Forward kinematic modelling of a regional transect in the Northern Emirates using geological and apatite fission track age constraints on paleo-burial history

This paper aims to simulate the kinematic evolution of a regional transect crossing the Northern Emirates in the northernmost part of the Semail Ophiolite and the Dibba zone, just south of the Musandam Platform exposures. The studied section comprises, from top to bottom and from inner to outer zones, (1) the erosional remnants of the Semail Ophiolite, mainly made up of serpentinized ultramafics in the west and gabbros in the east, (2) high-grade metamorphic rocks which are currently exposed in the core of a nappe anticline near Masafi, (3) far-travelled Hawasina basinal units and Sumeini paleo-slope units of the Dibba Zone, (4) parautochthonous platform carbonates, which are currently well exposed in the Musandam area, and (5) a flexural basin filled with uppermost Cretaceous to Neogene sediments. Two main compressional episodes are generally identified, resulting first in the obduction of the Semail Ophiolite and then in the stacking of underlying platform carbonate units of the former Arabian passive margin, thus accounting for the present architecture of this transect: (1) first, deformation at the plate boundary initiated in the Late Cretaceous, resulting in the obduction of the Semail Ophiolite and the progressive accretion of the Hawasina and Sumeini tectonic wedge on top of the Arabian foreland, leading to a progressive bending of its lithosphere and development of a wide flexural basin; (2) compression resumed during the Neogene, leading to the tectonic stacking of the parautochthonous platform duplexes of Musandam and Margham trends, the development of out-of-sequence thrusts and triangle zones, refolding of the sole thrust of the former Late Cretaceous accretionary wedge and coeval normal (?) high-angle faulting along the contact between the Musandam and Dibba zones. However, seismic profiles and paleo-thermometers also help in identifying another erosional event at the boundary between the Paleogene Pabdeh and the Neogene Fars series. Evidenced by the local erosional truncation of the Pabdeh series in the vicinity of the frontal triangle zone (i.e. the inner part of the former Late Cretaceous foredeep), this Paleogene uplift/unroofing episode is tentatively interpreted here as an evidence for a continuum of compressional deformation lasting from the Late Cretaceous to the Middle Miocene although one may alternatively speculate that it was related to the detachment of the subducted slab. Although carbonate facies are usually not suitable for apatite fission track (AFT) studies, we were able to extract detrital apatites from quartz-bearing Triassic dolomites in the Musandam area. However, the yield and the quality were both poor and too few fission track lengths could be measured, making it difficult to interpret the meaning of the FT ages. The FT dates obtained in this study are therefore compared with those existing in the literature. Fortunately enough, for each sample, at least ten apatite crystals could be used for fission track dating, except for site 6 with only five datable apatite grains. The obtained apatite fission track dates between 28 and 13 Ma, much younger than the Triassic age of the series, are taken to represent reset fission track ages, implying erosion of an up-to-3-km-thick pile of Jurassic–Cretaceous carbonates and Hawasina allochthon during the Neogene. Apatite fission track dates from the ~95 M-old plagiogranites of the Semail complex (Searle and Cox, Geol Mag 139(3):241–255, 2002) obtained in this study and compared with those recently published provide evidences for more than one cooling event. An early unroofing of the ophiolite during the Late Cretaceous is revealed in fission track dates of 72–76 Ma at the top of the ophiolite in the east, which are coeval and also consistent with the occurrence of paleo-soils, rudists and paleo-reefs on top of serpentinized ultramafics in the west. High-pressure rocks at As Sifah in the southeast near Muscat revealed apatite fission track data ranging from ~46 to 63 Ma (Gray et al. 2006). The leucocratic part of the ophiolite (sample UAE 180) yielded comparable young apatite (40.6?±?3.9 Ma) and zircon (46.6?±?4.3 Ma) FT dates. A Cenozoic (~20–21 Ma) exhumation has been determined for the Bani Hamid metamorphic sole in northern Oman, applying low temperature geochronology and combining apatite FT and apatite (U–Th)/He analyses (Gray et al. 2006). In this study, young apatite fission track dates of 20 Ma have also been found but at the base of the ophiolite near Masafi, in the core of the nappe anticline, thus indicating a Neogene age for the refolding of the allochthon and stacking of underlying parautochthonous platform carbonate units. During the subsequent 2D forward Thrustpack kinematic modelling of the regional transect, these AFT data-set has been used, together with available subsurface information, to reconstruct the past architecture of the structural sections through time, accounting for incremental deformation along the various decollement levels, synorogenic sedimentation and erosion, as well as for successive bending and unbending episodes of the Arabian lithosphere.     

