Post Earthquake Aggradation Processes to Hide Surface Ruptures in Thrust Systems: The M8.3, 1934, Bihar‐Nepal Earthquake Ruptures at Charnath Khola (Eastern Nepal)

Rizza, Magali; Bollinger, Laurent; Sapkota, Soma Nath; Tapponnier, Paul; Klinger, Yann; Karakaş, Çağıl; Kali, E.; Etchebes, Marie; Tiwari, Dilli Ram; Siwakoti, I.; Bitri, Adnand; Berc, Séverine Bès de

doi:10.1029/2018jb016376

Cited by 24 publications

(29 citation statements)

References 46 publications

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“…However, the face value of the confidence index percentile ages of unit 1b has been used to represent that the earthquake happened after the lower bound calendar age i.e., 1445 CE. Similar interpretations have widely been used in Himalaya by several researchers 12 , 13 , 27 , 28 . Based on the highest probability distribution of radiocarbon ages of samples combined with additional seismotectonic information discussed later in the discussion, we limit the timing of displacement any time after 1445 CE.…”

Section: Structural and Stratigraphic Relationships In The Trench Expmentioning

confidence: 83%

Establishing primary surface rupture evidence and magnitude of the 1697 CE Sadiya earthquake at the Eastern Himalayan Frontal thrust, India

Pandey

Jayangondaperumal

Hetényi

et al. 2021

Sci Rep

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Historical archives refer to often recurring earthquakes along the Eastern Himalaya for which geological evidence is lacking, raising the question of whether these events ruptured the surface or remained blind, and how do they contribute to the seismic budget of the region, which is home to millions of inhabitants. We report a first mega trench excavation at Himebasti village, Arunachal Pradesh, India, and analyze it with modern geological techniques. The study includes twenty-one radiocarbon dates to limit the timing of displacement after 1445 CE, suggesting that the area was devastated in the 1697 CE event, known as Sadiya Earthquake, with a dip-slip displacement of 15.3 ± 4.6 m. Intensity prediction equations and scaling laws for earthquake rupture size allow us to constraints a magnitude of Mw 7.7–8.1 and a minimum rupture length of ~ 100 km for the 1697 CE earthquake.

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Section: Structural and Stratigraphic Relationships In The Trench Expmentioning

confidence: 83%

Establishing primary surface rupture evidence and magnitude of the 1697 CE Sadiya earthquake at the Eastern Himalayan Frontal thrust, India

Pandey

Jayangondaperumal

Hetényi

et al. 2021

Sci Rep

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“…As for the Himalaya studies, the paleoseismic excavation records are likely to miss the blind fault stands. Such questions assume greater importance in the context of the 1934 Bihar-Nepal as the debate on whether this has activated a blind thrust or it had indeed ruptured the surface (Wesnousky et al, 2018;Rizza et al, 2019). Another example is the controversy regarding the location of the fault on the northern side of the Shillong Plateau, which has been variously called as the 'Oldham' fault and the 'Brahmaputra' fault -the former is placed on the northern topographic edge of the plateau and the latter along the Brahmaputra River (Fig.…”

Section: Future Directionsmentioning

confidence: 99%

Paleoseismological Studies in India (2016-2020): Status and Prospects

Rajendran¹,

Singh²,

Mukul³

et al. 2020

PINSA

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The last few years have witnessed consistent growth in paleoseismic investigations and active fault research in India. An overview of relevant publications during 2016-2020 indicates that this field is now widely accepted as a tool to characterize the seismic hazard in the country. Such studies initiated in the country in early nineties have gained momentum and widened its scope into a variety of tectonic and morphological settings.While earthquake frequency and fault activations are major objectives of such studies, the Indian researchers are now equally interested in constraining the fault geometry and the nature of near-surface crustal deformation, thereby contributing to earthquake hazard evaluations. This has been driven by an ever-increasing interaction between experts from associated fields like geomorphology, neotectonics, seismology, geodesy, modeling etc. Future challenges would include integrating the paleoseismological observations with the relevant geophysical inputs to develop physical models of the earthquake cycles, ultimately leading to an inventory of the active faults. Although there are gaps and disagreements on how things operated at different spatial and temporal scales, there have been broad agreements in general. The future should focus on evolving new strategies and methodologies to integrate different datasets in a coherent manner to yield practically relevant results and models that can explain data from various spatial and temporal scales.

