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1. Multi-Scale Numerical Simulation of Tsunami-Driven Debris-Field Impacts

   https://doi.org/10.1061/9780784484395.033  

   Bonus, Justin ; Arduino, Pedro ; Motley, Michael ; Eberhard, Marc ( September 2022 , ASCE Ports 22)

   In current practice, debris-field impact loading for near-water structures is usually derived from (1) infrequent case histories, (2) simplified analytical equations, and (3) practitioner experience. Via advanced numerical simulation of tsunami-driven debris-field impacts at multiple scales and conditions, we are now forging a modeling approach to address a wider range of scenarios. Broadened cases are characterized, with chaotic natures expressed stochastically. The analytical tools have the potential to strengthen the basis of ASCE 7 guidelines and to encompass events not yet described in the code. 

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2. Tsunami-driven debris experiment with varied density group conditions

   https://doi.org/10.17603/ds2-w6cr-s920  

   Park, Hyoungsu ; Cox, Daniel ( January 2021 , Designsafe-CI)

   It presents an experimental study of tsunami-driven debris transport over the flat testbed. We utilize two types of debris elements, which have the same shape but different material (wood, HDPE) to create debris of different density. We considered variations in the grouping of debris (wood only, mixed wood and HDPE, and HDPE only), parameterized by the mean specific gravity (SGg). The final dislocations and local velocity of debris elements were optically measured and compared to flow velocity. The effects of obstacles on the passage of debris and the probability of collision to obstacles were examined and the process of debris-debris and debris-obstacle interactions from debris entrainment to final dislocation was studied. The curated data could be utilized to understand initial debris entrainment, and espeically utilized to verify/validate a numerical debris transportation model. This work highlights the importance of considering debris density in estimating the longitudinal distance and spreading angle. These variables were less dependent on the initial configuration of the debris field. Future studies should consider other aspects of the phenomena, including a better understanding of the potential impact by debris on obstacles, the role of the return flow in determining the debris trajectory, and investigations of the obstacles that more realistically reflect urban shorelines subjected to strong overland flow. 

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3. Experimental study of debris transport driven by a tsunami-like wave: Application for non-uniform density groups and obstacles

   https://doi.org/10.1016/j.coastaleng.2021.103867  

   Park, Hyoungsu ; Koh, Myung-Jin ; Cox, Daniel T. ; Alam, Mohammad Shafiqual ; Shin, Sungwon ( June 2021 , Coastal Engineering)
4. Conjugate Effect of the 2011 Tohoku Reflected Tsunami‐Driven Gravity Waves in the Ionosphere

   https://doi.org/10.1029/2021GL097170  

   Chou, Min‐Yang ; Yue, Jia ; Lin, Charles C. H. ; Rajesh, P. K. ; Pedatella, N. M. ( February 2022 , Geophysical Research Letters)

   This study presents the conjugate ionospheric disturbances triggered by the 2011 Tohoku‐Oki reflected tsunami oceanic waves using the ground‐based Global Navigation Satellite System (GNSS) total electron content (TEC) observations. We found that the equatorward and westward propagating nighttime medium‐scale traveling ionospheric disturbances (MSTIDs) occurred over Japan and Australia simultaneously following the tsunami oceanic waves reflected by the Emperor Seamount Chain in the northern hemisphere. The atmospheric gravity waves driven by reflected tsunami oceanic waves are hypothesized to be the source to trigger the conjugate MSTIDs by transporting the polarization electric fields along the field line to the conjugate hemisphere. Moreover, only the southwestward propagating MSTIDs have this conjugate effect, which could be due to the wavefront orientation. The Perkins instability could also be involved in the interhemispheric coupling process. This study provides the first observational evidence that the reflected tsunami can induce conjugate ionospheric disturbances through electrodynamic forcing.

    

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5. Non‐Stationary Probabilistic Tsunami Hazard Assessments Incorporating Climate‐Change‐Driven Sea Level Rise

   https://doi.org/10.1029/2021EF002007  

   Sepúlveda, Ignacio ; Haase, Jennifer S. ; Liu, Philip L. ‐F. ; Grigoriu, Mircea ; Winckler, Patricio ( June 2021 , Earth's Future)

   We face a new era in the assessment of multiple natural hazards whose statistics are becoming alarmingly non‐stationary due to ubiquitous long‐term changes in climate. One particular case is tsunami hazard affected by climate‐change‐driven sea level rise (SLR). A traditional tsunami hazard assessment approach where SLR is omitted or included as a constant sea‐level offset in a probabilistic calculation may misrepresent the impacts of climate‐change. In this paper, a general method called non‐stationary probabilistic tsunami hazard assessment (nPTHA), is developed to include the long‐term time‐varying changes in mean sea level. The nPTHA is based on a non‐stationary Poisson process model, which takes advantage of the independence of arrivals within non‐overlapping time‐intervals to specify a temporally varying hazard mean recurrence rate, affected by SLR. The nPTHA is applied to the South China Sea (SCS) for tsunamis generated by earthquakes in the Manila Subduction Zone. The method provides unique and comprehensive results for inundation hazard, combining tsunami and SLR at a specific location over a given exposure time. The results show that in the SCS, SLR has a significant impact when its amplitude is comparable to that of tsunamis with moderate probability of exceedance. The SLR and its associated uncertainty produce an impact on nPTHA results comparable to that caused by the uncertainty in the earthquake recurrence model. These findings are site‐specific and must be analyzed for different regions. The proposed methodology, however, is sufficiently general to include other non‐stationary phenomena and can be exploited for other hazards affected by SLR.

    

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