The upper Hawasina nappes in the central Oman Mountains: stratigraphy,palinspastics and sequence of nappe emplacement

Abstract

In the Oman mountains, a succession of sedimentary decollement nappes, the Hawasina nappes, is sandwiched between the Samail ophiolite nappe and its underlying melange and the “autochthonous” sequences of the Arabian platform. The sediments of the Hawasina nappes document the Mesozoic evolution of the northeastern Arabian continental margin and the adjacent Tethys Ocean. In earlier paleogeographic reconstructions, based on simple telescoping of the tectonic units, the upper Hawasina nappes represent the distal part and the lower nappes the proximal part of the margin. New stratigraphic data suggest a revision of the paleogeography and a more complex model for nappe emplacement in the central Oman mountains. The lower Hawasina nappes with their Jurassic and Cretaceous base of slope and basin sediments (Hamrat Duru, Wahrah) form the original cover of part of the upper Hawasina nappes. In the latter (Al Ayn, Haliw), Triassic pelagic sediments, locally overlain by massive sandstone successions are preserved. Complete Mesozoic sequences with pelagic Cenomanian sediments as youngest dated elements are found in the highest Hawasina units (Al Aridh and Oman Exotics). The stratigraphic data indicate polyphase thrusting in the central Oman mountains. Downward propagation of thrusting in front of the Samail is responsible for cutting the original stratigraphie sequence into a number of thrust-sheets, involving successively older and more external formations. This kind of thrust propagation eventually leads to the observed superposition of originally lower stratigraphie units onto their original cover. Regional deformation of the nappe contacts in post-nappe culminations (J. Akhdar, Saih Hatat) is related to ramp-flat-systems in the Arabian foreland.     

New constrains on the thickness of the Semail ophiolite in the Northern Emirates

Near-critical angle and refraction studies were performed at IFP as piggyback studies during a wider programme of crustal imagery operated by WesternGeco on behalf of the Ministry of Energy of the United Arab Emirates. The main objective is to illuminate the base of the Semail Ophiolite along part of a regional transect (D1) crossing the Northern Emirates from the Gulf of Oman in the east up to the Arabian Gulf in the west. Results confirm that the sole thrust of the ophiolite has been folded during the Miocene stacking of the underlying Arabian Platform. The thickness of the ophiolite grades from zero in the core of the Masafi tectonic window, up to a maximum of 1.7 km below the axial part of a successor basin which has been preserved on top of the serpentinite west of the current exposure of the main ultramafic bodies. Apatite grains extracted from plagiogranites of the Semail ophiolite also provide evidences for an early unroofing of the gabbros and plagiogranites during the Late Cretaceous, with cooling ages of 72–76 Ma at the top of the ophiolite in the east (not far from the Fujairah coast line), which are coeval and also consistent with the occurrence of Late Cretaceous paleo-soils, rudists and paleo-reef deposits on top of serpentinized ultramafics in the west. Younger cooling ages of 20 Ma have been also found at the base of the ophiolite near Masafi, in the core of the nappe anticline, thus providing a Neogene age for the refolding of the allochthon and stacking of underlying parautochthonous platform carbonate units. These results, together with the occurrence of a thick sedimentary pile illuminated below the metamorphic sole along the north-trending, strike-profile D2 running parallel to the axis of the Masafi window, should stimulate a renewal of the exploration in the central part of the Emirate foothills, where the ophiolite thickness is currently limited, and was already drastically reduced by the end of its Late Cretaceous obduction.     

Detrital chromites in metasediments of the East-Arabian continental margin in the Saih Hatat area: constraints for the palaeogeographic setting of the Hawasina and Semail basins (Oman Mountains)