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“…Indeed, moderate to large in magnitude ( M > 6) earthquakes rupture faults extending for >15 km in length, but such large faults are rarely well‐exposed along their whole length at the surface due to weathering and vegetation or Quaternary cover. Major mature faults typically record a long, polyphase deformation history, which might obliterate the incipient stages of nucleation and growth (e.g., Rizza et al., 2019 ). Thus, the field geologists' challenge in studying ancient, crustal‐scale seismogenic fault systems is to find large areas which meet the following criteria: excellent preservation over kilometer‐scale exposures of the spatial arrangement of structures (e.g., joints, dykes, and faults) related to multiple deformation stages; faults exhumed from depths (i.e., 5–15 km depending on tectonic regime, rock composition, temperature gradient, etc.…”

Section: Introductionmentioning

confidence: 99%

“…Indeed, moderate to large in magnitude (M > 6) earthquakes rupture faults extending for >15 km in length, but such large faults are rarely well-exposed along their whole length at the surface due to weathering and vegetation or Quaternary cover. Major mature faults typically record a long, polyphase deformation history, which might obliterate the incipient stages of nucleation and growth (e.g., Rizza et al, 2019). Thus, the field geologists' challenge in studying ancient, crustal-scale seismogenic fault systems is to find large areas which meet the following criteria:…”

mentioning

confidence: 99%

Structural Evolution of a Crustal‐Scale Seismogenic Fault in a Magmatic Arc: The Bolfin Fault Zone (Atacama Fault System)

et al. 2021

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How major crustal‐scale seismogenic faults nucleate and evolve in crystalline basements represents a long‐standing, but poorly understood, issue in structural geology and fault mechanics. Here, we address the spatio‐temporal evolution of the Bolfin Fault Zone (BFZ), a >40‐km‐long exhumed seismogenic splay fault of the 1000‐km‐long strike‐slip Atacama Fault System. The BFZ has a sinuous fault trace across the Mesozoic magmatic arc of the Coastal Cordillera (Northern Chile) and formed during the oblique subduction of the Aluk plate beneath the South American plate. Seismic faulting occurred at 5–7 km depth and ≤ 300°C in a fluid‐rich environment as recorded by extensive propylitic alteration and epidote‐chlorite veining. Ancient (125–118 Ma) seismicity is attested by the widespread occurrence of pseudotachylytes. Field geologic surveys indicate nucleation of the BFZ on precursory geometrical anisotropies represented by magmatic foliation of plutons (northern and central segments) and andesitic dyke swarms (southern segment) within the heterogeneous crystalline basement. Seismic faulting exploited the segments of precursory anisotropies that were optimal to favorably oriented with respect to the long‐term far‐stress field associated with the oblique ancient subduction. The large‐scale sinuous geometry of the BFZ resulted from the hard linkage of these anisotropy‐pinned segments during fault growth.

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Post Earthquake Aggradation Processes to Hide Surface Ruptures in Thrust Systems: The M8.3, 1934, Bihar‐Nepal Earthquake Ruptures at Charnath Khola (Eastern Nepal)

Cited by 24 publications

References 46 publications

Establishing primary surface rupture evidence and magnitude of the 1697 CE Sadiya earthquake at the Eastern Himalayan Frontal thrust, India

Establishing primary surface rupture evidence and magnitude of the 1697 CE Sadiya earthquake at the Eastern Himalayan Frontal thrust, India

Paleoseismological Studies in India (2016-2020): Status and Prospects

Structural Evolution of a Crustal‐Scale Seismogenic Fault in a Magmatic Arc: The Bolfin Fault Zone (Atacama Fault System)

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