四川江油马角坝刺林包剖面二叠-三叠系间粘土岩研究

二叠-三叠纪之交华南地区普遍发育火山成因的粘土岩,其对于了解二叠纪末大规模火山活动及扬子板块碎屑物质来源具有重要意义。本文对扬子西缘马角坝刺林包剖面飞仙关组底部粘土岩进行了碎屑锆石U-Pb定年及原位Hf同位素测试、X衍射和全岩地球化学分析,以揭示粘土岩的岩石成分及物源信息。镜下特征、X衍射及主量元素特征表明岩石中粘土矿物主要为伊利石,含少量方解石、石英。碎屑锆石年龄显示,特征峰值年龄主要集中在2 615~2 383、1 868~1 328、1 186~778和430~246 Ma,并出现~250 Ma特征高峰,结合原位Hf同位素特征表明锆石与秦岭造山带、华南典型PTB剖面粘土岩及峨眉山大火成岩省具有较高的相似性。同时,通过微量、稀土元素分析发现粘土岩中Zr、Hf、Th、Cr、Co、Ti相对富集,与华南典型PTB粘土岩和峨眉山玄武岩相近,并结合构造背景及锆石特征,综合认为刺林包剖面PTB粘土岩来自于秦岭造山带及龙门山岛链局部剥蚀区、二叠纪末火山活动和峨眉山大火成岩省剥蚀岩体。     

从成岩-蚀变特征探讨塔深1井白云岩储层成因

塔深1井钻遇的寒武系地层属于中寒武统阿瓦塔格组和上寒武统丘里塔格下亚群。阿瓦塔格组以灰色-深灰色粉晶-细晶藻白云岩为主,丘里塔格下亚群以灰色-浅灰色晶粒结构白云岩与残余亮晶结构白云岩为主。藻白云岩在阴极发光下以明亮的中等强度砖红色-桔黄色为主要特点,具有相对偏重的δ18O值(-6.3‰~-4.5‰,平均为-5.3‰,VPDB)、相对较高的稀土总量以及与正常海相碳酸盐岩相似的稀土配分样式。晶粒白云岩与残余亮晶结构白云岩在阴极发光下以偏暗的中等强度蓝紫色-砖红色为主要特点,具有相对偏轻的δ18O值(-9.2‰~-5.7‰,平均为-7.5‰,VPDB)、相对偏低的稀土总量、Eu正异常与重稀土明显亏损为特点的稀土配分模式。阿瓦塔格组和丘里塔格下亚群白云岩在上述岩石学特征和地球化学特征上的差异表明储层发育的成岩-蚀变过程存在差异。研究认为,埋藏较深的阿瓦塔格组优质储层的形成受多种因素控制,其中准同生期大气淡水作用下石膏结核的溶解及非稳定碳酸盐矿物的溶解奠定了基础,后期成岩改造及流体作用进行了强化,局部遭充填破坏。     

辽西金羊盆地北票组烃源岩生物标志化合物特征及意义

采用气相色谱、气相色谱-质谱技术,研究了辽西金羊盆地北票组烃源岩的生物标志化合物特征,剖析其蕴含的有机质生源、沉积环境、有机质热演化程度等信息.金羊盆地北票组烃源岩样品的正构烷烃的正构烷烃分布图（m/z 85）峰型以"前峰型"的单峰态分布为主,表现出成熟源岩的分布特征;甾烷C₂₉-αββ/（ααα+αββ）值介于0.35~0.58之间,平均为0.50,表明金羊盆地北票组绝大多数烃源岩处于成熟阶段,部分已达生油高峰或高成熟阶段.Pr/Ph值主要介于1.0~3.0之间,表现出弱的姥鲛烷优势;Pr/nC₁₇-Ph/nC₁₈交汇图判识北票组烃源岩以Ⅲ型为主,三环萜烷呈C₂₀为主峰的正态分布,整体表现C₂₄四环二萜含量很高,C₂₄四环二萜/C₂₆三环萜烷比值基本都大于1,SZK01、SZK03井烃源岩的三环萜烷/藿烷比值都低于0.4,烃源岩伽马蜡烷指数分布在0.02~0.30之间,平均值为0.12,说明金羊盆地北票组烃源岩形成于偏氧化性的微咸水-淡水的浅水沉积环境,为典型高等植物输入的沉积相带.     