 In Oman, the convergence between Arabia and Eurasia resulted in the Late Cretaceous overthrusting of oceanic crust and mantle lithosphere onto the Arabian continental margin. During this compressional event, a part of the continental plate was subducted to a depth of more than 60 km (0.5 GPa, 250–350  °C to more than 2.0 GPa, 550  °C) resulting in progressive metamorphism of the continental margin sediments, well exposed in the Saih Hatat tectonic window, northeastern Oman Mountains. We attempt to constrain the possibility of one continuous history of extension (starting along the east Arabian continental margin in the Permian) that was followed by one continuous history of convergence starting at 90 Ma near a dead oceanic ridge. This compression resulted in the observed progressive metamorphism by ophiolite overthrusting onto the continental margin. Constraining arguments are the palaeogeographic setting before ophiolite obduction of the As Sifah units and the Hawasina Complex near Ghurba. Detrital chromites in the Triassic–Cretaceous metasediments of the Hawasina Complex are compared with magmatic Semail chromites, and the whole-rock chemistry of these metasediments and associated metabasites are investigated. In contrast to former hypotheses, differences in the chemical composition between detrital and magmatic chromites, and the probable origin of all detrital chromites in the Hawasina Basin from Permian age oceanic rocks, suggest that the high-pressure metamorphic sediments of As Sifah can be considered as part of the basal deposits of the Hawasina Basin. Received: 1 September 1998 / Accepted: 18 January 1999     

塔河油田盐下地区奥陶系成岩作用与孔隙演化

在55口井岩心、300片薄片观察的基础上,结合地球化学分析资料,系统研究了塔河油田南部盐下地区碳酸盐岩储层的成岩作用类型。研究表明:研究区存在胶结作用、溶蚀(或岩溶)作用、压溶作用、硅化作用、破裂作用、白云化作用和重结晶作用等多种成岩作用类型。溶蚀作用(或岩溶)分为4期,依次为同生期大气水溶蚀、加里东中期大气水岩溶、海西早期大气水岩溶以及海西晚期埋藏热液溶蚀作用,其中加里东中期大气水岩溶作用及海西早期大气水岩溶作用对改善区内碳酸盐岩储层物性具有重要意义。在此基础上,进一步分析了研究区成岩作用序列及孔隙演化。     

New <Superscript>40</Superscript>Ar/<Superscript>39</Superscript>Ar age constraints on cooling and unroofing history of the metamorphic host rocks (and igneous intrusion associates) from the Bulfat Complex (Bulfat area), NE-Iraq

The Northern Zagros Suture Zone (NZSZ), formed as a result of the collision between Arabian and Sanandaj-Sirjan microplate, is considered as part of the Zagros orogenic belt. NZSZ is marked by two allochthonous thrust sheets in upward stacking order: lower and upper allochthon. The Bulfat complex is a part of the upper allochthon or “Ophiolite-bearing terrane” of Albian-Cenomenion age (97–105 Ma). Voluminous highly sheared serpentinites associated with ophiolites occur within this upper allochthon. In addition, the Gemo-Qandil Group is characterized by gabbroic to dioritic Bulfat intrusion with a crystallization age spanning from ~45 to ~?40 Ma, as well as extensive metapelites with contact to the Walash-Naupurdam metavolcanic rocks. Due to the deformation in the Sanandaj-Sirjan Zone along the eastern side of the Iraqi segment of NZSZ, the Gemo-Qandil Group was regionally metamorphosed during late Cretaceous (~?80 Ma). This tectono-compressional dynamics ultimately caused an oscillatory deformation against Arabian continental margin deposits as well. During these events, gabbro-diorite intrusion with high-grade contact metamorphic aureoles occurred near Bulfat. Thus, there is an overlap between regional and contact metamorphic conditions in the area. The earlier metamorphic characteristic can be seen only in places where the latter contact influence was insignificant. Generally, this can only observed at a distance of more than 2.5 km from the contact. According to petrographic details and field observations, the thermally metamorphosed metapelitic units of the metasediment have been completely assimilated, with only some streaks of biotite and relicts of initial foliation. They strongly resemble amphibolite-grade slices from the regional metamorphic rocks in the region. Metapelitic samples far from the intrusion give similar biotite cooling ages as the intrusive rocks. Thus, they may be affected by the same thermal event. ⁴⁰Ar/³⁹Ar dating of biotite in metapelite rocks of Bulfat by step-wise heating with laser gave average weighted isotopic ages of 34.78?±?0.06 Ma. This is interpreted as crystallization/recrystallization age of biotite possibly representing the time of cooling and uplift history of the Bulfat intrusion. Cooling and exhumation rates for the Bulfat gabbro-diorite rocks were estimated as ~?400 °C/Ma and ~?3.3 mm/year respectively. According to petrographic details, field observations and Ar/Ar dating concerning the contact metamorphism near Bulfat due to the gabbro-diorite intrusion, no significant deformation is visible during exhumation processes after the Paleogene tectono-thermal event, indicating that isotopic ages of 34.78?±?0.06 Ma could mark the timing of termination of the island arc activity in the Ophiolite-bearing terrane (upper allochthon).     

