利用近海电磁数据确定新西兰南部 Hikurangi 边缘的孔隙结构和天然气水合物分布特征。

IF 2.8 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Geophysical Journal International Pub Date : 2023-06-19 eCollection Date: 2023-09-01 DOI:10.1093/gji/ggad243
Christine Chesley, Samer Naif, Kerry Key
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引用次数: 0

摘要

增生棱柱的动力学和沿俯冲界面发生的过程部分受前弧楔和由俯冲板块输送到该系统的沉积物的孔隙度和流体超压的控制。位于新西兰北岛近海的 Hikurangi 边缘是研究进入的板块沉积物的固结状态、增生楔中的脱水和流体流动与沿板块界面观测到的大地耦合和大推移滑动行为之间相互作用的一个特别相关的区域。在其较短的地理范围内,边缘具有影响俯冲过程和南北过渡的多种特性。其最南端的特征是锋面增生、厚沉积物俯冲、无海底粗糙度、强地震间耦合和深层缓慢滑动事件。在此,我们利用沿 Hikurangi 边缘南部剖面采集的海底磁测(MT)和可控源电磁(CSEM)数据,对前弧和来弧板块的电阻率进行成像。浅前弧的电阻异常可能表明存在天然气水合物,我们将更深的前弧电阻与同位地震反射数据中的推力断层联系起来。由于 MT 和 CSEM 数据对海底沉积物和大洋地壳孔隙空间中的流体相非常敏感,我们将电阻率转换为孔隙度,以表示流体沿剖面的分布情况。我们的研究表明,由电阻率数据预测的孔隙率可以很好地与指数沉积压实模型拟合。通过从孔隙度模型中去除这种压实趋势,我们能够评估孔隙度的二阶横向变化,这种方法可应用于其他沉积盆地的电磁数据集。利用这种孔隙度异常模型,我们可以研究进入的板块和增生楔沉积物的固结状态。在接近海沟的沉积物中观察到的孔隙度下降表明,在锋面推力向海 25 公里处正在形成一个原推力区。我们的数据还表明,增生楔深部的沉积物固结程度略低,这可能表明深楔的排水不完全和流体超压升高。
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Characterizing the porosity structure and gas hydrate distribution at the southern Hikurangi Margin, New Zealand from offshore electromagnetic data.

The dynamics of accretionary prisms and the processes that take place along subduction interfaces are controlled, in part, by the porosity and fluid overpressure of both the forearc wedge and the sediments transported to the system by the subducting plate. The Hikurangi Margin, located offshore the North Island of New Zealand, is a particularly relevant area to investigate the interplay between the consolidation state of incoming plate sediments, dewatering and fluid flow in the accretionary wedge and observed geodetic coupling and megathrust slip behaviour along the plate interface. In its short geographic extent, the margin hosts a diversity of properties that impact subduction processes and that transition from north to south. Its southernmost limit is characterized by frontal accretion, thick sediment subduction, the absence of seafloor roughness, strong interseismic coupling and deep slow slip events. Here we use seafloor magnetotelluric (MT) and controlled-source electromagnetic (CSEM) data collected along a profile through the southern Hikurangi Margin to image the electrical resistivity of the forearc and incoming plate. Resistive anomalies in the shallow forearc likely indicate the presence of gas hydrates, and we relate deeper forerarc resistors to thrust faulting imaged in colocated seismic reflection data. Because MT and CSEM data are highly sensitive to fluid phases in the pore spaces of seafloor sediments and oceanic crust, we convert resistivity to porosity to obtain a representation of fluid distribution along the profile. We show that porosity predicted by the resistivity data can be well fit by an exponential sediment compaction model. By removing this compaction trend from the porosity model, we are able to evaluate the second-order, lateral changes in porosity, an approach that can be applied to EM data sets from other sedimentary basins. Using this porosity anomaly model, we examine the consolidation state of the incoming plate and accretionary wedge sediments. A decrease in porosity observed in the sediments approaching the trench suggests that a protothrust zone is developing ∼25 km seaward of the frontal thrust. Our data also imply that sediments deeper in the accretionary wedge are slightly underconsolidated, which may indicate incomplete drainage and elevated fluid overpressures of the deep wedge.

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来源期刊
Geophysical Journal International
Geophysical Journal International 地学-地球化学与地球物理
CiteScore
5.40
自引率
10.70%
发文量
436
审稿时长
3.3 months
期刊介绍: Geophysical Journal International publishes top quality research papers, express letters, invited review papers and book reviews on all aspects of theoretical, computational, applied and observational geophysics.
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