Characteristics of the Fault Damage Zone From High-Resolution Seismic Imaging Along the Palos Verdes Fault, California

IF 8.3 Q1 GEOSCIENCES, MULTIDISCIPLINARY
AGU Advances Pub Date : 2024-07-03 DOI:10.1029/2023AV001155
Travis Alongi, Emily E. Brodsky, Jared Kluesner, Daniel Brothers
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Abstract

The distribution and intensity of fault damage zones provides insight into fault activity and its relationship to fluid flow in the crust. Presently, measures of the in-situ distribution of fault damage remain limited and along-strike studies are rare. This study focuses on an offshore section Palos Verdes Fault damage zone that spans 28 km, near Los Angeles, California. To investigate the previously unresolved shallow (∼400 m below the seafloor) fault damage zone we use densely spaced (∼500 m line separation) newly collected sparker multichannel seismic lines and sub-bottom profiles. The combination of high-resolution acquisition methods and specialized seismic processing workflows provide improved imaging of shallow faulting. We apply a multi-trace similarity technique to identify discontinuities in the seismic data that may be attributed to faults and fractures. This fault detection approach reveals diverse fault damage patterns on adjacent seismic profiles. However, a discernible damage zone pattern emerges by stacking multiple damage detection profiles along strike. We find that peak damage identified in this way corresponds to the active main fault strand, confirmed in this study, and thus the technique may be useful for identifying active fault strands elsewhere. Additionally, we observe that the variable width of the damage zone along strike is controlled by fault obliquity. Furthermore, our observations reveal a correlation between fault damage and seafloor fluid seeps visible in the water column, suggesting that damage plays a role in controlling fluid flow around the fault.

Abstract Image

加利福尼亚州帕洛斯维第斯断层沿线高分辨率地震成像显示的断层破坏带特征
断层破碎带的分布和强度有助于深入了解断层活动及其与地壳流体流动的关系。目前,对断层损伤原位分布的测量仍然有限,沿断层的研究也很少见。本研究侧重于加利福尼亚州洛杉矶附近横跨 28 公里的帕洛斯维第斯断层近海断面破坏带。为了研究之前尚未解决的浅层(海底以下 400 米)断层破坏带,我们使用了新采集的密集间隔(线间距 500 米)火花多道地震测线和海底下剖面。高分辨率采集方法与专门的地震处理工作流程相结合,改进了浅层断层的成像。我们采用多道迹相似性技术来识别地震数据中可能归因于断层和裂缝的不连续性。这种断层探测方法可揭示相邻地震剖面上多种多样的断层破坏模式。然而,通过沿走向叠加多个损伤检测剖面,可以发现一个明显的损伤区模式。我们发现,这种方法识别出的破坏峰值与本研究中确认的活跃主断层带相对应,因此该技术可用于识别其他地方的活跃断层带。此外,我们还观察到,破坏带沿走向的宽度变化受断层倾角的控制。此外,我们的观测还揭示了断层损伤与水柱中可见的海底流体渗出之间的相关性,这表明损伤在控制断层周围的流体流动方面发挥了作用。
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CiteScore
2.90
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