Slow cooling versus episodic fluid injections: Deciphering the Caledonian orogeny in Vestvågøy,Lofoten islands,Norway

The determination of the thermal (temperature–time) histories of high‐P metamorphic terranes has been commonly based on the concepts of slow cooling and closure temperatures. In this paper, we find that this approach cannot reconcile a geochronological data set obtained from the amphibolite‐facies allochthonous Leknes Group of the Lofoten islands, Norway, which reveals an extremely complex thermal history. Using detailed results from several different geochronometers such as ⁴⁰Ar/³⁹Ar, Rb–Sr and U–Pb, we show that a model invoking multiple, short‐lived thermal pulses related to hot‐fluid infiltration channelized by shear zones can reconcile this complicated data set. This model suggests that hot fluids infiltrated throughout basement shear zones and affected the overlying cold allochthon, partially resetting U/Pb rutile and titanite ages, crystallizing new zircon and produced identical ⁴⁰Ar/³⁹Ar and Rb/Sr ages in muscovite, biotite and amphibole in various rocks throughout the region. This paper shows the enormous potential of coupling laser Ar‐spot data with thermal modelling to identify and constrain the duration of short‐lived events. An optimal P–T–t history has been derived by modelling the age data from a previously dated large muscovite crystal (Hames & Andresen, 1996, Geology, 24 :1005) and using Zr‐in‐rutile thermometry which is consistent with all geochronological data and geological constraints from the basement zones and allochthon cover. This tectonothermal model history suggests that there have been three episodic hot‐fluid and ⁴⁰Ar‐free infiltration events, resulting in the total resetting of Ar ages during the Scandian (425 Ma) for 1 Ma at 650°C and two reheating events at 415 Ma for 400 ka at 650°C and at 365 Ma for 50 ka at 600°C, which are modelled as thermal spikes above an ambient temperature of 300°C. Independent confirmation of these parameters was provided by Pb‐diffusion modelling in rutile and titanite. The model suggests that the amphibolite facies rocks of the Leknes Group probably remained cold before being exhumed for at least 60 Ma (425–365 Ma) and successfully explains the presence of different minerals that crystallized or were totally/partially reset in the allochthon and in the basement. The migration of hot fluids for short periods of times within conduits extending through the basement and allochthon rock units is likely associated with episodic seismic activity during the Caledonian orogeny.     

古流体研究的无机地球化学方法综述

研究与成藏过程相关的古流体活动有助于深入认识油气成藏过程,从经济目的出发预测储层质量,精确分析不同阶段古流体活动对油气成藏的影响具有重要意义。目前国内外石油地质学家主要利用同位素地球化学、元素地球化学、流体包裹体分析等无机地球化学方法分析古流体活动特征及其对油气成藏的影响。在归纳前人研究成果的基础上,总结了各种无机地球化学方法的最新研究进展,认为同位素地球化学方法有助于分析古流体来源与成因,元素地球化学方法可示踪烃类流体的运移,流体包裹体分析技术结合岩相学研究可分析油气运移的时间、期次、相态、通道和油气藏的富集规律,并指出油气运移和聚集的有利方向。在运用无机地球化学方法研究古流体活动时不应局限于单一方法,综合利用多种无机地球化学方法更有利于全面分析古流体活动特征。     

Probabilistic frequency ratio model for groundwater potential mapping in Al Jaww plain,UAE

Arabian Journal of Geosciences - The United Arab Emirates, as a part of the Arabian Peninsula, is among the driest countries on earth. This study aims to map and explore new groundwater reservoirs...     

焦石坝-武隆构造带古流体活动差异及对页岩气保存条件的影响

焦石坝-武隆地区差异构造带发育,古流体活动复杂,对页岩气保存条件影响较为关键.以两类典型背斜(高陡背斜和箱状背斜)的裂缝脉为研究对象,基于裂缝分形理论和碳、氧、锶同位素地球化学理论,揭示出不同构造的古流体活动差异与页岩气保存条件优劣的耦合性.研究认为:(1)构造变形与古流体活动性存在耦合性.构造应力集中部位(如箱状背斜枢纽、隐伏断层)较构造其他部位具更强的流体活动性.(2)古流体示踪差异与页岩气保存条件存在耦合性.同位素地球化学揭示出二叠系-下三叠统以内源流体活动为主,封闭能力较好,盆内高陡背斜带和盆外残余向斜五峰-龙马溪组页岩气具备一定勘探前景;中寒武统-下奥陶统存在跨层流体活动的痕迹,封闭能力变差,盆外箱状背斜下寒武统筇竹寺组页岩气勘探风险加大.     

