New Zealand Fault-Rupture Depth Model v.1.0: A Provisional Estimate of the Maximum Depth of Seismic Rupture on New Zealand’s Active Faults

IF 2.6 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

Bulletin of the Seismological Society of America Pub Date : 2023-10-27 DOI:10.1785/0120230166

Susan Ellis, Stephen Bannister, Russ Van Dissen, Donna Eberhart-Phillips, Carolyn Boulton, Martin Reyners, Rob Funnell, Nick Mortimer, Phaedra Upton, Chris Rollins, Hannu Seebeck

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引用次数: 5

Abstract

ABSTRACT We summarize estimates of the maximum rupture depth on New Zealand’s active faults (“New Zealand Fault-Rupture Depth Model v.1.0”), as used in the New Zealand Community Fault Model v1.0 and as a constraint for the latest revision of the New Zealand National Seismic Hazard Model (NZ NSHM 2022). Rupture depth estimates are based on a combination of two separate model approaches (using different methods and datasets). The first approach uses regional seismicity distribution from a relocated earthquake catalog to calculate the 90% seismicity cutoff depth (D90), representing the seismogenic depth limit. This is multiplied by an overshoot factor representing the dynamic propagation of rupture into the conditional stability zone, and accounting for the difference between regional seismicity depths and the frictional properties of a mature fault zone to arrive at a seismic estimate of the maximum rupture depth. The second approach uses surface heat flow and rock type to compute depths that correspond to the thermal limits of frictional instabilities on seismogenic faults. To arrive at a thermally-based maximum rupture depth, these thermal limits are also multiplied by an overshoot factor. Both the models have depth cutoffs at the Moho and/or subducting slabs. Results indicate the maximum rupture depths between 8 (Taupō volcanic zone) and >30 km (e.g., southwest North Island), strongly correlated with regional thermal gradients. The depths derived from the two methods show broad agreement for most of the North Island and some differences in the South Island. A combined model using weighting based on relative uncertainties is derived and validated using constraints from hypocenter and slip model depths from recent well-instrumented earthquakes. We discuss modifications to the maximum rupture depths estimated here that were undertaken for application within the NZ NSHM 2022. Our research demonstrates the utility of combining seismicity cutoff and thermal stability estimates to assess the down-dip dimensions of future earthquake ruptures.

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新西兰断层破裂深度模型v.1.0:新西兰活动断层地震破裂最大深度的临时估计

我们总结了新西兰活动断层的最大破裂深度估计(“新西兰断层破裂深度模型v.1.0”)，用于新西兰社区断层模型v1.0，并作为新西兰国家地震危险模型(NZ NSHM 2022)最新修订的约束。破裂深度估计是基于两种独立模型方法的组合(使用不同的方法和数据集)。第一种方法利用重新定位地震目录的区域地震活动性分布来计算90%地震活动性截止深度(D90)，代表发震深度极限。再乘以一个超调系数，表示破裂向条件稳定带的动态传播，并考虑区域地震活动深度与成熟断裂带摩擦特性之间的差异，从而得出最大破裂深度的地震估计。第二种方法利用地表热流和岩石类型来计算与发震断层摩擦不稳定性热极限相对应的深度。为了得到基于热的最大破裂深度，这些热极限还要乘以一个超冲系数。这两种模型都在莫霍和/或俯冲板块处有深度界限。结果表明，最大破裂深度在8 km(陶普火山带)~ 30 km(如北岛西南部)之间，与区域热梯度密切相关。两种方法得到的深度在北岛大部分地区显示出广泛的一致性，而在南岛则有一些差异。基于相对不确定性的加权组合模型得到了推导，并使用了最近地震的震源和滑动模型深度的约束条件进行了验证。我们讨论了在新西兰NSHM 2022中应用的最大破裂深度的修改。我们的研究表明，结合地震活动切断和热稳定性估计来评估未来地震破裂的下倾尺寸的效用。

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来源期刊

Bulletin of the Seismological Society of America 地学-地球化学与地球物理

CiteScore

5.80

自引率

13.30%

发文量

140

审稿时长

3 months

期刊介绍： The Bulletin of the Seismological Society of America, commonly referred to as BSSA, (ISSN 0037-1106) is the premier journal of advanced research in earthquake seismology and related disciplines. It first appeared in 1911 and became a bimonthly in 1963. Each issue is composed of scientific papers on the various aspects of seismology, including investigation of specific earthquakes, theoretical and observational studies of seismic waves, inverse methods for determining the structure of the Earth or the dynamics of the earthquake source, seismometry, earthquake hazard and risk estimation, seismotectonics, and earthquake engineering. Special issues focus on important earthquakes or rapidly changing topics in seismology. BSSA is published by the Seismological Society of America.