油铀兼探的找矿思路在松辽盆地的应用——以中央拗陷区南部为例

以"油铀兼探"的找矿思路,带动松辽盆地中南部开展砂岩型铀矿调查选区及钻探验证工作.将异常强度250 API和450 API确定为划分潜在铀矿孔、潜在铀矿化孔和正常孔的关键技术指标,对中央拗陷区南部1572个钻孔进行异常筛查工作.排查发现潜在铀矿孔362个,潜在铀矿化孔223个.对191号钻孔和36号钻孔进行钻探验证,发现1个工业孔、1个异常孔.认为区内寻找砂岩型铀矿的有利地段为油田区反转构造形成的隆起区边部四方台组河流相砂体,并总结了中央拗陷区南部6种主要控矿因素.     

辽西地区北票组烃源岩生物标志化合物特征的差异性

北票组是辽西地区重要的一套煤系地层,被认为是该区油气勘探的重要目的层.坤头营子剖面和卧龙剖面是该区较为有代表性的北票组地层剖面,对于研究北票组的沉积环境、有机质来源等具有重要意义.采用气相色谱-质谱（GC-MS）等技术对2个剖面的烃源岩样品进行了分析测试,结果显示两组样品表现出不同的地球化学特征.坤头营子剖面的烃源岩样品抽提物正构烷烃的质量色谱图均为单峰态,主峰碳数以C₁₉为主,姥鲛烷/植烷比值（Pr/Ph）在3.0~4.0之间;甾烷系列中以C₂₉甾烷为优势,C₂₃三环萜烷含量相对较低,伽马蜡烷指数低（平均0.08）.取自卧龙剖面的样品质量色谱图大部分呈现双峰态,Pr/Ph值低;甾烷系列中C₂₇占优势,萜烷系列中C₂₃三环萜烷含量高,具有较高的伽马蜡烷含量（平均0.23）,且各项生标成熟度参数均已达到异构平衡化阶段.结合样品的全岩分析显微组分分析结果,认为两者主要差异可能是剖面附近的侵入岩造成,北票组烃源岩有机质具有陆源高等植物和低等水生生物双重来源,以陆源高等植物为主.     

三江盆地前进坳陷油气地质调查新进展

随着东北大型含油气沉积盆地油气勘探难度越来越大,老油田开发程度已进入中后期,亟需新的油气区接替。三江盆地作为松辽盆地外围7个一级远景盆地之一,具有较大的油气勘探潜力。最近在三江盆地前进坳陷开展了一系列油气地质调查工作,在中生界泥页岩、晚古生界暗色泥岩地层及硅质岩生烃潜力方面取得了新的进展与认识,对评价该区油气资源潜力、进行下一步油气勘探工作具有重要意义。     

Occurrence and conceptual sedimentary model of Cambrian gypsum-bearing evaporites in the Sichuan Basin,SW China

During the Cambrian, gypsum-bearing evaporites formed in the Sichuan Basin, SW China. These rocks are important for oil and gas sealing, but details of their distribution and origin are not well established. This study examines the regional distribution and origin of the gypsum-bearing evaporites using a comprehensive analysis of drilling data from 34 wells, 5 measured cross-sections in the basin and surrounding area, and 96 maps of area-survey data. Results show that in the stratigraphic succession, the gypsum-bearing evaporites occur mainly in the Lower Cambrian Longwangmiao Formation, the Middle Cambrian Douposi Formation, and the Middle-Upper Cambrian Xixiangchi Group. Geographically, the rocks are found mainly in the southeastern part of the basin, and the distribution of deposits shows an overall SW-NE trend. The sedimentary environments for evaporite formation were evaporative lagoon and inter-platform basin in a platform setting. Gypsum was generated by the underwater concentration of sea water in a strongly evaporative environment. Both an evaporative restricted platform and a mixeddeposition restricted platform model appear to be applicable to the development of gypsum in the Sichuan Basin. The gypsum-bearing evaporites with the best sealing capacity are located mostly in the southeastern part of the basin. These constraints can be applied directly to regional exploration, and have implications for the regional paleogeography and paleoclimate.     

The geothermal formation mechanism in the Gonghe Basin: Discussion and analysis from the geological background