The Tethyan plume: geochemical diversity of Middle Permian basalts from the Oman rifted margin

According to palinspastic reconstructions, the Neo-Tethys opening took place during the Permian between the Cimmerian fragments in the north and the Indo-Arabian margin in the south. Igneous remnants of this opening are exposed in Oman within either the Hawasina nappes or the para-autochtonous Arabian platform exposed in the Saih Hatat tectonic window. They consist predominantly of pillowed basaltic flows among which three groups have been distinguished. Group 1 is tholeiitic and characterized by low TiO₂ and incompatible trace element contents, and a large range of Nd_i values. Group 1 basalts are associated with distal sediments and plot near the boundary of or within the MORB field in the Pb–Pb correlation diagrams and between the MORB and Bulk Silica Earth (BSE) fields in Nd_i–(²⁰⁶Pb/²⁰⁴Pb)_i diagram. Group 2 basalts are alkaline and differ from Group 1 ones by their higher TiO₂, La and Nb contents, and lower and more homogeneous Nd_i values (+3 to +5). Group 2 volcanics are similar to alkali basalts from oceanic islands and share with Group 1 similar initial Pb ratios. Group 3 consists of tholeiitic and alkali basalts which are interbedded either with carbonate-platform sediments from the Saih Hatat window or with distal sediments from the Hawasina Nappes. This group differs from Groups 1 and 2 by its low to negative Nd_i (+1.6 to −2). Group 1 likely derived from the mixing of depleted and enriched sources while Group 2 derived exclusively from an enriched source. There is no indication that continental crust was involved in the genesis of both Groups 1 and 2. In contrast, the low to negative Nd_i values of Group 3 suggest that the magmas of this group were contaminated by the Arabian continental crust during their ascent. The geochemical features of the Middle Permian plume-related basalts suggest thus that the basement of the Hawasina basin was not genuine oceanic crust but either the thinned Arabian rifted continental margin or the continent–ocean transition zone of the Neo-Tethys.     

Re-imbrication of the Hawasina allochthons in the Sufrat ad Dawh range,Oman Mountains

The Hawasina complex consists of deformed slope to basinal sedimentary rocks of Mesozoic age, emplaced on the Arabian continental margin in the Late Cretaceous as a series of nappes. This complex is well exposed in the Sufrat ad Dawh range where it is represented by the Hamrat Duru Group and the Wahrah Formation. Two generations of imbricate faults are recognized in this area. The first is the imbrication of the Hamrat Duru and the Wahrah units into two separate nappes. These nappes were then folded and cross-cut by a second set of imbricate faults, resulting in the systematic tectonic repetition of the Wahrah-Hamrat Duru Nappe stratigraphy. The late-stage faulting event correlates with the origin of re-imbrication structures documented from other parts of the Oman orogen, interpreted to be of a post-emplacement, Early Tertiary age. This implies that Tertiary deformation of the Oman allochthons was expressed at least in part as a continuation of nappe development, initiated during the Late Cretaceous orogeny.     

塔里木盆地古城墟隆起奥陶系多期古流体活动证据及意义

深部热流体活动与碳酸盐岩储层改造及油气成藏具有密切的关系.通过对塔里木盆地古城墟隆起奥陶系的11块样品的成岩观测和流体包裹体系统分析, 识别出3期古流体活动.结合埋藏史, 确定这3期流体活动的发生时间分别为: 第1期以第1世代高角度裂缝及网状裂缝充填方解石为代表, 推测与加里东晚期构造运动有关; 第2期为构造-热液白云岩化流体, 可能与塔里木盆地经历二叠纪末大规模的火山活动有关; 第3期以充填于孔、缝中央的晚期方解石为代表, 记录了晚期天然气充注事件, 发生于喜山期.第1期流体活动伴随的构造运动导致了早期充注的油气沥青化; 第2期流体活动对该区域的储层有建设性改造作用, 所形成的鹰山组内幕储层成为了区内重要的勘探目的层; 第3期流体活动记录了晚期天然气充注事件.因此, 工区应以寻找喜山晚期天然气藏为主要勘探目标.      

