深层油气循环

V. Kutcherov, K. Ivanov, E. Mukhina, A. Serovaiskii
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引用次数: 2

摘要

研究课题。对极端热压条件下复杂烃类系统的转化进行了实验模拟。所得结果与乌拉尔、堪察加等地区的地质观测结果进行了比较。材料和方法。研究材料为与天然气凝析油组成相似的模式烃体系,由饱和烃和富含57Fe的多种含铁矿物混合组成。使用了两种类型的高压设备:金刚石砧细胞和环形高压室。实验在压力高达8.8 GPa,温度范围593-1600 k下进行。根据所获得的结果,淹没在俯冲板中的碳氢化合物系统可以在50 km深的深度下保持稳定性。在进一步浸没后,烃类流体与周围的含铁矿物接触时,形成铁氢化物和铁碳化物。当铁碳化物在软流层的热压条件下与水反应时,形成水-烃流体。未受蛇纹岩化作用影响的超镁铁质岩石中橄榄石中发现甲烷,乌拉尔古俯冲带挤压出的蛇绿岩异体和超镁铁质岩石中存在多环芳烃和重饱和烃等地质观测结果与实验数据吻合较好。所获得的实验结果和提出的地质观测结果使提出深部油气旋回的概念成为可能。浸没在俯冲板中的烃系与含铁矿物接触后,形成铁氢化物和铁碳化物。由对流气流携带到软流圈中的铁碳化物可以与某些矿物羟基中的氢或软流圈中的水发生反应,形成水-烃流体。地幔流体可以沿着深断层进入地壳,在任何岩性、成因和年龄的岩石中形成多层石油和天然气矿床。除了来自俯冲板块的碳化铁外,软流圈还含有其他碳供体。这些供体可以作为深层碳氢化合物的来源,也参与深层碳氢化合物循环,作为水-烃流体总向上流动的额外补给。所描述的深部油气循环似乎是更普遍的深部碳循环的一部分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Hydrocarbon Cycle
Research subject. Experimental modelling of the transformation of complex hydrocarbon systems under extreme thermobaric conditions was carried out. The results obtained were compared with geological observations in the Urals, Kamchatka and other regions.Material and methods. The materials for the research were a model hydrocarbon system similar in composition to natural gas condensate and a system consisting of a mixture of saturated hydrocarbons and various iron-containing minerals enriched in 57Fe. Two types of high-pressure equipment were used: a diamond anvils cell and a Toroid-type high-pressure chamber. The experiments were carried out at pressures up to 8.8 GPa in the temperature range 593–1600 K.Results. According to the obtained results, hydrocarbon systems submerged in a subduction slab can maintain their stability down to a depth of 50 km. Upon further immersion, during contact of the hydrocarbon fluid with the surrounding iron-bearing minerals, iron hydrides and carbides are formed. When iron carbides react with water under the thermobaric conditions of the asthenosphere, a water-hydrocarbon fluid is formed. Geological observations, such as methane finds in olivines from ultramafic rocks unaffected by serpentinization, the presence of polycyclic aromatic and heavy saturated hydrocarbons in ophiolite allochthons and ultramafic rocks squeezed out from the paleo-subduction zone of the Urals, are in good agreement with the experimental data.Conclusion. The obtained experimental results and presented geological observations made it possible to propose a concept of deep hydrocarbon cycle. Upon the contact of hydrocarbon systems immersed in a subduction slab with iron-bearing minerals, iron hydrides and carbides are formed. Iron carbides carried in the asthenosphere by convective flows can react with hydrogen contained in the hydroxyl group of some minerals or with water present in the asthenosphere and form a water-hydrocarbon fluid. The mantle fluid can migrate along deep faults into the Earth’s crust and form multilayer oil and gas deposits in rocks of any lithological composition, genesis and age. In addition to iron carbide coming from the subduction slab, the asthenosphere contains other carbon donors. These donors can serve as a source of deep hydrocarbons, also participating in the deep hydrocarbon cycle, being an additional recharge of the total upward flow of a water-hydrocarbon fluid. The described deep hydrocarbon cycle appears to be part of a more general deep carbon cycle.
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