New papers on paleoseismology, active tectonics, and archaeoseismology (Aug 2022)

Today we have a number of articles on fault physics and some papers that use novel or unconventional ways to address large earthquakes and their proxies. Enjoy reading!

• Webber, S., Little, T., Boulton, C., Biemiller, J., & Mizera, M. (2022). Regional‐Scale Low‐Angle Normal Fault Friction and Cohesion Constrained From Mohr‐Coulomb Models of Active and Abandoned Range‐Front Faults in Papua New Guinea. Journal of Geophysical Research: Solid Earth, 127(4), e2021JB023553.
• Costa, P. J., Lario, J., & Reicherter, K. (2022). Tsunami Deposits in Atlantic Iberia: A Succinct Review. Historical Earthquakes, Tsunamis and Archaeology in the Iberian Peninsula, 105-126.
• Brandes, C., Polom, U., Winsemann, J., & Sandersen, P. B. (2022). The near-surface structure in the area of the Børglum fault, Sorgenfrei-Tornquist Zone, northern Denmark: Implications for fault kinematics, timing of fault activity and fault control on tunnel valley formation. Quaternary Science Reviews, 289, 107619.
• Marchandon, M., Wright, T. J., & Hollingsworth, J. (2022). Remote Sensing of the Earthquake Deformation Cycle. Surface Displacement Measurement from Remote Sensing Images, 191-246.
• Yang, X., Qiu, Q., Feng, W., Lin, J., Zhang, J., Zhou, Z., & Zhang, F. (2022). Mechanism of the 2017 Mw 6.3 Pasni earthquake and its significance for future major earthquakes in the eastern Makran. Geophysical Journal International.
• Ye, L., Bai, Y., Si, D., Lay, T., Cheung, K. F., & Kanamori, H. (2022). Rupture Model for the 29 July 2021 MW 8.2 Chignik, Alaska Earthquake Constrained by Seismic, Geodetic, and Tsunami Observations. Journal of Geophysical Research: Solid Earth, e2021JB023676.
• Stiros, S. C. (2022). Earthquakes, tsunamis, dried harbours and seismic coastal uplift: evidence from the Eastern Mediterranean. Mediterranean Geoscience Reviews, 1-10.
• Molenaar, A., Van Daele, M., Huang, J. J. S., Strasser, M., De Batist, M., Pino, M., Urrutia, R., & Moernaut, J. (2022). Disentangling Factors Controlling Earthquake-Triggered Soft-Sediment Deformation in Lakes. Sedimentary Geology, 106200.
• Martin, S. S., & Hough, S. E. (2022). The 8 April 1860 Jour de Pâques Earthquake Sequence in Southern Haiti. BSSA.
• Galadini, F., Ceccaroni, E., Dixit Dominus, G., Falcucci, E., Gori, S., Maceroni, D., … & Vassallo, M. (2022). Combining earth sciences with archaeology to investigate natural risks related to the cultural heritage of the Marsica region (central Apennines, Italy). Mediterranean Geoscience Reviews, 1-32.
• Padgett, J. S., Engelhart, S. E., Kelsey, H. M., Witter, R. C., & Cahill, N. (2022). Reproducibility and variability of earthquake subsidence estimates from saltmarshes of a Cascadia estuary. Journal of Quaternary Science.
• Oliveira, C. S. (2022). The main developments of Seismology and Earthquake Engineering since the early 1700s and the new challenges for a sustainable society. Bulletin of Earthquake Engineering, 1-167.
• Yang, H., Sellmann, S., & Quigley, M. (2022). Fluid‐enhanced neotectonic faulting in the cratonic lithosphere of the Nullarbor Plain in south‐central Australia. Geophysical Research Letters, e2022GL099155.
• Pan, J., Li, H., Chevalier, M. L., Tapponnier, P., Bai, M., Li, C., … & Chen, P. (2022). Co-seismic rupture of the 2021, Mw7. 4 Maduo earthquake (northern Tibet): Short-cutting of the Kunlun fault big bend. Earth and Planetary Science Letters, 594, 117703.
• Diercks, M., Grützner, C., Vrabec, M., & Ustaszewski, K. (2022). Addendum to Diercks et al., 2021: A model for the formation of the Pradol (Pradolino) dry valley in W Slovenia and NE Italy. Geologija, /65/(1), 93-99.
• Lu, Y., Pope, E. L., Moernaut, J., Bookman, R., Waldmann, N., Agnon, A., … & Strasser, M. (2022). Stratigraphic record reveals contrasting roles of overflows and underflows over glacial cycles in a hypersaline lake (Dead Sea). Earth and Planetary Science Letters, 594, 117723.
• Combey, A., Audin, L., Gandreau, D., Benavente, C., Rosell, L., & Marconato, L. (2022). Reassessing the seismic hazard in the Cusco area, Peru: New contribution coming from an archaeoseismological survey on Inca remains. Quaternary International.
• Zielke, O., Benedetti, L., Mai, P. M., Fleury, J., Rizza, M., & Viseur, S. (2022). Bedrock fault roughness resolves slip increments of large earthquakes: Case studies from Central Italy. Tectonophysics, 838.
• O’Kane, A., Copley, A., Mitra, S., & Wimpenny, S. (2022). The geometry of active shortening in the north–west Himalayas and the implications for seismic hazard. Geophysical Journal International https://doi.org/10.17863/CAM.86998
• Ishimura, D., Iwasa, Y., Takahashi, N., Tadokoro, R., & Oda, R. (2022). Paleoseismic events and shallow subsurface structure of the central part of the Futagawa fault, which generated the 2016 Mw 7.0 Kumamoto earthquake. Geomorphology, 108387.
• Sato, T., Sato, M., Yamada, M., Saito, H., Satake, K., Nakamura, N., … & Yokoyama, Y. (2022). Two-step movement of tsunami boulders unveiled by modified viscous remanent magnetization and radiocarbon dating. Scientific Reports, 12(1), 1-12.
• García-Delgado, H., Velandia, F., Bermúdez, M. A., & Audemard, F. (2022). The present-day tectonic regimes of the Colombian Andes and the role of slab geometry in intraplate seismicity. International Journal of Earth Sciences, 1-19.

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