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1. Technology Transfer of PMEL Tsunami Research Protects Populations and Expands the New Blue Economy

   https://doi.org/10.5670/oceanog.2023.205  

   Titov, Vasily; Meinig, Christian; Stalin, Scott; Wei, Yong; Moore, Christopher; Bernard, Eddie (January 2023, Oceanography)

   NOAA Pacific Marine Environmental Laboratory’s (PMEL’s) approach to tsunami research is unique among such laboratories in that tsunami observations and modeling are under one roof, offering the advantages of enhancing the speed and lowering the cost of developments. Here, we chronicle the history of the transfer of deep-ocean observational and flooding modeling technologies within and outside of NOAA and provide a case study for future transfers. PMEL and partners’ efforts in transferring tsunami technology have been very successful, resulting in improved protection of global communities with high tsunami risk while enhancing the new blue economy. The transfer of observational technology within NOAA required years of effort, while the transfer outside of NOAA only required a patent and license agreement. During the transfer process, three additional generations of observational technologies were created. The transfer of tsunami flooding modeling technology required a validation process for transfer into NOAA operations and an international training program to allow access to the technology by other countries. During this model development, a web-based product was created to simplify the use of and access to these models for both real-time and hazard assessment applications. We present lessons learned from these transfers, including the need for support as long as the technology is in use. The tsunami transfer process created a wealth of economic expansion while protecting coastal citizens from future tsunamis. 

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2. Detection of Earthquake Infragravity and Tsunami Waves With Underwater Distributed Acoustic Sensing

   https://doi.org/10.1029/2023GL106767  

   Xiao, Han; Spica, Zack_J; Li, Jiaxuan; Zhan, Zhongwen (January 2024, Geophysical Research Letters)

   Abstract Underwater Distributed Acoustic Sensing (DAS) utilizes optical fiber as a continuous sensor array. It enables high‐resolution data collection over long distances and holds promise to enhance tsunami early warning capabilities. This research focuses on detecting infragravity and tsunami waves associated with earthquakes and understanding their origin and dispersion characteristics through frequency‐wavenumber domain transformations and beamforming techniques. We propose a velocity correction method based on adjusting the apparent channel spacing according to water depth to overcome the challenge of detecting long‐wavelength and long‐period tsunami signals. Experimental results demonstrate the successful retrieval of infragravity and tsunami waves using a subsea optical fiber in offshore Oregon. These findings underscore the potential of DAS technology to complement existing infragravity waves detection systems, enhance preparedness, and improve response efforts in coastal communities. Further research and development in this field are crucial to fully utilize the capabilities of DAS for enhanced tsunami monitoring and warning systems. 

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3. Backyard Buoys: Meeting Needs of Coastal, Indigenous Communities Through Co-Design and Co-Production

   https://doi.org/10.5670/oceanog.2025.105  

   Newton, Jan; Wisdom, Sheyna; Iwamoto, Melissa; Carini, Roxanne; Watson, Jordan; Boulay, Sebastien; Mactavish, Duncan; Hagen, Jennifer; Schumacker, Joe; Rudolph, Dua; et al (January 2025, Oceanography)

   The Backyard Buoys project (https://backyardbuoys.org/) enables Indigenous and coastal communities to gather and use wave data to enhance their blue economies and hazard protections. These communities have been historically underserved, and climate change is making weather and wave predictability even harder. Leveraging low-cost, scalable marine technology in partnership with regional ocean observing networks, Backyard Buoys offers a system for community-managed ocean buoys and data access to complement Indigenous Knowledge. These innovations include a sustainable process for community-led implementation and stewardship of affordable ocean buoys along with co-designed and co-produced mobile and web-based applications (apps) that render data easy to access and understand. 

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4. Evacuation behaviors in tsunami drills

   https://doi.org/10.1007/s11069-022-05208-y  

   Chen, Chen; Mostafizi, Alireza; Wang, Haizhong; Cox, Dan; Cramer, Lori (February 2022, Natural Hazards)

   This paper presents the use of tsunami evacuation drills within a coastal community in the Cascadia Subduction Zone (CSZ) to better understand evacuation behaviors and thus to improve tsunami evacuation preparedness and resilience. Evacuees’ spatial trajectory data were collected by Global Navigation Satellite System (GNSS) embedded in mobile devices. Based on the empirical trajectory data, probability functions were employed to model people’s walking speed during the evacuation drills. An Evacuation Hiking Function (EHF) was established to depict the speed–slope relationship and to inform evacuation modeling and planning. The regression analysis showed that evacuees’ speed was significantly negatively associated with slope, time spent during evacuation, rough terrain surface, walking at night, and distance to destination. We also demonstrated the impacts of milling time on mortality rate based on participants’ empirical evacuation behaviors and a state-of-the-art CSZ tsunami inundation model. Post-drill surveys revealed the importance of the drill as an educational and assessment tool. The results of this study can be used for public education, evacuation plan assessment, and evacuation simulation models. The drill procedures, designs, and the use of technology in data collection provide evidence-driven solutions to tsunami preparedness and inspire the use of drills in other types of natural disasters such as wildfires, hurricanes, volcanoes, and flooding. 

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5. Coastal emergency managers’ risk perception and decision making for the Tonga distant tsunami

   https://doi.org/10.1016/j.ijdrr.2024.104560  

   Moore, Ashley; Jean, Cassandra; Korfmacher, Matias; Vickery, Jamie; Bostrom, Ann; Errett, Nicole A (June 2024, International Journal of Disaster Risk Reduction)

   On January 15, 2022, the Hunga-Tonga-Hunga-Ha'apai (Tonga) volcano erupted and triggered a tsunami forecasted to reach North America. This event provided a unique opportunity to investigate risk perception and communication among coastal emergency managers and emergency program coordinators (EMs). In response, this research explores 1) how risk can be communicated most effectively and 2) how risk perceptions associated with “distant” tsunami alerts and warnings affect EMs' willingness to issue emergency alerts. A purposive sample of coastal EMs (n = 21) in the U.S. Pacific Northwest participated in semi-structured interviews. Participants represented Tribal, county, state, and federal agencies in Washington, Oregon, and California. Interview transcripts were deductively coded and thematically analyzed. Participants perceived low risk from the Tonga tsunami but took precautionary measures and alerted the public. Participants described how their actions were driven by community characteristics and the anticipated reactions to messaging among residents. Many reported the need to balance notifying the public and avoiding the negative impacts of their messaging (e.g., “crying wolf,” panic, curiosity). The unique nature of the event led to identification of unanticipated facilitators and barriers to decision- making among participants. These findings can inform distant tsunami risk communication and preparedness for coastal communities. 

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