the sediments. The morphology of the deposits, type of metals, ore texture and the nature of the host rocks suggest that the formation of the VMS bodies was similar to the accumulation of metals around and in the subsurface of hydrothermal vents observed in modern mid‐oceanic ridge and back‐arc basin rift settings. The podiform chromitites occur as pods and subordinate layers within totally serpentinized dunite in the residual upper mantle sequence. No large coherent chromitite deposit was found since the host dunitic rocks often occur as blocks within the serpentinites. It is difficult to evaluate the original geodynamic setting of the mineralized bodies since the chemistry of the host rocks were considerably modified by alteration during their tectonic emplacement. A preliminary conclusion for Antique is that the VMS is apparently associated with a primitive tholeiitic intermediate MORB‐IAB volcanic suite, the chemistry of which is close to the calculated composition of the liquid that coexisted with the podiform chromitites.     

红河流域元古界大红山群变质岩系的热储结构及热流特征

经过地热地质调查、物探验证和分析论证,在红河流域中段的戛洒盆地古元古界大红山群变质岩系中钻探获得了可供开发利用的热矿水。勘探孔深2 200.71 m,大红山群第4至第5段（Pt₁dhs4-5）热储层富水性强,钻孔涌水量1 089 m3·d?1,孔底测温84.3 ℃,地热水矿化度9 777 mg·L?1,水化学类型为Cl-Na型,水化学成分复杂。此次成功的勘探研究,揭示了大红山变质岩系的热储特征及地热资源潜力,拓展了地热水勘探开发的新领域。综合研究认为,大红山群变质岩系中的硬脆性大理岩、石英片岩、火成岩等热储层（带）、导热导水的深大断裂及上覆隔水隔热的三叠系红层等盖层,构成了较为典型的带状热储。热储层赋存承压地热水,主要由地下水在重力和热力作用下,沿区域深大断裂带的主干和次级导热导水断裂作深循环逐渐增温和对流运动所形成,实测地热增温率为3.0 ℃·(100 m)?1。