Structural and stratigraphic evolution of Abu Dhabi in the context of Arabia

The Emirate of Abu Dhabi is famed for its coastal carbonate, sabkhas and sand dunes; it is located in the NE part of the Arabian Plate, which formed during the Late Neoproterozoic (~820–750 Ma) by the accretion of island arcs and microcontinents to early Gondwana. Most of Arabia seems to have spent its existence within the Southern Hemisphere until it crossed the Equator during the Mesozoic; parts were involved in four glaciations, two in the Proterozoic (~750–630 Ma—Iceball or Slushball Earth?), and two more in the Palaeozoic (Late Ordovician and Permo-Carboniferous transition). In the early Palaeozoic the Arabian Plate was oriented about 90° counter clockwise relative to today’s poles. Gondwana later skirted the South Pole, migrating to the other side of the planet, eventually emerging the ‘right-way up’ with the Arabian Plate oriented to the poles more or less as seen today. Cold and temperate climate conditions ensured that for much of its early existence, Arabia was the site of mainly quartz-rich deposits. Later in the Neoproterozoic, however, extensive stromatolitic carbonate deposition took the lead, culminating around the Cambro-Precambrian boundary with deposition of the extensive Ara and Hormuz evaporites. Since south Arabia’s Permo-Carboniferous glaciation, the Arabian plate has been drifting northward, crossing temperate climatic zones conducive to fluvial and aeolian sandstone deposition and, from the later Permian, to tropical shallow-marine carbonates and evaporites In parallel with the above, the rifting of Gondwana opened an oceanic trough in the Late Permian off the NE flank of Arabia. Slope carbonates and deepwater Hawasina turbidites with a clear flow to the NE were deposited until they were obducted (together with associated ophiolites) in the Late Cretaceous on the edge of the Arabian plate in Oman and Iran. The deposition of widespread Early Silurian hydrocarbon source rocks in east-central Arabia was followed in the later Permian by extensive reservoir rocks with more during the mid-Late Mesozoic, giving rise to major oilfields both on- and off-shore, including Abu Dhabi. Arabia and Africa began to separate late in the Miocene with the opening of the Red Sea and Gulf of Aden. SSW–NNE compressive stresses caused uplift and volcanic activity in west Saudi Arabia and Yemen. Some products of erosion flowed eastward into Abu Dhabi. At the NE margin of Arabia, the Tethys Ocean narrowed, the NE flank of the newly forming Zagros Mountains of Iran is being subducted beneath southern Asia. To the SE, roughly coeval crustal compression adjacent to the Gulf of Oman led to uplift of the Oman Mountains and deposition of erosional products flanking the mountains mainly to the W and SW. The Oman Mountains are currently rising at about 2 mm/a, while northern Musandam is subsiding into the Strait of Hormuz at some 6 mm/a in association with subduction of the Arabian plate margin below the Eurasian plate. Alternations between polar glaciations and interglacials over the past few 100 ka resulted in considerable climatic changes over Arabia; slow glacial build-ups lasting some 80 to 120 ka led, somewhat erratically, to a fall in sea level of up to 130 m, to strong winds and the building of systems of extensive sand dunes such as the Rub’ al Khali. The joint Tigris–Euphrates river system flowed through a desert landscape, reaching the ocean only SE of the Strait of Hormuz. The peak of the last glaciation about 21 ka was followed by its rapid collapse and flooding of the Arabian Gulf to its present level between about 12 or 10 and 6 ka, a horizontal marine advance of some 200–300 m/a. Abu Dhabi is now the site of shallow-marine carbonates offshore and classical sabkhas and carbonate-rich sand dunes onshore.     

吐哈盆地西南缘古流体地质作用与砂岩型铀矿成矿作用初探

笔通过岩石后生蚀变与气-液包裹体特征研究,认为吐哈盆地西南缘中-下侏罗统水西沟群(J1—2sh)地层存在两期明显的古流体地质作用：早期酸性氧化古流体和晚期碱性还原古流体地质作用。前造成本区J1—2Sh地层由“黄色”及“红色”蚀变岩石组成的层间氧化带的广泛发育,该期古流体作用对铀成矿极其有利;后是本区“钙质层”形成的主要原因,对铀成矿不利。据气-液包裹体成分测试结果初步认为：古流体的组成主要是地下水及煤成天然气。     

