INFLUENCE OF PLEISTOCENE GLACIATION ON PETROLEUM SYSTEMS AND GAS HYDRATE STABILITY IN THE OLGA BASIN REGION, BARENTS SEA

IF 1.8 4区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Sebastian Amberg, Ralf Littke, Rüdiger Lutz, Peter Klitzke, Victoria Sachse
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引用次数: 0

Abstract

This study presents the results of a 2D numerical basin and petroleum systems model of the Olga Basin in the NW Barents Sea offshore northern Norway, a frontier exploration area in which there are abundant seafloor oil and gas seepages. The effects of Pleistocene ice sheet advances on rock properties and subsurface fluid migration in this area, and on seafloor hydrocarbon seepage, are not well understood. The 2D numerical model takes account of recurrent ice advances and retreats, together with related erosional and temperature effects, and investigates the influence of these parameters on fluid migration. Model results show that Pleistocene glaciations reduced the temperature in the sedimentary succession in the Olga Basin by up to 20 °C, for example in the uppermost Cretaceous and Jurassic sediments which underlie the seafloor down to a depth of 0.5 to 1 km. The decrease in temperature was in general predominantly related to the intensity of glacial erosion, which was set in this study to a depth of 600 m based on previous studies. Hydrocarbon fluids expelled from potential thermogenic source rocks of Carboniferous to Triassic ages on the SW margin of the Olga Basin migrated to the seafloor through permeable carrier beds. However, fluid migration to the surface in the NE of the study area took place along fault conduits. In a closed fault model scenario, only 0.3 Mt of hydrocarbons are modelled to have migrated along the 0.5 km wide model section; in a second scenario with partially open faults, about 22 Mt of hydrocarbons, representing about 11% of the total hydrocarbons generated by potential thermogenic source rocks in the study area, were lost to the surface during the Pleistocene. The potential for microbial methane generation in the Olga Basin was limited both during the Pleistocene and at the present day due to the significant reduction in temperature during glacial episodes, and due to the intense glacial-related erosion of the Mesozoic to Cenozoic stratigraphy. During glacial stages, the gas hydrate stability zone beneath the ice sheet is modelled to have extended to a depth of up to 900 m for a pure methane composition, and to a depth of up to 1100 m for a possible thermogenic-sourced mixed gas composition of 90% methane, 7% propane and 3% ethane. Gas hydrates with this mixed composition are modelled to have been stable in the Olga Basin during the last three glacial advances and into the present. These modelling results provide an insight into the key factors controlling the migration and surface leakage of hydrocarbon fluids in the Olga Basin region, and into the effects of glaciations on rock properties in a glaciated basin.

更新世冰川作用对巴伦支海奥尔加盆地地区石油系统和天然气水合物稳定性的影响
本研究介绍了挪威北部近海西北巴伦支海奥尔加盆地二维数值盆地和石油系统模型的结果,该盆地是一个前沿勘探区,存在大量海底油气渗漏。人们对该地区更新世冰盖推进对岩石性质和地下流体迁移以及海底油气渗流的影响还不甚了解。二维数值模型考虑了冰的反复推进和后退,以及相关的侵蚀和温度效应,并研究了这些参数对流体迁移的影响。模型结果表明,更新世冰川使奥尔加盆地沉积演替的温度降低达 20 °C,例如白垩纪和侏罗纪最上层沉积物的温度降低了 0.5 至 1 千米。温度的降低一般主要与冰川侵蚀的强度有关,本研究根据以往的研究将冰川侵蚀的深度定为 600 米。从奥尔加盆地西南缘石炭纪至三叠纪潜在热源岩排出的碳氢流体通过渗透性载床迁移到海底。然而,在研究区的东北部,流体是沿着断层导管迁移到地表的。在封闭的断层模型方案中,仅有 0.3 百万吨碳氢化合物沿 0.5 公里宽的模型断面迁移;在部分开放断层的第二种方案中,约有 2,200 万吨碳氢化合物在更新世期间流失到地表,约占研究区潜在热源岩产生的碳氢化合物总量的 11%。由于冰川期气温显著下降,以及中生代至新生代地层受到冰川期的强烈侵蚀,奥尔加盆地微生物产生甲烷的潜力在更新世和现今都受到了限制。在冰川期,冰盖下的天然气水合物稳定区根据模型可延伸至 900 米深处(纯甲烷成分),以及 1100 米深处(可能来自热源的混合气体成分,即 90% 甲烷、7% 丙烷和 3% 乙烷)。根据建模,具有这种混合成分的天然气水合物在过去三次冰川期和现在的奥尔加盆地一直保持稳定。这些建模结果有助于深入了解控制奥尔加盆地地区碳氢化合物流体迁移和地表泄漏的关键因素,以及冰川作用对冰川盆地岩石性质的影响。
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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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