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Manaster, Adam E.; Sheehan, Anne F.; Goldberg, Dara E.; Barnhart, Katherine R.; Roth, Ethan H. (2025) Detection of Landslide‐Generated Tsunami by Shipborne GNSS Precise Point Positioning. Geophysical Research Letters, 52 (8). doi:10.1029/2024gl112472

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Reference TypeJournal (article/letter/editorial)
TitleDetection of Landslide‐Generated Tsunami by Shipborne GNSS Precise Point Positioning
JournalGeophysical Research Letters
AuthorsManaster, Adam E.Author
Sheehan, Anne F.Author
Goldberg, Dara E.Author
Barnhart, Katherine R.Author
Roth, Ethan H.Author
Year2025 (April 28)Volume52
Issue8
PublisherAmerican Geophysical Union (AGU)
DOIdoi:10.1029/2024gl112472Search in ResearchGate
Generate Citation Formats
Mindat Ref. ID18339628Long-form Identifiermindat:1:5:18339628:4
GUID0
Full ReferenceManaster, Adam E.; Sheehan, Anne F.; Goldberg, Dara E.; Barnhart, Katherine R.; Roth, Ethan H. (2025) Detection of Landslide‐Generated Tsunami by Shipborne GNSS Precise Point Positioning. Geophysical Research Letters, 52 (8). doi:10.1029/2024gl112472
Plain TextManaster, Adam E.; Sheehan, Anne F.; Goldberg, Dara E.; Barnhart, Katherine R.; Roth, Ethan H. (2025) Detection of Landslide‐Generated Tsunami by Shipborne GNSS Precise Point Positioning. Geophysical Research Letters, 52 (8). doi:10.1029/2024gl112472
In(2025, April) Geophysical Research Letters Vol. 52 (8). American Geophysical Union (AGU)

References Listed

These are the references the publisher has listed as being connected to the article. Please check the article itself for the full list of references which may differ. Not all references are currently linkable within the Digital Library.

Anchorage Daily News. (2022).Road along bay in Seward remains buried under landslide. Retrieved fromhttps://www.adn.com/alaska‐news/2022/05/07/landslide‐closes‐lowell‐point‐road‐in‐seward
Annunziato, Alessandro (2022) Tsunami Detection Model for Sea Level Measurement Devices. Geosciences, 12 (10) 386 doi:10.3390/geosciences12100386
()
Barnhart K. R. (2021) Preliminary assessment of the wave generating potential from landslides at Barry Arm, Prince William Sound , 28
Not Yet Imported: - journal-article : 10.1016/j.advwatres.2011.02.016

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
Bock, Y., Melgar, D., Crowell, B. W. (2011) Real-Time Strong-Motion Broadband Displacements from Collocated GPS and Accelerometers. Bulletin of the Seismological Society of America, 101 (6). 2904-2925 doi:10.1785/0120110007
Boots M. T. (2022) Crews begin clearing huge landslide that covered road in Seward
Corsa, Brianna D., Jacquemart, Mylène, Willis, Michael J., Tiampo, Kristy F. (2022) Characterization of large tsunamigenic landslides and their effects using digital surface models: A case study from Taan Fiord, Alaska. Remote Sensing of Environment, 270. 112881pp. doi:10.1016/j.rse.2021.112881
Not Yet Imported: - journal-article : 10.1017/S0373463318000887

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
()
()
Not Yet Imported: - journal-article : 10.3390/s23218874

