Chemical Composition of Gases as a Geochemical Tracer of Natural Gas Migration
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摘要: 本文通过我国不同含油气盆地典型地区岩石酸解气、罐顶气和天然气中化学组分分析,结合天然气的形成和盆地的地质演化,研究了天然气运移时组分的变化。结果表明,天然气通过地层孔隙系统运移时,组分会发生明显分馏,表现在甲烷相对重烃、异构丁烷相对正构丁烷的优先迁移。酸解气、罐顶气和成藏天然气中C1/C2+、iC4/nC4及总烃/非烃等比值,是天然气运移示踪的有效指标。Abstract: The chemical compositions of gases released from sedimentary rocks by acidolysis, canned head-space gases of rocks and commercial natural gases, which were collected from different areas of various oil/gas bearing basins in China, were analyzed. Combined with natural gas generation and geological evolution of Ordos basin, Tarim basin, Ying-Qun basin and Huanghua depression, the chemical composition change resulted from natural gas migration was discussed in this paper. As a result of the obvious fractionation in the chemical composition during gas migration through porous sedimentary rock, the evidence that the molecular of methane will preferentially migrate to heavier gaseous hydrocarbons and normal butane to isobutane was recognized. 1. acidolysis gases released from sendimentary rock The compositional ratios of C1/C2+ and C1/C total of the gases released from sedimentary rocks by acidolysis, which were collected from 3 080~3 560 m section of well Chenchuan-1 in Ordos basin, decrease with increasing of the buried depth (as shown in Fig. 1 ). The organic matter in this section is from condensate to over-mature and three gas producing layers are found in brown sandstone with TOC values less than 0.3%. However, above two ratios resulted from thermal gas generation from organic matter should tend to increase with depth corresponding to its thermal maturation. This suggests that the molecular methane preferentially transfer to heavier gaseous hydrocarbons during gas migration. 2. canned head-space gases The methane concentration and heavier gaseous hydrocarbons concentration of canned head-space gases from reservoir rocks are far greater than those from source rocks (Fig. 2a), which are collected from 3 600~4 438 m section of well Chenchuan-1. And the ratio of C1/(C2+C3) is much bigger in the reservoir rock than source rock and becomes bigger and bigger with the depth (Fig. 2b). C1and C2+ concentration in the source rock of 6th to 10th section of Majiagou Ⅴ group are obviously larger than those of Majiagou Ⅰ group to Ⅳ group and the C1/(C2+C3) ratio becomes bigger with buried depth, indicating that natural gases generated in the 6th to 10th section of Majiagou Ⅴ group is migrated and trapped in the reservoir. 3. commercial natural gases The natural gases with the same origin identified by δ13C1 andδ13C2 values are trapped in different reservoirs, which are distributed in Donghetan reservoir of Tarim basin, Dongfang1-1 and Luodong15-1 reservoirs of Ying-Qun basin and Qikou sag of Huanghua depression. Their chemically compositional change of C1/C 2+, C1/C total and C total gaseous hydrocarbons /C total non-hydrocarbons in the vertical also reveals that the molecular of methane preferentially migrate to heavier gaseous hydrocarbons and hydrocarbons to non-hydrocarbons. As a result of migrational fractionation, the natural gas with much more methane than heavier hydrocarbons is trapped in relatively shallow reservoirs.
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