The Gonghe Basin, a Cenozoic down-warped basin, is located in the northeastern part of the Qinghai-Xizang (Tibetan) Plateau, and spread over important nodes of the transfer of multiple blocks in the central orogenic belt in the NWW direction. It is also called “Qin Kun Fork” and “Gonghe Gap”. The basin has a high heat flow value and obvious thermal anomaly. The geothermal resources are mainly hot dry rock and underground hot water. In recent years, the mechanism of geothermal formation within the basin has been controversial. On the basis of understanding the knowledge of predecessors, this paper proposes the geothermal formation mechanism of the “heat source–heat transfer–heat reservoir and caprock–thermal system” of the Gonghe Basin from the perspective of a geological background through data integration-integrated research-expert, discussion-graph, compilation-field verification and other processes: (1) Heat source: geophysical exploration and radioisotope calculations show that the heat source of heat in the basin has both the contribution of mantle and the participation of the earth’s crust, but mainly the contribution of the deep mantle. (2) Heat transfer: The petrological properties of the basin and the exposed structure position of the surface hot springs show that one transfer mode is the material of the mantle source upwells and invades from the bottom, directly injecting heat; the other is that the deep fault conducts the deep heat of the basin to the middle and lower parts of the earth’s crust, then the secondary fracture transfers the heat to the shallow part. (3) Heat reservoir and caprock: First, the convective strip-shaped heat reservoir exposed by the hot springs on the peripheral fault zone of the basin; second, the underlying hot dry rock layered heat reservoir and the upper new generation heat reservoir and caprock in the basin revealed by drilling data. (4) Thermal system: Based on the characteristics of the “heat source-heat transfer-heat reservoir and caprock”, it is preliminarily believed that the Gonghe Basin belongs to the non-magmatic heat source hydrothermal geothermal system (type II2₁) and the dry heat geothermal system (type II2₂). Its favorable structural position and special geological evolutionary history have given birth to a unique environment for the formation of the geothermal system. There may be a cumulative effect of heat accumulation in the eastern part of the basin, which is expected to become a favorable exploration area for hot dry rocks.     

基于航空重磁特征对突泉盆地构造的认识

为获取突泉盆地航空物探基础地质资料,为油气调查评价提供参考,中国国土资源航空物探遥感中心在该盆地开展了1:10万航空重磁综合调查工作。利用最新的航空重磁资料及实测岩石物性数据,对突泉盆地及其邻区重磁异常特征进行研究,分析航空重磁异常与地层展布、断裂活动、岩浆岩体的分布关系,重点探讨盆地的基底性质。结果表明,研究区航空重力异常与航磁异常在强度、范围、形态、梯度和走向等方面具有一定的规律性,该区断裂体系分布与重磁场特征明显相关,NNE-NE向、NW向及NE向3组断裂明显控制盆地沉积岩体及岩浆岩体的展布,盆地基底由下古生界浅变质岩系和前古生界中等变质岩系构成。     

Down‐slope facies variability within deep‐water channel systems: Insights from the Upper Cretaceous Cerro Toro Formation,southern Patagonia

In southern Patagonia, outcrops of the Upper Cretaceous Cerro Toro Formation preserve a >150 km long deep‐water axial channel belt in the Magallanes–Austral Basin, providing a unique opportunity to investigate longitudinal variations in the depositional characteristics of a deep‐water channel system. This study documents sedimentological, stratigraphical and geochronological data from the Cerro Toro Formation in the Argentine sector of the basin. New results are integrated with previous work from the Chilean basin sector to conduct a basin‐scale comparison of the timing of deposition, provenance and lithofacies proportions. The Cerro Toro channel belt includes a nearly 1000 m thick section characterized by high‐density turbidites and mass‐wasting deposits. Two ash beds from the base of the section yield U–Pb zircon ages of 90·4 ± 2 Ma and 88·0 ± 3 Ma, indicating similar initiation ages as documented in the Chilean sector. The U–Pb detrital zircon age spectra from samples in the study area reveal similar provenance trends to samples from the Chilean basin sector, with peak age populations at 310 to 260 Ma, 160 to 135 Ma and 110 to 82 Ma. The maximum depositional age of the channel belt in the Argentine sector is 87·8 ± 1·5 Ma and all new geochronology data corroborate an 86 to 80 Ma depositional age for the main Cerro Toro channel belt. Statistical analyses of 7370 beds from nearly 8000 m of new and previously published stratigraphic sections along the entire outcrop belt suggest progressive variations in the down‐system proportion of lithofacies. In the up‐slope region, lithofacies representing mass wasting processes (for example, debris‐flow and mass‐transport deposits) account for ca 29% of the stratigraphic thickness, as opposed to 5% in the down‐slope region of the channel belt, where turbidity current deposits are more prevalent. The proportion of beds >1 m thick also decreases systematically down slope, particularly for conglomeratic turbidite deposits. This work highlights that: (i) the proportion of thick beds and distribution of lithofacies are key down‐system changes in the stratigraphic fill of this deep‐water channel belt; (ii) detrital zircon trends suggest a relatively well‐mixed longitudinal depositional system; and (iii) geochronology of the main Cerro Toro outcrop belt supports but does not necessitate the model of a single, roughly age‐equivalent, channel system. This study has implications for understanding the downslope variability in depositional processes, stratigraphic architecture and reservoir quality of submarine channel systems.