The 3D Crustal Structure in the Epicentral Region of the 1980, Mw 6.9, Southern Apennines Earthquake (Southern Italy): New Constraints From the Integration of Seismic Exploration Data, Deep Wells, and Local Earthquake Tomography

IF 3.3 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Tectonics Pub Date : 2024-05-11 DOI:10.1029/2023tc008056

F. Feriozzi, L. Improta, F. E. Maesano, P. De Gori, R. Basili

{"title":"The 3D Crustal Structure in the Epicentral Region of the 1980, Mw 6.9, Southern Apennines Earthquake (Southern Italy): New Constraints From the Integration of Seismic Exploration Data, Deep Wells, and Local Earthquake Tomography","authors":"F. Feriozzi, L. Improta, F. E. Maesano, P. De Gori, R. Basili","doi":"10.1029/2023tc008056","DOIUrl":null,"url":null,"abstract":"We present the first 3D crustal model of the epicentral region of the 1980, Mw 6.9, normal-faulting Irpinia earthquake (southern Italy) determined by jointly interpreting the CROP-04 deep seismic profile, a grid of commercial seismic lines, deep exploration wells, and a high-resolution Local Earthquake Tomography. Despite numerous seismotectonic surveys and source studies of the background seismicity recorded by dense networks, a complete 3D geological model of the mid-upper crust was still lacking in the region. The architecture of the Neogene fold-and-thrust belt is also debated, with competing thin- and thick-skinned tectonic interpretations. We use the 3D geological model derived from subsurface exploration data to interpret the upper crustal tomographic velocities in terms of rock physical properties, while Vp and Vp/Vs anomalies provide inferences on the deep structural setting down to 12 km depth. We find that a thick-skinned deformation style allows explaining the geometry of Pliocene fold-and-thrust systems deforming the Apulian carbonates but also deeper Permo-Triassic metasediments and the Paleozoic crystalline femic basement. Inherited compressional structures and lithological heterogeneities control background seismicity occurring at two crustal levels. Fluid-driven shallow seismicity (<4–6 km) concentrates in a high-Vp/Vs wedge of fractured, brine-saturated Mesozoic stiff rocks delimited by the 1980 earthquake faults. Deep seismicity (9–14 km) clusters instead within the low-Vp/Vs crystalline basement underneath the Apulian carbonate ramp-anticlines. Commercial seismic data allow us to identify the Irpinia Fault, the main fault ruptured by the 1980 earthquake, reinforcing its previous interpretations as an immature structure with subtle geological and geophysical evidence.","PeriodicalId":22351,"journal":{"name":"Tectonics","volume":"130 1","pages":""},"PeriodicalIF":3.3000,"publicationDate":"2024-05-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Tectonics","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1029/2023tc008056","RegionNum":1,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"GEOCHEMISTRY & GEOPHYSICS","Score":null,"Total":0}

引用次数: 0

Abstract

We present the first 3D crustal model of the epicentral region of the 1980, M_w 6.9, normal-faulting Irpinia earthquake (southern Italy) determined by jointly interpreting the CROP-04 deep seismic profile, a grid of commercial seismic lines, deep exploration wells, and a high-resolution Local Earthquake Tomography. Despite numerous seismotectonic surveys and source studies of the background seismicity recorded by dense networks, a complete 3D geological model of the mid-upper crust was still lacking in the region. The architecture of the Neogene fold-and-thrust belt is also debated, with competing thin- and thick-skinned tectonic interpretations. We use the 3D geological model derived from subsurface exploration data to interpret the upper crustal tomographic velocities in terms of rock physical properties, while V_p and V_p/V_s anomalies provide inferences on the deep structural setting down to 12 km depth. We find that a thick-skinned deformation style allows explaining the geometry of Pliocene fold-and-thrust systems deforming the Apulian carbonates but also deeper Permo-Triassic metasediments and the Paleozoic crystalline femic basement. Inherited compressional structures and lithological heterogeneities control background seismicity occurring at two crustal levels. Fluid-driven shallow seismicity (<4–6 km) concentrates in a high-V_p/V_s wedge of fractured, brine-saturated Mesozoic stiff rocks delimited by the 1980 earthquake faults. Deep seismicity (9–14 km) clusters instead within the low-V_p/V_s crystalline basement underneath the Apulian carbonate ramp-anticlines. Commercial seismic data allow us to identify the Irpinia Fault, the main fault ruptured by the 1980 earthquake, reinforcing its previous interpretations as an immature structure with subtle geological and geophysical evidence.

查看原文本刊更多论文

1980 年意大利南部亚平宁半岛 6.9 级地震震中地区的三维地壳结构：综合地震勘探数据、深井和当地地震层析成像得出的新约束条件

我们介绍了 1980 年 Mw 6.9 正断层伊尔皮尼亚地震（意大利南部）震中地区的首个三维地壳模型，该模型是通过联合解释 CROP-04 深层地震剖面、商业地震测线网格、深层勘探井和高分辨率局部地震层析图确定的。尽管进行了大量地震构造调查，并对密集网络记录的背景地震进行了震源研究，但该地区仍缺乏完整的中上地壳三维地质模型。新近纪褶皱推覆带的构造也存在争议，薄壳构造和厚壳构造的解释相互竞争。我们利用从地下勘探数据中得出的三维地质模型，从岩石物理性质的角度解释了上地壳层析成像速度，而 Vp 和 Vp/Vs 异常则推断了深度达 12 千米的深部构造环境。我们发现，厚皮变形方式不仅可以解释上新世褶皱-推力系统对阿普利亚碳酸盐岩的几何变形，还可以解释更深层的二叠三叠统元古代和古生代晶质母岩基底的变形。继承的压缩结构和岩性异质性控制着两个地壳层面的背景地震。流体驱动的浅层地震（4-6 千米）集中在以 1980 年地震断层为界的中生代坚硬岩石断裂、盐水饱和的高 Vp/Vs 楔形地带。深层地震（9-14 千米）则集中在阿普利亚碳酸盐岩斜坡-anticlines 下的低 Vp/Vs 结晶基底中。通过商业地震数据，我们确定了 1980 年地震中断裂的主要断层--伊尔皮尼亚断层，并通过微妙的地质和地球物理证据加强了之前对其作为未成熟结构的解释。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Tectonics 地学-地球化学与地球物理

CiteScore

7.70

自引率

9.50%

发文量

151

审稿时长

3 months

期刊介绍： Tectonics (TECT) presents original scientific contributions that describe and explain the evolution, structure, and deformation of Earth¹s lithosphere. Contributions are welcome from any relevant area of research, including field, laboratory, petrological, geochemical, geochronological, geophysical, remote-sensing, and modeling studies. Multidisciplinary studies are particularly encouraged. Tectonics welcomes studies across the range of geologic time.