New papers on paleoseismology, active tectonics, and archaeoseismology (Jan 2023)

I hope you all had a wonderful start into 2023. May it bring you health and success, great field trips, lots of data, and nice reviewers. Here’s the latest list of papers that already made it through review. Enjoy reading!

• Liu, S. H., Lüthgens, C., Hardt, J., Hebenstreit, R., Böse, M., & Frechen, M. (2022). Late Quaternary formation of the Miaoli Tableland in northwest Taiwan, an interplay of tectonic uplift and fluvial processes dated by OSL. Quaternary Research, 1-22.
• Husker, A., Werner, M. J., Bayona, J. A., Santoyo, M., & Corona‐Fernandez, R. D. (2022). A Test of the Earthquake Gap Hypothesis in Mexico: The Case of the Guerrero Gap. Bulletin of the Seismological Society of America.
• Hidalgo‐Leiva, D. A., Linkimer, L., Arroyo, I. G., Arroyo‐Solórzano, M., Piedra, R., Climent, A., … & Rojas, W. (2022). The 2022 Seismic Hazard Model for Costa Rica. Bulletin of the Seismological Society of America.
• Jobe, J. T., Briggs, R., Gold, R., DeLong, S., Hille, M., Delano, J., … & Calvert, A. T. The Pondosa fault zone: A distributed dextral-normal-oblique fault system in northeastern California, USA. Geosphere.
• Ocakoğlu, F., & Tuncay, E. (2022). Geological and geomechanical evidence from the Sünnet landslides (NW Anatolia) for an Mw8. 0 cascade rupture in the North Anatolian Fault 8 ky ago. Tectonophysics, 229682.
• Papadopoulos, G. A., Triantafyllou, I., & Vassilopoulou, A. (2022). The mid-6th century AD enigmatic mega earthquake and tsunami in central Greece: a seismotectonic, archeological, and historical reexamination. The Holocene, 09596836221138330.
• Gómez‐Novell, O., Ortuño, M., García‐Mayordomo, J., Insua‐Arévalo, J. M., Rockwell, T. K., Baize, S., … & Masana, E. Improved geological slip rate estimations in the complex Alhama de Murcia Fault zone (SE Iberia) and its implications for fault behavior. Tectonics, e2022TC007465.
• Battogtokh Davaasambuu, Matthieu Ferry, Jean-Francois Ritz & Ulziibat Munkhuu(2022). The Ar-Hötöl surface rupture along the Khovd fault (Mongolian Altay). Journal of Maps.
• Henriquet, M., Kordic, B., Métois, M., Lasserre, C., Baize, S., Benedetti, L., et al. (2022). Rapid remeasure of dense civilian networks as a game-changer tool for surface deformation monitoring: The case study of the M_w 6.4 2020 Petrinja earthquake, Croatia. Geophysical Research Letters, 49, e2022GL100166.
• Rockwell, T. K., Costa, C. H., Meigs, A. J., Ragona, D., Owen, L. A., Murari, M. K., … & Richard, A. D. (2022). Paleoseismology of the Marquesado-La Rinconada thrust system, Eastern Precordillera of Argentina. Frontiers in Earth Science, 2235.
• Picotti, V., Romano, M. A., Ponza, A., Guido, F. L., & Peruzza, L. (2022). The Montello thrust and the active mountain front of the eastern Southern Alps (northeast Italy). Tectonics, e2022TC007522.
• Barrell, D. J., Stirling, M. W., Williams, J. N., Sauer, K. M., & van den Berg, E. J. (2022). Hundalee Fault, North Canterbury, New Zealand: late Quaternary activity and regional tectonics. New Zealand Journal of Geology and Geophysics, 1-24.
• Déverchère, J., Barbé, A., Kernec, M., Jaud, M., & Ruault, R. (2022). A submarine morphotectonic analysis combining GIS-based methods and Virtual Reality: Case study of the low-rate active thrust faulting off Boumerdès (Algeria). Frontiers in Earth Science, 10, 2524.
• de Nardis, R., Pandolfi, C., Cattaneo, M., Monachesi, G., Cirillo, D., Ferrarini, F., … & Lavecchia, G. (2022). Lithospheric double shear zone unveiled by microseismicity in a region of slow deformation. Scientific Reports, 12(1), 1-18.
• Bello, S., Lavecchia, G., Andrenacci, C., Ercoli, M., Cirillo, D., Carboni, F., … & Brozzetti, F. (2022). Complex trans-ridge normal faults controlling large earthquakes. Scientific Reports, 12(1), 1-20.
• Churchill, R. M., Werner, M. J., Biggs, J., & Fagereng, Å. (2022). Relative Afterslip Moment does not correlate with Aftershock Productivity: Implications for the relationship between Afterslip and Aftershocks. Geophysical Research Letters, e2022GL101165.
• López‐Venegas, A. M., Mattioli, G. S., Solares‐Colón, M., Mencin, D., & Jansma, P. E. (2022). Estimating Coseismic Deformation of Southwestern Puerto Rico from the 7 January 2020 Mw 6.4 Earthquake: Constraints from Campaign and Continuous GPS. Bulletin of the Seismological Society of America.
• 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, 229502.
• Shao, Y., van der Woerd, J., Liu‐Zeng, J., Yuan, D., Yao, Y., Zou, X., & Wang, P. Shortening rates and recurrence of large earthquakes from folded and uplifted terraces in the Western Danghe Nan Shan foreland, north Tibet. Journal of Geophysical Research: Solid Earth, e2021JB023736.
• Silva, P. G., Roquero, E., Medialdea, A., Bardají, T., Élez, J., & Rodríguez-Pascua, M. A. (2022). Dating of Holocene Sedimentary and Paleosol Sequence within the Guadalentín Depression (Murcia, SE Spain): Paleoclimatic Implications and Paleoseismic Signals. Geosciences, 12(12), 459.
• Huang, Z., & Zhou, Y. (2022). A Complete Map of Fine‐Scale Slip Rate Distribution and Earthquake Potential along the Haiyuan Fault System. Geophysical Research Letters, e2022GL101805.
• Vitale, S., Albanese, S., Di Maio, R., Ambrosino, M., Cicchella, D., De Paola, C., … & Ciarcia, S. (2022). Insights on the active Southern Matese Fault system through geological, geochemical, and geophysical investigations of the CO2 gas vent in the Solopaca area (southern Apennines, Italy). Tectonophysics, 229657.
• 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.
• Gaidzik, K., & Kázmér, M. (2023). The Børglum fault was active in historical times. Comment on ‘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’by Brandes et al.[Quat. Sci. Rev. 289 (2022) 107619]. Quaternary Science Reviews, 301, 107933.
• Malik, J. N., Arora, S., Gadhavi, M. S., Singh, G., Kumar, P., Johnson, F. C., … & Raoof, J. (2022). Geological evidence of paleo-earthquakes on transverse right-lateral strike-slip fault along the NW Himalayan front: Implications towards Fault Segmentation and Strain Partitioning. Journal of Asian Earth Sciences, 105518.
• Xu, D., He, Z., Ma, B., Liang, K., Long, J., & Zhang, H. Classification and Semiquantitative Evaluation of Palaeoearthquake Identification from Trenches on Normal Faults: A Case Study of Holocene Palaeoearthquake Events from the Northern Margin of the Hetao Basin, China. Tectonics, e2022TC007443.
• Calais, E., Symithe, S. J., & de Lépinay, B. M. (2022). Strain Partitioning within the Caribbean–North America Transform Plate Boundary in Southern Haiti, Tectonic and Hazard Implications. Bulletin of the Seismological Society of America.

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