南高加索古地理与远景:从黑海到里海的石油系统要素

IF 1.8 4区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY Journal of Petroleum Geology Pub Date : 2021-06-26 DOI:10.1111/jpg.12792
G. A. Blackbourn, N. Tevzadze, A. Janiashvili, O. Enukidze, V. Alania
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引用次数: 8

摘要

本文介绍了九幅中生代和新生代古地理图,从一个新的角度说明了南高加索地区的石油远景,并将其作为更广泛的高加索地区的一部分。以前,油气系统的要素——储层、烃源和密封岩性及其形成时间——大多是在单个子盆地或许可区块内进行研究的,区域认识有限。重点是格鲁吉亚和阿塞拜疆的陆上前景;阿塞拜疆东部和里海南部著名的上新世生产系列不在考虑范围内。大高加索盆地(GCB)形成于早侏罗世古特提斯关闭后,尽管构造发生了变化,但一直保持着重要的特征,直到始新世末的逆冲和隆升将盆地转变为大高加索山脉。到托瓦良期,沿其东北边缘发育了一个主要的三角洲体系,而南部的外高加索地块大部分被浅海覆盖,沉积物供应有限。南高加索地区的巴约修火山活动伴随着大高加索盆地构造的改变和拉斑岩脉的侵入,可能与新特提斯向北俯冲的开始有关。海平面上升导致了GCB三角洲系统的废弃。巴统时期南高加索的相对隆起形成了低地,周围环绕着边缘环境,在这些边缘环境中沉积了海陆沉积物和煤。侏罗系烃源岩包括大高加索盆地内沉积的深海相页岩和煤;他们的潜力在格鲁吉亚和阿塞拜疆境内的大量渗透中得到证实。多种中侏罗统砂岩为潜在储集层。碳酸盐岩以晚卡洛世为主,北高加索地区广泛发育牛津礁和晚侏罗世蒸发岩盆地。格鲁吉亚的层状硬石膏包含潜在的密封。在白垩纪,浅海碎屑再次在高加索地区广泛分布,后来被包括白垩样灰岩在内的碳酸盐所取代。深海相条件在大高加索盆地持续存在,该盆地变得不那么明确,并分裂成单独的沉积中心。裂缝性白垩系是北高加索地区已知的储层,也是南高加索地区的远景储层。古近纪南高加索南部的隆升导致沉积物向北运移,形成格鲁吉亚东部和阿塞拜疆西部E-W - se - wsw演化盆地。这些盆地内的海相沉积形成了储层,包括格鲁吉亚东部厚的断裂火山浊积岩。晚始新世开始,这里的沉积物供应减少,使得富含有机物的限制性海相烃源岩得以积聚。始新世末期GCB的快速隆起与逆冲作用导致了大高加索山脉的出现。在渐新世和早中新世,北高加索地区、阿塞拜疆部分地区和格鲁吉亚西部地区,丰富的迈科比烃源岩沉积在限制海相条件下,但在晚始新世烃源岩更为重要的格鲁吉亚东部地区,它们被较粗的碎屑所稀释。晚中新世整个高加索地区的隆升导致海相渐进式退行,形成了冲积砂和浅海相砂的潜在储层。
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SOUTH CAUCASUS PALAEOGEOGRAPHY AND PROSPECTIVITY: ELEMENTS OF PETROLEUM SYSTEMS FROM THE BLACK SEA TO THE CASPIAN

Nine Mesozoic and Cenozoic palaeogeographic maps are presented to illustrate the petroleum prospectivity of the South Caucasus from a fresh perspective and as part of the wider Caucasus region. Previously, elements of petroleum systems – reservoir, source and sealing lithologies, and the timing of their formation – have mostly been examined within individual sub-basins or licence blocks, and regional understanding has been limited. Emphasis is placed here on the onshore prospectivity of Georgia and Azerbaijan; the well-known Pliocene Productive Series of eastern Azerbaijan and the southern Caspian is not considered.

The Great Caucasus Basin (GCB) formed in the Early Jurassic following closure of PalaeoTethys, and remained a significant feature, despite structural modifications, until end-Eocene underthrusting and uplift converted the basin into the Greater Caucasus mountains. By the Toarcian a major delta system had developed along its northeastern margin, while the Transcaucasus block to the south was mostly covered by a shallow sea with limited sediment supply. Bajocian volcanism across the South Caucasus was accompanied by modification of the structure of the Great Caucasus Basin with the intrusion of tholeiitic dykes, possibly associated with onset of northward NeoTethyan subduction. Rising sea levels led to the abandonment of the GCB delta system. Relative uplift of the South Caucasus in the Bathonian created lowlands surrounded by marginal settings in which paralic deposits and coals were laid down. Jurassic hydrocarbon source rocks include deep-marine shales deposited within the Great Caucasus Basin together with coals; their potential is confirmed by numerous seeps within both Georgia and Azerbaijan. Various Middle Jurassic sandstones are potential reservoirs.

Carbonates dominated by the late Callovian, with widespread development of Oxfordian reefs and of Late Jurassic evaporite basins in the North Caucasus. Bedded anhydrites in Georgia comprise potential seals. Shallow-marine clastics again became widespread across the Caucasus in the Cretaceous, later replaced by carbonates including chalk-like limestones. Deeper-marine conditions persisted in the Great Caucasus Basin, which became less well-defined and split into separate depocentres. Fractured chalks are known reservoirs in the North Caucasus and prospective reservoirs in the South Caucasus.

Uplift of the southern South Caucasus during the Paleogene led to northward transport of sediment into evolving E-W to ESE-WSW basins in eastern Georgia and western Azerbaijan. Marine deposits within these basins form reservoirs, including thick fractured volcanogenic turbidites in eastern Georgia. Reduced sediment supply here at the start of the Late Eocene allowed organic-rich restricted-marine source rocks to accumulate.

Rapid uplift of the GCB associated with underthrusting at the end of the Eocene led to emergence of the Greater Caucasus mountains. The prolific Maikopian source rocks were deposited in restricted-marine conditions during the Oligocene and Early Miocene over the North Caucasus, parts of Azerbaijan and western Georgia, but they are diluted by coarser clastics in eastern Georgia where the Late Eocene source is more significant. Later Miocene uplift of the entire Caucasus region resulted in progressive marine regression, and the formation of potential reservoirs in alluvial and shallow-marine sands.

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来源期刊
Journal of Petroleum Geology
Journal of Petroleum Geology 地学-地球科学综合
CiteScore
3.40
自引率
11.10%
发文量
22
审稿时长
6 months
期刊介绍: Journal of Petroleum Geology is a quarterly journal devoted to the geology of oil and natural gas. Editorial preference is given to original papers on oilfield regions of the world outside North America and on topics of general application in petroleum exploration and development operations, including geochemical and geophysical studies, basin modelling and reservoir evaluation.
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