Seismic inversion for CO2 volume monitoring and comprehensive evaluation of pore fluid properties: a case study

IF 2.8 4区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Environmental Earth Sciences Pub Date : 2025-01-15 DOI:10.1007/s12665-025-12088-5

G. Hema, S. P. Maurya, Ravi Kant, Ajay P. Singh, Nitin Verma, Brijesh Kumar, Raghav Singh, K. H. Singh

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Abstract

A comprehensive evaluation of pore fluid properties, involves detailed analysis of various characteristics and behaviours relevant to its storage and management in subsurface reservoirs. The assessment includes variations in CO₂ density, bulk modulus, temperature, pressure, velocities, and interactions with reservoir fluids and rocks. The seismic response of porous rocks hosting pore fluids is influenced by these physical properties, crucial for understanding CO₂ behaviour in carbon capture and storage (CCS) initiatives. In this study, we first utilize the Batzle–Wang model to predict the behavior of common pore fluids, such as brine and gas, which are key to understanding the seismic response of the reservoir. This initial analysis provides the foundation for the next step: monitoring the behavior of injected CO₂ at the Sleipner field in Norway. To accurately track changes in the subsurface related to CO₂ injection, we employ seismic inversion using the simulated annealing (SA) technique. This global optimization approach offers significant advantages over traditional local optimization methods, yielding more reliable and near-optimal solutions for estimating the changes in acoustic impedance caused by CO₂ saturation. The study examines five sets of time-lapse seismic data from the Sleipner field, from 1994 to 2006. Acoustic impedances are computed for the pre-injection period and post-injection years, revealing a low impedance zone spanning from 2000 to 2500 m/s/g/cc. This inversion result predicts the injected CO₂ volume by calculating the CO₂ area from the uppermost time slice of different years, based on acoustic impedance seismic sections. To address inherent non-uniqueness in time-lapse analysis, the estimated volume is compared with the original production volume. The results indicate that the estimated volume closely resembles the original injected volume for different time-lapse seismic data.

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二氧化碳体积监测和孔隙流体性质综合评价的地震反演：一个案例研究

孔隙流体性质的综合评价包括对其在地下储层中储存和管理的各种特征和行为的详细分析。评估包括CO2密度、体积模量、温度、压力、速度以及与储层流体和岩石的相互作用的变化。承载孔隙流体的多孔岩石的地震响应受到这些物理性质的影响，这对于理解碳捕集与封存（CCS）计划中的二氧化碳行为至关重要。在本研究中，我们首先利用Batzle-Wang模型预测了常见孔隙流体（如盐水和气体）的行为，这是理解储层地震响应的关键。这一初步分析为下一步工作奠定了基础：监测挪威Sleipner油田注入二氧化碳的行为。为了准确跟踪与二氧化碳注入相关的地下变化，我们采用模拟退火（SA）技术进行地震反演。与传统的局部优化方法相比，这种全局优化方法具有显著的优势，可以为估计二氧化碳饱和度引起的声阻抗变化提供更可靠和接近最优的解决方案。该研究检查了Sleipner油田1994年至2006年的五组延时地震数据。计算了注入前和注入后年份的声阻抗，揭示了2000 - 2500 m/s/g/cc的低阻抗区。该反演结果基于声阻抗地震剖面，通过计算不同年份最上层时间片的CO2面积来预测注入CO2体积。为了解决延时分析中固有的非唯一性问题，将估计的产量与原始产量进行了比较。结果表明，对于不同时移地震资料，估算体积与原始注入体积非常接近。

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来源期刊

Environmental Earth Sciences 环境科学-地球科学综合

CiteScore

5.10

自引率

3.60%

发文量

494

审稿时长

8.3 months

期刊介绍： Environmental Earth Sciences is an international multidisciplinary journal concerned with all aspects of interaction between humans, natural resources, ecosystems, special climates or unique geographic zones, and the earth: Water and soil contamination caused by waste management and disposal practices Environmental problems associated with transportation by land, air, or water Geological processes that may impact biosystems or humans Man-made or naturally occurring geological or hydrological hazards Environmental problems associated with the recovery of materials from the earth Environmental problems caused by extraction of minerals, coal, and ores, as well as oil and gas, water and alternative energy sources Environmental impacts of exploration and recultivation – Environmental impacts of hazardous materials Management of environmental data and information in data banks and information systems Dissemination of knowledge on techniques, methods, approaches and experiences to improve and remediate the environment In pursuit of these topics, the geoscientific disciplines are invited to contribute their knowledge and experience. Major disciplines include: hydrogeology, hydrochemistry, geochemistry, geophysics, engineering geology, remediation science, natural resources management, environmental climatology and biota, environmental geography, soil science and geomicrobiology.