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祁连山区的含煤地层有中、上石炭统、上三叠统和下、中侏罗统等(图1),其中最具经济价值的煤系地层,是上石炭统和中侏罗统。从大地构造发展阶段看,祁连山在泥盆纪以前,属前地槽和地槽阶段;加里东运动后进入地台阶段;印支运动以后开始转入地洼阶段。 相似文献
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胜利油区石炭二叠系含煤地层层序地层学初探 总被引:1,自引:0,他引:1
胜利油区石炭二叠系含煤地层包括中石炭统本溪组,上石炭统太原组和下二叠统山西组。可识别出潮坪沉积体系,障壁岛-舄湖沉积体系和三角洲沉积体系三种体系单元。根据区域地质及古生物资料,确定了三个等时面,划分出2个层序14个准层序,每个层序包括低位域,海侵域及高位域,而以高位域最发育。纵观整个含煤地层的沉积演化过程,本溪组沉积期以滨浅海相为主;大原组沉积期为海陆交替相;山西组沉积期以三角洲相为主,总体表现为 相似文献
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湖北省主要煤系地层是下二叠统“梁山煤系”、上二叠统“龙潭煤系”和上三叠统-下侏罗统“香溪煤系”。“粱山煤系”和“龙潭煤系”主要分布在鄂东南、鄂西南地区,“香溪煤系”零星分布在鄂州-赤壁、远安-当阳、巴东-兴山、利川等地。研究认为:二叠纪成煤环境属近海型,而晚三叠世、早侏罗世属于内陆型。控制聚煤作用的主要因素有:①成煤环境为滨岸沼泽相区,沼泽发育之前沉积物若为砂质、粉砂质岩类,则含煤性好,反之若为泥质或粘土质岩类,则含煤性差;(爹煤系沉积的早期沉积基底剥蚀夷平为坳陷地带,到中晚期坳陷逐渐增大,能形成宽阔的聚煤(盆地)带;⑧地壳沉降幅度大,升降速度乎稳,泥炭沼泽发育时间长;④地壳振荡次数频繁,沉积旋回多,煤层厚度较大,含煤性好,反之.沉积旋回少或不完整,煤层少,且薄,含煤性差。通过分析有利的聚煤因素,提出了各煤系的找煤方向。 相似文献
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依据最新的《中国地层指南及中国地层指南说明书》和《中国区域年代地层(地质年代)表说明书》,在区域生物地层对比的基础上,本文重新厘订了安徽省华北型石炭-二叠纪年代地层系统,石炭系二分,二叠系三分。区内石炭系仅沉积上石炭统,二叠系齐全,下二叠统、中二叠统、上二叠统均发育。 相似文献
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松南地区构造-地层层序与盆地演化 总被引:3,自引:0,他引:3
松南地区地跨兴蒙-吉黑褶皱带、华北板块及其北缘增生带等大地构造单元,主要发育一系列晚中生代小规模断陷沉积盆地,这些断陷盆地具有“多阶段演化和后期强烈改造”特征,目前已在彰武、昌图、茫汉等断陷发现了油气田。如何认识这些强烈改造断陷的含油气潜力、持续拓展油气发现是目前油气勘探研究的重点,剖析其构造-地层层序,解析盆地演化历史,是深入认识地区的油气地质条件、开展油气资源预测的重要基础。本文基于研究区最新的探井和地震资料,并结合周缘1:250 000区域地质填图成果,建立研究区内的地层系统;依据区域不整合面的发育特征,划分构造-地层层序与盆地演化阶段,探讨盆地形成历史。研究认为,松南地区的沉积盆地主要是在环太平洋构造体制的控制下发育的;发育下白垩统义县组底部、下白垩统泉头组底部、上白垩统四方台组底部等3个区域性不整合面,据此划分出基底构造层、断陷构造层、坳陷构造层、盆地反转构造层等四套构造-地层层序;相应地,松南地区经历了基底形成期、早白垩世断陷期、早白垩世末-晚白垩世坳陷期、晚白垩世末盆地反转期等四个盆地演化阶段;松南地区构造演化控制了区内含油气系统的发育与油气分布规律,下白垩统断陷构造层是目前勘探的主要目的层,油气地质条件优越,具有较好的油气勘探前景。 相似文献
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我们在云南省墨江县坝溜公社下蜜地地区工作时,发现了晚石炭世含煤地层。这套地层,无论在沉积相方面,还是在岩性组合上,都明显地不同于扬子区和华南区的上石炭统;但却与我国北方的主要含煤地层上石炭统太原群有相似之处。为了与我国南方常见的上石炭统马平群相区别,我们将这一套含煤地层称为上石炭统下蜜地组(C_(3x))。 相似文献
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<正> 广州地区下三叠统地层,1981年谌建国、徐光洪在《广东省二叠纪煤系含煤性研究》一文提到广州加禾有含Claraia的地层。1983年吴起俊在加禾猪木岭测剖面采标本,于1984年在省地质学会提交《广州市郊下三叠统的初步研究》文章。笔者在1977年曾得到广东省“52”项在猪木岭采到的标本,经鉴定为Claraia,将原认为上二叠统地层划为下三叠统。 相似文献
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我国腐植煤的还原性质及其与沉积环境的关系 总被引:3,自引:2,他引:3
一、不同还原性腐植煤的基本特征在研究华北聚煤区东部晚古生代太原组(C3)和山西组(P11)煤性质差别及显微特征的基础上,作者认为除煤岩成分和变质程度外,还存在着影响煤质的第三个成因因素--还原性质。 相似文献
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A series of geochemical anomalies of Pt and Pd were found in 1 358 recombined samples from a geochemical stream sediment survey in eastern Yunnan (云南) Province, China. Chemical optical emission spectroscopy, X-ray fluorescence analysis, and inductively coupled plasmas atomic emission spectrometry analyses of 22 elements and chemical compositions of 21 samples from coal-bearing strata from the Late Paleozoic, Mesozoic, and Cenozoic show Pt and Pd concentrated to some extent in coal rocks, with Pd/Pt相似文献
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五风井田位于贵州省大方县城东侧,面积89.22km^2,含煤地层为二叠系上统龙潭组,主要可采煤层为6中、26、33号煤层,煤炭总资源量26 130万t。井田内主要含水层为三叠系茅草铺组岩溶溶洞含水层(T1m),夜郎组玉龙山灰岩岩溶裂隙含水层T1y2),二叠系中统长兴组岩溶裂隙含水层(P3c)、茅口组岩溶溶洞-暗河含水层(P2m)。矿床属于以岩溶充水为主,水文地质条件中等的矿床。井田的充水水源为地表水、地下水和小煤矿、采空区的老窑积水,充水通道为断裂破碎带及采矿冒落裂隙带。 相似文献
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Bat-Orshikh Erdenetsogt Insung Lee Delegiin Bat-Erdene Luvsanchultem Jargal 《International Journal of Coal Geology》2009,80(2):87-104
