Recent Publications
This page lists the most recently-uploaded publications that have been added to the ESD Publications database. Select one or more Research Program(s) to filter the list.
| Publication Citation | Research Program(s) | Revision create time |
|---|---|---|
| Shadab, M.A., S. Adhikari, A. Rutishauser, C. Grima, and M.A. Hesse (2024), A Mechanism for Ice Layer Formation in Glacial Firn, Geophys. Res. Lett., 51, e2024GL109893, doi:10.1029/2024GL109893. | ESI, CSP, Climate Variability and Change Program | |
| Higgins, M., S. Wdowinski, A.E.F. Cigna, and Y. Maghsoudi (2025), InSAR Detection of Slow Ground Deformation: Taking Advantage of Sentinel-1 Time Series Length in Reducing Error Sources, Remote Sens., 17, 2420, doi:10.3390/rs17142420. | ESI | |
| Sharma, A., S. Wdowinski, and R.W.2. Parkinson (2025), Type of the Paper (Article) 1 Coastal Subsidence in Cape Canaveral, FL, and Surrounding 2 Areas: Shallow Subsidence Induced by Natural and Anthropo- 3 genic Processes 4, Land, 14, x, doi:10.3390/xxxxx. | ESI | |
| Trugman, D.T. (2025), How S/P Amplitude Ratio Data Can Bias Earthquake Focal Mechanism Estimates, Seismological Research Letters, 96, 3705-3717, doi:10.1785/0220250066. | ESI | |
| Bogolub, K.R., D.T. Trugman, Y. Jiang, W.C. Hammond, K.D. Smith, R.D. Koehler, and C.D. Rowe (2025), The M 5.7 Parker Butte Earthquake near Yerington, Nevada: Anatomy of a Dual‐Plane Rupture in the Walker Lane from High‐Precision Relocated Earthquakes, InSAR, GPS, and Strong‐Motion Data. Seismological Research Letters., XX, 1-13, doi:10.1785/0220250203. | ESI | |
| Koehler, R., C. Rowe, D. Vlaha, S. Masoch, N. Hart-Wagoner, Y. Jiang, K. Bogolub, D. Trugman, B. Hammond, A. Crandall-Bear, C. Kratt, K. Dohm, and J. Vlcan (2025), The 09 December 2024 Mw5.7 Parker Butte Earthquake: Orthogonal surface fracturing and associated ground disturbances near Yerington, Nevada, central Walker Lane. Seismica, 4, doi:10.26443/seismica.v4i2.1702. | ESI | |
| Mohammad, A.T., M. Sultan, A.Z. Abotalib, P. Voice, H. Saleh, H. Karimi, M.K. Emil, and H. Elhaddad (2025), Coupled control of tectonic and surface processes on the inception and evolution of the East Saharan Mega-depressions, Geomorphology, 491, 110025, doi:10.1016/j.geomorph.2025.110025. | ESI | |
| Mohammad, A.T., M. Sultan, A.Z. Abotalib, P. Voice, H. Saleh, H. Karimi, M.K. Emil, and H. Elhaddad (2025), Coupled control of tectonic and surface processes on the inception and evolution of the East Saharan Mega-depressions, Geomorphology, 491, 110025, doi:10.1016/j.geomorph.2025.110025. | ESI | |
| Milliner, C., J.P. Avouac, J.F. Dolan, et al. (2025), Localization of inelastic strain with fault maturity and effects on earthquake characteristics, Nat. Geosci., 18, 793-800, doi:10.1038/s41561-025-01752-x. | ESI | |
| Chatterjee, A., C.N. Pennington, D.T. Trugman, and W.R. Walter (2025), A Deep Learning‐Aided Workflow for Decoding the Stress Regime of Southern Nevada, Seismological Research Letters, doi:10.1785/0220240443. | ESI | |
| Trugman, D.T. (2024), A High‐Precision Earthquake Catalog for Nevada, Seismological Research Letters, 95, 3737-3745, doi:10.1785/0220240106. | ESI | |
| Patton, A.M., C.N. Pennington, W.R. Walter, and D.T. Trugman (2025), Improving Measurements of Earthquake Source Parameters Exploring Uncertainty in Moment Estimation for Small Earthquakes in Southern Nevada Using the Coda Envelope Method, Bull. Seismol. Soc. Am., 115, 1308-1317, doi:10.1785/0120240120. | ESI | |
| Vavra, E., Y. Fialko, F. Bulut, A. Garagon, S. Yalvac, and C. Yaltirak (2025), The 2023 Mw 7.8-7.7 Kahramanmaraş earthquakes were loosely slip-predictable, Communications Earth and Environment, 6, 80, doi:10.1038/s43247-024-01969-5. | ESI | |
| Jia, Z., Z. Jin, M. Marchandon, T. Ulrich, A.-A. Gabriel, W. Fan, P. Shearer, X. Zou, J. Rekoske, F. Bulut, A. Garagon, and Y. Fialko (2023), NATURAL HAZARDS The complex dynamics of the 2023 Kahramanmaraş, Turkey, Mw 7.8-7.7 earthquake doublet, Science, 381, 985-990, doi:10.1126/science.adi0685. | ESI | |
| Zou, X., and Y. Fialko (2024), Can large strains be accommodated by small faults: “Brittle flow of rocks, revised. Earth and Space Science, 11, e2024EA003824, doi:10.1029/2024EA003824. | ESI | |
| Shearer, P.M., N.S. Senobari, and Y. Fialko (2024), Implications of a Reverse Polarity Earthquake Pair on Fault Friction and Stress Heterogeneity Near Ridgecrest, California, J. Geophys. Res., 129, e2024JB029562, doi:10.1029/2024JB029562. | ESI | |
| Vavra, E.J., Y. Fialko, T. Rockwell, R. Bilham, P. Štěpančíková, J. Stemberk, P. Tábořík, and J. Stemberk (2024), Characteristic Slow‐Slip Events on the Superstition Hills Fault, Southern California, Geophys. Res. Lett., 51, e2023GL107244, doi:10.1029/2023GL107244. | ESI | |
| Jin, Z., Y. Fialko, H. Yang, and Y. Li (2023), Transient Deformation Excited by the 2021 M7.4 Maduo (China) Earthquake: Evidence of a Deep Shear Zone, J. Geophys. Res., doi:10.1029/2023JB026643. | ESI | |
| Trugman, D.T., and Y. Ben-Zion (2024), Potency-Magnitude Scaling Relations and a Unified Earthquake Catalog for the Western United States, The Seismic Record, 4, 223-230, doi:10.1785/0320240022. | ESI | |
| Regmi, N.R., J.I. Walter, J. Jiang, A.M. Orban, and N.W. Hayman (2024), Spatial patterns of landslides in a modest topography of the Ozark and Ouachita Mountains, Usa. Catena, 245, 108344. | ESI |