Multiple segmentation and seismogenic evolution of the 6th February 2023 (Mw 7.8 and 7.7) consecutive earthquake ruptures and aftershock deformation in the Maras triple junction region of SE-Anatolia, Turkey

IF 2.4 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Physics of the Earth and Planetary Interiors Pub Date : 2023-10-21 DOI:10.1016/j.pepi.2023.107114
Mustafa Toker , Evrim Yavuz , Murat Utkucu , Fatih Uzunca
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Abstract

On 6th February 2023 (UTC), two consecutive and catastrophic earthquakes with moment magnitudes (Mw) 7.8 and 7.7 struck the Maras Triple Junction (MTJ) region in SE Anatolia along with dozens of aftershocks, causing numerous casualties and significant building damage, and generating the most complex and longest surface ruptures ever observed in Turkey. The main driving mechanisms of this complex double event are still unresolved and remain controversial, even though they are likely linked with conventional fault activations, recurrence intervals and seismic gaps. Here, the aim was to gain insight into the source regimes and rupture processes of both events and their relationship with resolved fault focal solutions for the observed aftershocks, and to present an interpretation that accounts for the most puzzling aspects of the fault rupture models. In line with this, the co-seismic slip distributions of these two events were examined by joint analyses of centroid moment tensor (CMT) and finite-fault source inversions using regional and teleseismic broadband observations. Inversion results indicate that both earthquakes were left-lateral strike-slip events, and the main ruptures extended mainly from close to NNE to SSW and E to W, with maximum slips of ∼6.5–10 m, mostly confined to a shallow depth range of ≤ ∼10–15 km and extending to the surface, indicating bilateral source processes with an average rupture velocity of ∼3.5–5.5 km/s. The estimated total seismic moment range was 4.94–8.22 × 1020 N m, associated with ∼352–152 km long (along strike) and ∼ 25 km wide (along dip) fault planes at focal depth of ∼10 km. Regional CMT results indicate nearly pure normal-slip and left-lateral normal oblique-slip focal mechanisms and shallow centroid depths (≤ ∼15 km) for the early aftershock distribution that are obviously complementary with the co-seismic bilateral rupture propagations. This result highlights that double pull-apart branching of focal mechanisms for aftershock occurrence implies interacting fault ruptures embedded in the MTJ area, where two sub−/supershear-rupturing faults meet, thus explaining multiple segmentation and seismogenic evolutions of two interrelated mainshocks, i.e. “triple junction earthquakes”. The results reveal that the MTJ tends to migrate to the SSW and likely drives the SSW-stepping of the left-lateral strike-slip shear (∼136 km). This accounts for the peak slips, long co-seismic fault ruptures and the associated faulting styles. Hence, the co-seismic faulting apparently distributed across the MTJ may reflect triple junction migration, and thus large extension at the core of the Anatolian-Arabian plates, leading to very high seismic hazard in similar junction regions of the country.

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2023年2月6日(Mw 7.8和7.7)土耳其东-安纳托利亚Maras三联结地区连续地震破裂和余震变形的多次分割和发震演化
2023年2月6日(UTC),安纳托利亚东南部的马拉斯三重交界处(Maras Triple Junction, MTJ)地区连续发生了两场矩震级(Mw) 7.8和7.7的灾难性地震,并伴有数十次余震,造成大量人员伤亡和严重的建筑物损坏,并产生了土耳其有史以来观测到的最复杂和最长的地表破裂。这一复杂双重事件的主要驱动机制仍未得到解决,尽管它们可能与常规断层活化、复发间隔和地震间隙有关,但仍存在争议。在这里,目的是深入了解这两个事件的震源机制和破裂过程,以及它们与观测到的余震的已解决的断层震源解的关系,并提出一种解释,解释断层破裂模型中最令人困惑的方面。在此基础上,利用区域和远震宽带观测,利用质心矩张量(CMT)和有限断层源反演联合分析了这两个事件的同震滑动分布。反演结果表明,两次地震均为左侧走滑事件,主破裂主要从近NNE向SSW和E向W扩展,最大滑移为~ 6.5 ~ 10 m,主要局限于≤~ 10 ~ 15 km的浅层深度范围,并向地表延伸,表明双侧震源过程,平均破裂速度为~ 3.5 ~ 5.5 km/s。估计总地震矩范围为4.94-8.22 × 1020 N m,在震源深度约10 km处,断层长约352-152 km(沿走向),断层宽约25 km(沿倾角)。区域CMT结果表明,早期余震分布接近纯正滑和左侧正斜滑震源机制,质心深度较浅(≤~ 15 km),与同震双侧破裂传播明显互补。这一结果表明,余震发生的震源机制的双拉分分支意味着嵌入在MTJ地区的相互作用断层破裂,两个亚/超剪切破裂断层在那里相遇,从而解释了两个相互关联的主震的多次分割和孕震演化,即“三接合地震”。结果表明,MTJ倾向于向西南偏西方向迁移,并可能驱动左侧走滑剪切的SSW步进(~ 136 km)。这解释了峰滑、长同震断层破裂和相关的断裂样式。因此,明显分布在MTJ上的同震断裂可能反映了三重接合的迁移,从而在安纳托利亚-阿拉伯板块的核心处进行了大规模的伸展,导致该国类似接合区域的地震危险性很高。
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来源期刊
Physics of the Earth and Planetary Interiors
Physics of the Earth and Planetary Interiors 地学天文-地球化学与地球物理
CiteScore
5.00
自引率
4.30%
发文量
78
审稿时长
18.5 weeks
期刊介绍: Launched in 1968 to fill the need for an international journal in the field of planetary physics, geodesy and geophysics, Physics of the Earth and Planetary Interiors has now grown to become important reading matter for all geophysicists. It is the only journal to be entirely devoted to the physical and chemical processes of planetary interiors. Original research papers, review articles, short communications and book reviews are all published on a regular basis; and from time to time special issues of the journal are devoted to the publication of the proceedings of symposia and congresses which the editors feel will be of particular interest to the reader.
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