氦 - 与其他储层气体的关系以及对勘探的一些影响:新墨西哥州实例

Ronald F. Broadhead
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引用次数: 0

摘要

氦(He)是宇宙中含量仅次于氢的元素,但在地球上却相对稀少。氦有两种稳定同位素,即 3He 和 4He。4He 是地壳气体中的主要同位素,是铀和钍的放射性衰变产物,主要存在于花岗岩基底岩石中。3He 是主要的原始同位素,主要来源于地幔。3He 也可能是由 6Li(锂)的放射性衰变形成的,可能存在于蒸发环境中沉积的箭状沉积物中。虽然 He 存在于大多数天然气体中,但其浓度几乎总是极低,低于 0.1%。浓度超过 1%的情况则很少见。极少数小型储层中的气体 He 含量超过 7%。构成含氦天然气主要成分的其他气体是氮(N2)、二氧化碳(CO2)和甲烷(CH4)。氦气浓度最高的地方主要是氮气,但历史上大多数氦气都是作为碳氢化合物气体的副产品产生的。碳氢化合物产生于石油源岩。它们在储层中的存在取决于盆地中是否存在成熟的源岩,以及源岩和储层之间的迁移路径。美国西南部的大量二氧化碳积聚是由于上升的第三纪岩浆脱气以及随后气体迁移到地壳储层所致。N2 似乎主要来源于地幔的脱气,但也可能是在某些地层中通过角砾岩的热成熟或红床序列中粘土或有机化合物的成岩蚀变形成的。储层气体中是否存在经济浓度的 He,不仅取决于花岗岩基底岩石产生的 4He 是否充足,还取决于 N2、CO2 和 CH4 的容纳通量。这些气体的来源、生成地点以及生成、迁移和置换速度各不相同。来自基底的 4He 和 N2 在漫长的地质年代中以缓慢的速度进入储层,而碳氢化合物和 CO2 则在更短的时间内进入储层并稀释 4He 和 N2。地层衍生气体的特征可能是不同的 N2:He 比率,这可能表明某些地区地壳内的 He 产生率更高。20 世纪 90 年代末和 21 世纪初在 Chupadera Mesa 进行的 He 勘探钻井在下二叠统地层中发现了富含 He 的气体。同位素分析表明,Chupadera Mesa 93% 的 He 来自地壳岩石中的放射性衰变,7% 来自地幔或二叠纪蒸发页岩。不同地层中二氧化碳浓度的明显差异表明,一些地层是岩浆衍生二氧化碳的载床,而富含 N2 和贫 CO2 气体的地层则与二氧化碳源隔绝。
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Helium - Relationships to other reservoir gases and some implications for exploration: The New Mexico Example
Helium (He) is the second most abundant element in the universe after hydrogen but is relatively rare on earth. He occurs as two stable isotopes, 3He and 4He. 4He is the dominant isotope in crustal gases and is a radiogenic decay product of uranium and thorium mainly in granitic basement rocks. 3He is dominantly primordial and primarily originates from the earth’s mantle. 3He may also be formed by radiogenic decay of 6Li (Lithium) which may be found in argillaceous sediments deposited in evaporitic settings. Although He occurs in most natural gases, it almost always occurs in extremely low, subeconomic concentrations, less than 0.1%. It is rare in concentrations more than 1%. A very few small reservoirs have gases with more than 7% He. Other gases that constitute the dominant components of helium-bearing natural gases are nitrogen (N2), carbon dioxide (CO2), and methane (CH4). The highest He concentrations occur where the dominant gas is N2 but most He has historically been produced as a byproduct of gases that are hydrocarbons. Hydrocarbons are generated from petroleum source rocks. Their presence in a reservoir is dependent upon the presence of a mature source rock in the basin and a migration path between the source rock and the reservoir. Large accumulations of CO2 in the southwestern U.S. resulted from the degassing of rising Tertiary magmas and subsequent migration of the gases into crustal reservoirs. N2 appears to originate mostly from degassing of the mantle but may also be formed in some strata by the thermal maturation of kerogens or by diagenetic alteration of clays or organic compounds in red bed sequences. The presence of economic concentrations of He in reservoir gases is dependent not only on an adequate source of 4He generated from granitic basement rocks but also on accommodating flux rates of N2, CO2, and CH4. These gases differ in their origins, places of generation and rates of generation, migration and emplacement. While basement-derived 4He and N2 enter reservoirs at slow rates over long periods of geologic time, hydrocarbons and CO2 enter the reservoir over much shorter time periods and dilute the 4He and N2. Basement-derived gases may be characterized by differing N2:He ratios which may indicate greater rates of He production within the crust in some areas. Exploratory drilling for He on Chupadera Mesa in the late 1990’s and early 2000’s encountered He-rich gases in Lower Permian strata. Isotopic analyses suggest that 93% of Chupadera Mesa He originated from radiogenic decay in crustal rocks while 7% is derived from the mantle or with a possible contribution by evaporitic Permian shales. Marked differences in the CO2 concentrations in different strata indicate that some strata acted as carrier beds for magmatically-derived CO2 while strata with N2-rich and CO2-poor gases were isolated from CO2 sources.
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