Global seismic energy scaling relationships based on the type of faulting

IF 3.2 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Solid Earth Pub Date : 2024-02-12 DOI:10.5194/se-15-229-2024
Quetzalcoatl Rodríguez-Pérez, F. Ramón Zúñiga
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Abstract

Abstract. We derived scaling relationships for different seismic energy metrics for earthquakes around the globe with MW > 6.0 from 1990 to 2022. The seismic energy estimations were derived with two methodologies, the first based on the velocity flux integration and the second based on finite-fault models. In the first case, we analyzed 3331 reported seismic energies derived by integrating far-field waveforms. In the latter methodology, we used the total moment rate functions and the approximation of the overdamped dynamics to quantify seismic energy from 231 finite-fault models (Emrt and EO, EU, respectively). Both methodologies provide compatible energy estimates. The radiated seismic energies estimated from the slip models and integration of velocity records are also compared for different types of focal mechanisms (R, reverse; R-SS, reverse–strike-slip; SS, strike-slip; SS-R, strike-slip–reverse; SS-N, strike-slip–normal; N, normal; and N-SS, normal–strike-slip), and then used to derive converting scaling relations among the different energy types. Additionally, the behavior of radiated seismic energy (ER), energy-to-moment ratio (ER/M0), and apparent stress (τα) for different rupture types at a global scale is examined by considering depth variations in mechanical properties, such as seismic velocities, rock densities, and rigidities. For this purpose, we used a 1-D global velocity model. The ER/M0 ratio is, based on statistical t tests, largest for strike-slip earthquakes, followed by normal-faulting events, with the lowest values for reverse earthquakes for hypocentral depths < 90 km. Not enough data are available for statistical tests at deeper intervals except for the 90 to 120 km range, where we can satisfactorily conclude that ER/M0 for R-SS and SS-R types is larger than for N-type faulting, which also conforms to the previous assumption. In agreement with previous studies, our results exhibit a robust variation in τα with the focal mechanism. Regarding the behavior of τα with depth, our results agree with the existence of a bimodal distribution with two depth intervals where the apparent stress is maximum for normal-faulting earthquakes. At depths in the range of 180–240 km, τα for reverse earthquakes is higher than for normal-faulting events. We find the trend EU > Emrt > EO for all mechanism types based on statistical t tests. Finite-fault energy estimations also support focal mechanism dependence of apparent stress but only for shallow earthquakes (Z < 30 km). The slip distribution population used was too small to conclude that finite-fault energy estimations support the dependence of average apparent stress on rupture type at different depth intervals.
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基于断层类型的全球地震能量比例关系
摘要我们推导了 1990 年至 2022 年全球发生的 MW > 6.0 地震的不同地震能量指标的比例关系。地震能量估算有两种方法,第一种基于速度通量积分,第二种基于有限断层模型。在第一种方法中,我们分析了 3331 次报告的地震能量,这些地震能量是通过整合远场波形得出的。在后一种方法中,我们使用总力矩率函数和过阻尼动力学近似值来量化来自 231 个有限断层模型(分别为 Emrt 和 EO,EU)的地震能量。这两种方法都提供了兼容的能量估算。通过滑动模型和速度记录积分估算的辐射地震能量还针对不同类型的病灶机制(R,反向;R-SS,反向-打击-滑动;SS,打击-滑动;SS-R,打击-滑动-反向;SS-N,打击-滑动-正常;N,正常;N-SS,正常-打击-滑动)进行了比较,然后用于推导不同能量类型之间的转换比例关系。此外,通过考虑地震速度、岩石密度和刚度等力学特性的深度变化,研究了全球范围内不同断裂类型的辐射地震能量(ER)、能量-时刻比(ER/M0)和表观应力(τα)的行为。为此,我们使用了一维全球速度模型。根据统计 t 检验,ER/M0 比值最大的是走向滑动地震,其次是正断层地震,而根据统计 t 检验,在所有机制类型中,下中心深度 Emrt > EO 的反向地震的ER/M0 比值最小。有限断层能量估算也支持视应力的焦点机制依赖性,但仅适用于浅层地震(Z < 30 km)。由于使用的滑动分布群太小,因此无法得出有限断层能量估计支持不同深度区间的平均视应力与断裂类型有关的结论。
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来源期刊
Solid Earth
Solid Earth GEOCHEMISTRY & GEOPHYSICS-
CiteScore
6.90
自引率
8.80%
发文量
78
审稿时长
4.5 months
期刊介绍: Solid Earth (SE) is a not-for-profit journal that publishes multidisciplinary research on the composition, structure, dynamics of the Earth from the surface to the deep interior at all spatial and temporal scales. The journal invites contributions encompassing observational, experimental, and theoretical investigations in the form of short communications, research articles, method articles, review articles, and discussion and commentaries on all aspects of the solid Earth (for details see manuscript types). Being interdisciplinary in scope, SE covers the following disciplines: geochemistry, mineralogy, petrology, volcanology; geodesy and gravity; geodynamics: numerical and analogue modeling of geoprocesses; geoelectrics and electromagnetics; geomagnetism; geomorphology, morphotectonics, and paleoseismology; rock physics; seismics and seismology; critical zone science (Earth''s permeable near-surface layer); stratigraphy, sedimentology, and palaeontology; rock deformation, structural geology, and tectonics.
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