流体饱和度和粘度对贝里亚砂岩地震频散特性的影响

GEOPHYSICS Pub Date : 2024-05-24 DOI:10.1190/geo2023-0350.1
Qianqian Wei, De-hua Han, Hui Li, Jianhua Wang, Yang Wang, Jianjun Chen
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引用次数: 0

摘要

尽管有更多来自水饱和砂岩的地震频率实验室数据,但对高粘度流体饱和的岩石样本,尤其是部分饱和的岩石样本的测量仍然很少见。为了量化流体粘度和饱和度对地震频散和衰减特性的影响,我们在不同流体粘度(如水、甘油)的部分饱和砂岩中进行了两次地震频率(2-400 Hz)强迫振荡对比测量。结果表明,流体粘度和饱和度都会对测量频率的频散和衰减特性产生重大影响。在甘油和水饱和度相对较低的情况下(∼6% - 8%),都能观察到显著的频散和衰减,但其幅度和特征频率各不相同。具体来说,在饱和度为 94% 的水饱和岩石中,最大延伸衰减(∼0.024)出现在大约 200 Hz,而在饱和度为 92% 的甘油饱和岩石中,最大延伸衰减出现在大约 30 Hz,峰值为 0.032。根据理论模型分析,我们认为介观流体流动可能是部分水或甘油饱和情况下观测到的衰减的主要机制,而微观(喷射)流动机制可能在完全饱和情况下占主导地位。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effects of fluid saturation and viscosity on seismic dispersion characteristics in Berea sandstone
Despite additional availability of laboratory data from water-saturated sandstone at seismic frequencies, measurements of rock samples saturated with high viscous fluids, particularly at partial saturation, are still rare. To quantify the effects of fluid viscosity and saturation levels on seismic dispersion and attenuation characteristics, we conducted two comparative forced-oscillation measurements in partially saturated sandstone with varying fluid viscosity (e.g., water, glycerin) at seismic frequencies (2-400 Hz). The results demonstrate that both fluid viscosity and saturation levels substantially influence the dispersion and attenuation characteristics at the measured frequencies. Significant dispersion and attenuation are observed in the presence of a relatively small amount of gas (∼6% - 8%) for both glycerin and water saturation cases but vary in their magnitudes and characteristic frequencies. Specifically, the maximum extensional attenuation (∼0.024) occurs at approximately 200 Hz for water-saturated rock at 94% saturation, while at around 30 Hz with a peak of 0.032 for glycerin-saturated rock at 92% saturation. Based on theoretical modeling analysis, we suggest that mesoscopic fluid flow might be a dominant mechanism accounting for the observed attenuation in partial water or glycerin saturation, while the microscopic (squirt) flow mechanism possibly dominates the fully saturated cases.
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