Forensic Mapping Of Spatial Velocity Heterogeneity In A CO2 Layer At Sleipner Using Time-Lapse 3D Seismic Monitoring

Fifth CO2 Geological Storage Workshop Pub Date : 2018-11-21 DOI:10.3997/2214-4609.201802979

A. Chadwick, G. Williams

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Abstract

The Sleipner injection operation has stored over 17 Mt of CO2. Time-lapse seismic monitoring has provided high resolution images of CO2 plume development, constraining and verifying numerical flow simulations. Seismic velocity is a key diagnostic parameter for CO2 layer properties and we adopt a forensic interpretative approach to determine velocity variation in the topmost layer of the plume. The 2010 seismic dataset enables, for the first time, temporal thicknesses of the layer to be determined, taking into account interference-induced time-shifts. Combining these with CO2 layer thicknesses determined from structural analysis of the topseal topography allows layer velocity to be mapped. A marked spatial variation in velocity is evident across the layer with higher velocities (1630±103 ms-1) in the central part of the layer contrasting with lower values (~1370± 122 ms-1) to the north. Recent published work has identified a north-trending channel in the topmost Utsira sand unit, which greatly improves history-matching of the topmost CO2 layer with numerical flow simulations. This channel correlates almost exactly with the low velocity area mapped from the seismic, the higher velocity area corresponding to less permeable overbank deposits. The seismic therefore provides key corroborative evidence of permeability heterogeneity within the reservoir sand.

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利用时移三维地震监测在Sleipner CO2层进行空间速度非均质法医学制图

Sleipner注入作业已经储存了超过1700万吨的二氧化碳。延时地震监测提供了CO2羽流发展的高分辨率图像，约束和验证了数值流动模拟。地震速度是CO2层性质的关键诊断参数，我们采用法证解释方法来确定羽流最上层的速度变化。2010年的地震数据集首次考虑了干扰引起的时移，从而确定了地层的时间厚度。将这些数据与由上封印地形的结构分析确定的二氧化碳层厚度相结合，就可以绘制出层速。整个层的速度空间变化明显，层中部速度较高(1630±103 ms-1)，而北部速度较低(~1370±122 ms-1)。最近发表的研究发现，在最上层的Utsira砂单元中有一条北向通道，这极大地改善了最上层二氧化碳层与数值流动模拟的历史匹配。该水道与地震测得的低速区几乎完全对应，高速区对应的是渗透性较差的河岸上沉积物。因此，地震为储层砂体渗透率非均质性提供了关键的确证证据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fifth CO2 Geological Storage Workshop

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