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

I am on my way back from the PATA Days in France, which were great. A detailed report will follow later. In the meantime, enjoy reading the latest papers – we have a nice variety of topics and working areas.

• Griffin, J. D., Stirling, M. W., Wilcken, K. M., & Barrell, D. J. (2022). Late Quaternary slip rates for the Hyde and Dunstan faults, southern New Zealand: Implications for strain migration in a slowly deforming continental plate margin. Tectonics, e2022TC007250.
• Meschis, M., Roberts, G. P., Robertson, J., Mildon, Z. K., Sahy, D., Goswami, R., … & Iezzi, F. (2022). Out of phase Quaternary uplift-rate changes reveal normal fault interaction, implied by deformed marine palaeoshorelines. Geomorphology, 108432.
• Zhao, D., Qu, C., Shan, X., Bürgmann, R., Chen, H., & Materna, K. (2022). Transient fault creep on the Xidatan (Tibet) fault driven by viscoelastic relaxation following the 2001 Kokoxili earthquake. Geology.
• Kázmér, M., Györi, E., & Gaidzik, K. (2022). Was Antiquity seismically more active than the Middle Ages? – Roman earthquakes in Pannonia and Dacia. 3rd European Conference on Earthquake Engineering and Seismology, Bucharest, Romania.
• Hamiel, Y., Katz, O., & Avni, Y. (2022). Migration and localization of faulting near the intersection of the Dead Sea Fault and the Carmel− Gilboa− Faria Fault System. GSA Bulletin.
• Aron, F., Johnstone, S., Mavrommatis, A., Sare, R., Maerten, F., Loveless, J. P., … & Hilley, G. E. (2022). Mountain rivers reveal the earthquake hazard of geologic faults in Silicon Valley. Geophysical Research Letters, e2022GL099220.
• Shea, H. N., & Barnhart, W. D. (2022). The Geodetic Centroid (gCent) Catalog: Global Earthquake Monitoring with Satellite Imaging Geodesy. Bulletin of the Seismological Society of America.
• Pollitz, F. F., Evans, E. L., Field, E. H., Hatem, A. E., Hearn, E. H., Johnson, K., … & Zeng, Y. (2022). Western US Deformation Models for the 2023 Update to the US National Seismic Hazard Model. Seismological Research Letters.
• Hatem, A. E., Reitman, N., Briggs, R., Gold, R., JA, T. J., & Burgette, R. (2022). Western US geologic deformation model for use in the US National Seismic Hazard Model 2023. Seismological Research Letters.
• Zeng, Y. (2022). GPS Velocity Field of the Western United States for the 2023 National Seismic Hazard Model Update. Seismological Research Letters.
• Hinzen, K.-G., Meghraoui, M., Bahrouni, N., & Reamer, S. K. (2022). Testing the earthquake damage and vulnerability of the Cherichira aqueduct bridge, Kairouan (Tunisia) with discrete element modeling. Mediterranean Geoscience Reviews.
• Don, J., Shaw, J. H., Nicolae, A. L., Sorlien, C. C., Nicholson, C., & Plesch, A. (2022). Late Pleistocene Slip Rate and 3D Geometry of the Mid‐Channel Blind Thrust, Santa Barbara Channel, California, and Their Implications for Earthquake Hazards. Bulletin of the Seismological Society of America.
• Wang, Y., Lin, Y. N., Ota, Y., Chung, L. H., Shyu, J. B. H., Chiang, H. W., … & Shen, C. C. (2022). Mud Diapir or fault‐related fold? On the development of an active mud‐cored anticline offshore southwestern Taiwan. Tectonics, e2022TC007234.
• Stanko, D., Sović, I., Belić, N., & Markušić, S. (2022). Analysis of Local Site Effects in the Međimurje Region (North Croatia) and Its Consequences Related to Historical and Recent Earthquakes. Remote Sensing, 14(19), 4831.
• Langridge, R. M., Clark, K. J., Almond, P., Baize, S., Howell, A., Kearse, J., … & Amos, C. (2022). Late Holocene earthquakes on the Papatea Fault and its role in past earthquake cycles, Marlborough, New Zealand. New Zealand Journal of Geology and Geophysics, 1-24.
• Lazos, I., Papanikolaou, I., Sboras, S., Foumelis, M., & Pikridas, C. (2022). Geodetic Upper Crust Deformation Based on Primary GNSS and INSAR Data in the Strymon Basin, Northern Greece—Correlation with Active Faults. Applied Sciences, 12(18), 9391.
• Adhikari, L. B., Laporte, M., Bollinger, L., Vergne, J., Lambotte, S., Koirala, B. P., … & Perrier, F. (2022). Seismically active structures of the Main Himalayan Thrust revealed before, during and after the 2015 Mw 7.9 Gorkha earthquake in Nepal. Geophysical Journal International.
• Premus, J., Gallovič, F., & Ampuero, J. P. (2022). Bridging time scales of faulting: From coseismic to postseismic slip of the M w 6.0 2014 South Napa, California earthquake. Science Advances, 8(38), eabq2536.
• Azennoud, K., Baali, A., El Asmi, H., Brahim, Y. A., Hakam, O., Hayati, A., & El Kamel, T. (2022). Soft-sediment deformation structures recognised in a reverse-drag associated with normal faulting (Lake Ifrah, Northwest Africa): Palaeoseismic assessment and neotectonic implications. Sedimentary Geology, 106264.
• Hu, Z., Yang, X., Li, A., Yang, H., Yuan, H., & Zuo, Y. (2022). Multiple Mw≥ 6.5 Strong‐Major Paleoearthquakes Occurred Before the 2017 Mw 6.3 Jinghe Earthquake: Evidence from Trenching the Jinghenan Fault. Seismological Research Letters.
• Wang, H., Li, D., Li, K., Deng, L., & Luo, P. (2022). Late Quaternary Fault Activity of the Southern Segment of the Daliangshan Fault along the Southeastern Margin of the Tibetan Plateau and Its Implications for Fault Rupture Behaviour at Stepovers. Lithosphere, 2022(1), 9259647.
• Li, C., Li, T., Shan, X., & Zhang, G. (2022). Extremely Large Off‐Fault Deformation during the 2021 Mw 7.4 Maduo, Tibetan Plateau, Earthquake. Seismological Research Letters.

Tweet