This paper presents geological settings, stratigraphy, coal quality, petrography, reserves and the tectonic history of the Mongolian coal-bearing basins. This is based on a synthesis of the data from nearly 50 coal deposits. The results of ultimate and proximate analyses, and calorific value, maceral composition and vitrinite reflectance data is given.The coal deposits of Mongolia tend to become younger from west to east and can be subdivided into two provinces, twelve basins, and three areas. Main controlling factor of coal rank is the age of the coal bearing sequences. Western Mongolian coal-bearing province contains mostly high rank bituminous coal in strata from Late Carboniferous. The basins in southern Mongolia and the western part of central Mongolia have low rank bituminous coal in strata from the Permian. The northern and central Mongolian basins contain mainly Jurassic subbituminous coal, whereas the Eastern Mongolian province has Lower Cretaceous lignite. The Carboniferous, Permian and Jurassic coal-bearing sequences were mainly deposited in foreland basins by compressional tectonic event, whereas Cretaceous coal measures were deposited in rift valleys caused by extensional tectonic event. Petrographically, Mongolian coals are classified as humic type. Vitrinite/huminite groups of Carboniferous, Permian, and Cretaceous coal range from 44.9% to 82.9%. Inertinite group varies between 15.0% and 53.3%, but liptinite group does not exceed more than 7%. Jurassic coals are characterized by high percentages of vitrinite (87.3% to 96.6%) and liptinite groups (up to 11.7%). This might be explained by paleoclimatic conditions. Mongolian coal reserves have been estimated to be 10.2 billion tons, of which a predominant portion is lignite in the Eastern Mongolian province and coking coal in the South Gobi basin. 相似文献
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With the aim of constraining the influence of the surrounding plates on the Late Paleozoic–Mesozoic paleogeographic and tectonic evolution of the southern North China Craton (NCC), we undertook new U–Pb and Hf isotope data for detrital zircons obtained from ten samples of upper Paleozoic to Mesozoic sediments in the Luoyang Basin and Dengfeng area. Samples of upper Paleozoic to Mesozoic strata were obtained from the Taiyuan, Xiashihezi, Shangshihezi, Shiqianfeng, Ermaying, Shangyoufangzhuang, Upper Jurassic unnamed, and Lower Cretaceous unnamed formations (from oldest to youngest). On the basis of the youngest zircon ages, combined with the age-diagnostic fossils, and volcanic interlayer, we propose that the Taiyuan Formation (youngest zircon age of 439 Ma) formed during the Late Carboniferous and Early Permian, the Xiashihezi Formation (276 Ma) during the Early Permian, the Shangshihezi (376 Ma) and Shiqianfeng (279 Ma) formations during the Middle–Late Permian, the Ermaying Group (232 Ma) and Shangyoufangzhuang Formation (230 and 210 Ma) during the Late Triassic, the Jurassic unnamed formation (154 Ma) during the Late Jurassic, and the Cretaceous unnamed formation (158 Ma) during the Early Cretaceous. These results, together with previously published data, indicate that: (1) Upper Carboniferous–Lower Permian sandstones were sourced from the