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Foster, James H., Brooks, Benjamin A., Wang, Dailin, Carter, Glenn S., Merrifield, Mark A. (2012) Improving tsunami warning using commercial ships. Geophysical Research Letters, 39 (9) doi:10.1029/2012gl051367
Foster, J. H., Carter, G. S., Merrifield, M. A. (2009) Ship-based measurements of sea surface topography. Geophysical Research Letters, 36 (11) doi:10.1029/2009gl038324
Fujita, Masayuki, Ishikawa, Tadashi, Mochizuki, Masashi, Sato, Mariko, Toyama, Shin-ichi, Katayama, Masato, Kawai, Koji, Matsumoto, Yoshihiro, Yabuki, Tetsuichiro, Asada, Akira, Colombo, Oscar L. (2006) GPS/Acoustic seafloor geodetic observation: method of data analysis and its application. Earth, Planets and Space, 58 (3) 265-275 doi:10.1186/bf03351923
()
George D. L. (2006) Finite volume methods and adaptive refinement for tsunami propagation and inundation , 183
George D. L. Barnhart K. R. &Iverson R. M.(2025).D‐Claw ‐ a library for simulation of granular‐fluid flows version 1.0.0[Software].U.S. Geological Survey.https://doi.org/10.5066/P13GUXUT
George, David L., Iverson, Richard M. (2014) A depth-averaged debris-flow model that includes the effects of evolving dilatancy. II. Numerical predictions and experimental tests. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 470 (2170). 20130820pp. doi:10.1098/rspa.2013.0820
George, D. L., Iverson, R. M., Cannon, C. M. (2017) New methodology for computing tsunami generation by subaerial landslides: Application to the 2015 Tyndall Glacier landslide, Alaska. Geophysical Research Letters, 44 (14) 7276-7284 doi:10.1002/2017gl074341
Goldberg, Dara E., Haynie, Kirstie L. (2022) Ready for Real Time: Performance of Global Navigation Satellite System in 2019 Mw 7.1 Ridgecrest, California, Rapid Response Products. Seismological Research Letters, 93 (2) 517-530 doi:10.1785/0220210278
Guo, Jinyun, Dong, Zhenghua, Tan, Zhengguang, Liu, Xin, Chen, Chuanfa, Hwang, Cheinway (2016) A crossover adjustment for improving sea surface height mapping from in-situ high rate ship-borne GNSS data using PPP technique. Continental Shelf Research, 125. 54-60 doi:10.1016/j.csr.2016.07.002
()
Hossen, M. J., Mulia, Iyan E., Mencin, David, Sheehan, Anne F. (2021) Data Assimilation for Tsunami Forecast With Ship‐Borne GNSS Data in the Cascadia Subduction Zone. Earth and Space Science, 8 (3) doi:10.1029/2020ea001390
()
Iverson, Richard M., George, David L. (2014) A depth-averaged debris-flow model that includes the effects of evolving dilatancy. I. Physical basis. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 470 (2170). 20130819pp. doi:10.1098/rspa.2013.0819
Iverson, R. M., George, D. L. (2016) Modelling landslide liquefaction, mobility bifurcation and the dynamics of the 2014 Oso disaster. Géotechnique, 66 (3). 175-187 doi:10.1680/jgeot.15.lm.004
()
Not Yet Imported: - book-chapter : 10.1007/978-3-319-42928-1_33

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Not Yet Imported: - journal-article : 10.1785/0320230044

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Not Yet Imported: - journal-article : 10.1016/j.ocemod.2021.101943

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Not Yet Imported: - book-chapter : 10.1007/978-3-319-42928-1_25

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Not Yet Imported: - report-component : 10.3133/ds374

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Larson, Kristine M., Freymueller, Jeffrey T., Philipsen, Steven (1997) Global plate velocities from the Global Positioning System. Journal of Geophysical Research: Solid Earth, 102. 9961-9981 doi:10.1029/97jb00514
Not Yet Imported: - journal-article : 10.1017/S0962492911000043

If you would like this item imported into the Digital Library, please contact us quoting Journal ID
()
Manaster A. Sheehan A. Goldberg D. Barnhart K. &Roth E.(2025).Supporting information for "detection of subaerial‐landslide‐generated waves by ship‐borne GNSS precise point positioning[Dataset].U.S. Geological Survey.https://doi.org/10.5066/P13BUGIZ
Manaster A. E. (2024) Feasibility of GNSS precise point positioning of ships to detect tsunamis, landslide‐generated waves, and other anomalies in sea surface height
()
Melgar, Diego, Crowell, Brendan W., Melbourne, Timothy I., Szeliga, Walter, Santillan, Marcelo, Scrivner, Craig (2020) Noise Characteristics of Operational Real‐Time High‐Rate GNSS Positions in a Large Aperture Network. Journal of Geophysical Research: Solid Earth, 125 (7) doi:10.1029/2019jb019197
Melgar, Diego, Melbourne, Timothy I., Crowell, Brendan W., Geng, Jianghui, Szeliga, Walter, Scrivner, Craig, Santillan, Marcelo, Goldberg, Dara E. (2020) Real-Time High-Rate GNSS Displacements: Performance Demonstration during the 2019 Ridgecrest, California, Earthquakes. Seismological Research Letters, 91 (4) 1943-1951 doi:10.1785/0220190223
Murray, J. R., Crowell, B. W., Grapenthin, R., Hodgkinson, K., Langbein, J. O., Melbourne, T., Melgar, D., Minson, S. E., Schmidt, D. A. (2018) Development of a Geodetic Component for the U.S. West Coast Earthquake Early Warning System. Seismological Research Letters, 89 (6). 2322-2336 doi:10.1785/0220180162
North Atlantic Treaty Organization Shipping Centre. (2021).AIS (Automatic Identification system) overview. Retrieved fromhttps://shipping.nato.int/nsc/operations/news/2021/ais‐automatic‐identification‐system‐overview
()
Pavlis, Nikolaos K., Holmes, Simon A., Kenyon, Steve C., Factor, John K. (2012) The development and evaluation of the Earth Gravitational Model 2008 (EGM2008) Journal of Geophysical Research: Solid Earth, 117. doi:10.1029/2011jb008916
Penna, Nigel T., Morales Maqueda, Miguel A., Martin, Ian, Guo, Jing, Foden, Peter R. (2018) Sea Surface Height Measurement Using a GNSS Wave Glider. Geophysical Research Letters, 45 (11) 5609-5616 doi:10.1029/2018gl077950
Petley D. (2022) The Lowell point landslide in Alaska
Saari, Timo, Bilker-Koivula, Mirjam, Koivula, Hannu, Nordman, Maaria, Häkli, Pasi, Lahtinen, Sonja (2021) Validating Geoid Models with Marine GNSS Measurements, Sea Surface Models, and Additional Gravity Observations in the Gulf of Finland. Marine Geodesy, 44 (3) 196-214 doi:10.1080/01490419.2021.1889727
Varbla, Sander, Ellmann, Artu, Delpeche-Ellmann, Nicole (2020) Validation of Marine Geoid Models by Utilizing Hydrodynamic Model and Shipborne GNSS Profiles. Marine Geodesy, 43. 134-162 doi:10.1080/01490419.2019.1701153
Wessel, P., Luis, J. F., Uieda, L., Scharroo, R., Wobbe, F., Smith, W. H. F., Tian, D. (2019) The Generic Mapping Tools Version 6. Geochemistry, Geophysics, Geosystems, 20 (11) 5556-5564 doi:10.1029/2019gc008515