含油气盆地流体分析方法体系及今后应加强研究的问题

含油气盆地流体分析牟指导油气勘探和开发,环境保护和防震减灾有重要的实践意义,同时为更大构造单元和更深层次上研究流休作用提供证据,本文主要针对油气勘探和开发,建立了盆地流体分析的方法体系,讨论了流体动力系统分析的原理及其应用前景,提出了在盆地流体分析中今后加强研究的若干具普遍意义的问题。     

United Arab Emirates limestones: impact of petrography on thermal behavior

The thermal behavior of selected limestones from representative localities of the United Arab Emirates is investigated for their suitability for soft-burnt lime production. The limestone samples were collected from the Ghalilah, Musandam, Shauiba, Muthaymimah, Dammam and Asmari formations. The samples were characterized for petrography, mineral and chemical composition, together with physico-mechanical characteristics. Investigative methods included transmitted light microscopy (TLM), cathodoluminescence (CLM) and scanning electron microscopy (SEM), as well as X-ray micro-tomography (μ-CT), XRD, XRF and Archimedes method. The limestone samples were fired in an electrical muffle furnace for 0.25, 0.5, 1 and 2 hours at 800, 900, 1,000 and 1,100 °C. After firing the lime grains were tested to determine their hydration rate and microfabric. The Ghalilah and Musandam limes show the lowest and highest maximum hydration rates, respectively, due mainly to the impure nature of the former, and the smaller lime crystallites and dominance of post-calcination micro-cracks of the latter. The Dammam and Asmari limes preserve a “ghost” microfabric of the original limestone. Higher allochem contents impose lower activation energy requirements for calcination, which implies earlier calcination of the allochems. The Musandam, Shauiba and Muthaymimah limestones may be useful for the production of reactive soft-burnt lime under the applied firing conditions, however, the Dammam and Asmari limestones need more advanced calcination conditions than the applied ones. The Ghalilah limestone was found to be unsuitable for the production of lime.     

The Oman Exotics: a key to the understanding of the Neotethyan geodynamic evolution

Abstract

The study of the exotic blocks of the Hawasina Nappes (Sultanate of Oman) leads to give apposit data that allow us to propose a new paleogeographic evolution of the Oman margin in time and space. A revised classification of exotic blocks into different paleogeographical units is presented. Two newly introduced stratigraphic groups, the Ramaq Group (Ordovician to Triassic) and the Al Buda’ah Group (upper Permian to Jurassic) are interpreted as tilted blocks related to the Oman continental margin. The Kawr Group (middle Triassic to Cretaceous) is redefined and interpreted as an atoll-type seamount. The paleogeography and paleoenvironments of these units are integrated into a new scheme of the Neotethyan rifting history. Brecciae and olistoliths of the Hawasina series are interpreted to have originated from tectonic movements affecting the Oman margin and the Neotethyan ocean floor. The breccias of late Permian age were generated by the extension processes affecting the margin, and by the creation of the Neotethyan oceanic floor. The breccias of mid-late Triassic age coincide in time with the collision of the Cimmerian continents with Eurasia. In constrast, the breccias of late Jurassic and Cretaceous age are interpreted as resulting to the creation of a new oceanic crust (Semail) off the Oman margin.     

http://www.sciencedirect.com/science/article/pii/S1674987115001516

The Semail ophiolite of Oman and the United Arab Emirates(UAE) provides the best preserved large slice of oceanic lithosphere exposed on the continental crust,and offers unique opportunities to study processes of ocean crust formation,subduction initiation and obduction.Metamorphic rocks exposed in the eastern UAE have traditionally been interpreted as a metamorphic sole to the Semail ophiolite.However,there has been some debate over the possibility that the exposures contain components of older Arabian continental crust.To help answer this question,presented here are new zircon and rutile U-Pb geochronological data from various units of the metamorphic rocks.Zircon was absent in most samples.Those that yielded zircon and rutile provide dominant single age populations that are 95-93 Ma,partially overlapping with the known age of oceanic crust formation(96.5-94.5 Ma),and partially overlapping with cooling ages of the metamorphic rocks(95-90 Ma).The data are interpreted as dating high-grade metamorphism during subduction burial of the sediments into hot mantle lithosphere,and rapid cooling during their subsequent exhumation.A few discordant zircon ages,interpreted as late Neoproterozoic and younger,represent minor detrital input from the continent.No evidence is found in favour of the existence of older Arabian continental crust within the metamorphic rocks of the UAE.