Northern Qinling Orogen (NQO); (2) Lower Permian sandstones were formed mainly from material derived from the Yinshan–Yanshan Orogenic Belt (YYOB) on the northern margin of the NCC with only minor material from the NQO; (3) Middle–Upper Permian sandstones were derived primarily from the NQO, with only a small contribution from the YYOB; (4) Upper Triassic sandstones were sourced mainly from the YYOB and contain only minor amounts of material from the NQO; (5) Upper Jurassic sandstones were derived from material sourced from the NQO; and (6) Lower Cretaceous conglomerate was formed mainly from recycled earlier detritus.The provenance shift in the Upper Carboniferous–Mesozoic sediments within the study area indicates that the YYOB was strongly uplifted twice, first in relation to subduction of the Paleo-Asian Ocean Plate beneath the northern margin of the NCC during the Early Permian, and subsequently in relation to collision between the southern Mongolian Plate and the northern margin of the NCC during the Late Triassic. The three episodes of tectonic uplift of the NQO were probably related to collision between the North and South Qinling terranes, northward subduction of the Mianlue Ocean Plate, and collision between the Yangtze Craton and the southern margin of the NCC during the Late Carboniferous–Early Permian, Middle–Late Permian, and Late Jurassic, respectively. The southern margin of the central NCC was rapidly uplifted and eroded during the Early Cretaceous. 相似文献
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《International Geology Review》2012,54(3):282-295
The development of the Yugoslavian, Albanian, and Italian segments of the Mediterranean geosyncline is compared, using the province of Montenegro as the standard for correlation of the paleogeographic analysis during the Alpine tectonic cycle. The tectonic zones, characteristic of the Montenegro area are four in number and given as the Maritime zone with rocks ranging from Upper Carboniferous to Oligocene; the old Montenegro zone consisting of Triassic, Jurassic, Cretaceous and upper Oligocene sediments; the Ku?a zone deposits ranging from Upper Permian through Mesozoic; and the Durmitor zone with Devonian, Carboniferous, Permian, Triassic, and Jurassic sedimentary and volcanic-sedimentary bodies and Upper Cretaceous flysch.—IGR Staff. 相似文献
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吐鲁番-哈密盆地从晚二叠世到晚第三纪经历了复杂的,多旋回的沉积构造演化历史,造成主要地层间均以不整合为界。盆地内沉积相类型丰富,沉积环境随时间的推移而发生改变。在晚石炭世,盆地北部为浅海环境;到晚二叠世,沉积环境由海相转变为陆相,并在上二叠统下部形成大量冲积相或河流相粗碎屑沉积;在三叠纪,沉积物主要形成于冲积相或河流-湖泊环境中,古气候则由干旱转为温暖湿润。早、中侏罗世,沉积环境以湖泊-沼泽相为主;到晚侏罗世,则以辫状河流相为主及干旱气候为特征。在白垩纪,盆地的沉积范围大为缩小,以湖泊环境为主;第三纪,沉积范围则扩大到整个盆地,沉积相以辫状河流及冲积相为特征,沉积气候干旱,局部地区接受了盐类沉积。古流向分析显示,吐-哈盆地具有复杂的沉积搬运体系。在盆地南侧,沉积物搬运方向总是由南向北,表明觉罗塔格山是盆地的主要物源区;而在盆地北侧,博格达山自晚侏罗世开始隆起,构成盆地的另一新的物源区,沉积物搬运方向由北向南。在白垩及第三纪,博格达山成为盆地的主要物源区。 相似文献
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滇西亲冈瓦纳相生物群特征及地层时代的重新厘定 总被引:14,自引:1,他引:14
滇西保山地区丁家寨组及其上覆卧牛寺组,前人根据其中(虫筳)类化石定为上石炭统(马平阶),沿用至今。笔者在该区多门类化石中,见到不同时代的化石混积在一起,包括异地再沉积的早石炭世腕足类Syringothyris,石炭纪的(虫筳)类、珊瑚等。原地埋藏的腕足类有Steriochia litostyla等,并保存有完好的壳刺。厘定后的时代为Sakmarian晚期至Artinskian,它可与西藏的冈瓦纳相地层及生物群进行对比。 滇西腾冲地区空树河组及其上覆的岩子坡组,前人因其含(虫筳)Triticites,Quasifusulina等也定为上石炭统。实际上,空树河组中、上部的多门类化石(包括腕足类、苔藓虫、单体珊瑚和微古植物等),与丁家寨组相似,具有强烈的二叠纪面貌,与冈瓦纳相更为接近。厘定空树河组时代为Sakmarian—Chihsian,它与西藏的相应地层可以很好地进行对比。 相似文献