See Also

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Karasözen, Ezgi; West, Michael E.; Barnhart, Katherine R.; Lyons, John J.; Nichols, Terry; Schaefer, Lauren N.; Bahng, Bohyun; Ohlendorf, Summer; Staley, Dennis M.; Wolken, Gabriel J. (2025) 2024 Surprise Inlet Landslides: Insights From a Prototype Landslide‐Triggered Tsunami Monitoring System in Prince William Sound, Alaska. Geophysical Research Letters, 52 (13). doi:10.1029/2025gl115911
Shelly, David R.; Goldberg, Dara E.; Wech, Aaron G.; Thomas, Amanda M. (2025) A Northeast‐Dipping Zone of Low‐Frequency Earthquakes at the Southern Edge of Cascadia Subduction. Geophysical Research Letters, 52 (12). doi:10.1029/2025gl116116
Hossen, M. J., Mulia, Iyan E., Mencin, David, Sheehan, Anne F. (2021) Data Assimilation for Tsunami Forecast With Ship‐Borne GNSS Data in the Cascadia Subduction Zone. Earth and Space Science, 8 (3) doi:10.1029/2020ea001390
Zajdel, Radosław, Kazmierski, Kamil, Sośnica, Krzysztof (2022) Orbital Artifacts in Multi‐GNSS Precise Point Positioning Time Series. Journal of Geophysical Research: Solid Earth, 127 (2) doi:10.1029/2021jb022994
Pino, Nicola Alessandro, Boschi, Enzo (2009) Seismic detection of island trapped sea waves from a landslide-generated tsunami at Stromboli (Italy) Geophysical Research Letters, 36 (9) doi:10.1029/2009gl037550
Sheehan, Anne F., Gusman, Aditya R., Satake, Kenji (2019) Improving Forecast Accuracy With Tsunami Data Assimilation: The 2009 Dusky Sound, New Zealand, Tsunami. Journal of Geophysical Research: Solid Earth, 124 (1) 566-577 doi:10.1029/2018jb016575
Tyler, R. H. (2005) A simple formula for estimating the magnetic fields generated by tsunami flow. Geophysical Research Letters, 32 (9) doi:10.1029/2005gl022429
Thompson Jobe, Jessica A.; Hanagan, Catherine E.; Hatem, Alexandra E.; Barnhart, William D.; Goldberg, Dara E.; Yeck, William L. (2025) Surface Rupture from an Aftershock: Remote Observations from the January 2024 Wushi (Aykol), China, Earthquakes. Seismological Research Letters, 96 (6). doi:10.1785/0220240347
Kubota, Tatsuya; Kubo, Hisahiko; Saito, Tatsuhiko (2025) Reliable Fault Modeling of an Mw 7.1 Earthquake in Hyuganada Sea on 8 August 2024 by Offshore Tsunami Data From New Seafloor Network N‐net and Onshore GNSS Data. Geophysical Research Letters, 52 (8). doi:10.1029/2025gl115391
Aguiar, C. R., Monico, J. F. G., Moraes, A. O. (2025) Impact of Ionospheric Scintillations on GNSS Availability and Precise Positioning. Space Weather, 23 (2). doi:10.1029/2024sw004217
Li, Chuxuan; Handwerger, Alexander L.; Horton, Daniel E. (2025) Mixed Hydrometeorological Processes Explain Regional Landslide Potential. Geophysical Research Letters, 52 (14). doi:10.1029/2025gl115912
 
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