The lower ionosphere disturbances observed during the chain of the meteotsunamis in the Mediterranean Sea in June 2014

Solovieva, M.; Рожной, А.; Шалимов, С. Л.; Shevchenko, G. V.; Biagi, P. F.; Fedun, V.

doi:10.1007/s11069-020-04223-1

Cited by 3 publications

(2 citation statements)

References 33 publications

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“…The model is applied to four Adriatic meteotsunami events and mostly leads to increasing the meteotsunami run-up height, up to 70% compared to the standard models (without inundation). Solovieva et al (2021) describe the ionospheric disturbances recorded during the chain of meteotsunamis affecting the Mediterranean Sea in June 2014 (e.g. Šepić et al 2015b) and found significant variations with periods ranging from 10 to 40-70 min at various stations, i.e.…”

Section: Mediterranean and Black Sea Meteotsunamismentioning

confidence: 99%

Special issue on the global perspective on meteotsunami science: editorial

2021

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Section: Mediterranean and Black Sea Meteotsunamismentioning

confidence: 99%

Special issue on the global perspective on meteotsunami science: editorial

2021

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“…Matoza et al ( 2022 ) detected ionospheric TEC perturbations caused by traveling gravity waves (GWs) produced by the Tonga volcanic eruption, and Kubota et al ( 2022 ), Omira et al ( 2022 ), and Yamada et al ( 2022 ) showed that these fast-moving GWs generated a meteotsunami wave with almost constant height of about 1.1 m up to 10,000 km away from the eruption site. Solovieva et al ( 2021 ) reported the meteotsunami signatures in the earth’s ionosphere caused by a high-altitude dynamic system sweeping through the Mediterranean and Black Sea in June 2014. They captured the event in 1 min amplitude perturbations of VLF/LF signals from the ground-based International Network for Frontier Research on Earthquake Precursors (INFREP) network.…”

Section: Introductionmentioning

confidence: 99%

Prospects for meteotsunami detection in earth’s atmosphere using GNSS observations

et al. 2023

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We study, for the first time, the physical coupling and detectability of meteotsunamis in the earth’s atmosphere. We study the June 13, 2013 event off the US East Coast using Global Navigation Satellite System (GNSS) radio occultation (RO) measurements, Sounding of the Atmosphere using Broadband Emission Radiometry (SABER) temperatures, and ground-based GNSS ionospheric total electron content (TEC) observations. Hypothesizing that meteotsunamis also generate gravity waves (GWs), similar to tsunamigenic earthquakes, we use linear GW theory to trace their dynamic coupling in the atmosphere by comparing theory with observations. We find that RO data exhibit distinct stratospheric GW activity at near-field that is captured by SABER data in the mesosphere with increased vertical wavelength. Ground-based GNSS-TEC data also detect a far-field ionospheric response 9 h later, as expected by GW theory. We conclude that RO measurements could increase understanding of meteotsunamis and how they couple with the earth’s atmosphere, augmenting ground-based GNSS TEC observations.

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Exploring the Mediterranean tsunami research landscape: scientometric insights and future prospects

Laksono,

Mishra,

Mulyana

et al. 2024

Geoenviron Disasters

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Background The Mediterranean Sea is a region characterized by high seismic activity, with at least 200 tsunami events recorded from the fourth century to the present twenty-first century. Numerous studies have been conducted to understand past tsunami events, earthquake–tsunami generation, tsunami recurrence periods, tsunami vulnerability zones, and tsunami hazard mitigation strategies. Therefore, gaining insights into future trends and opportunities in Mediterranean Sea tsunami research is crucial for significantly contributing to all relevant aspects. This study aims to assess such trends and opportunities through a scientometric analysis of publications indexed by Web of Science from 2000 to 2023. Results Based on a selection of 329 publications, including research articles, review articles, book chapters, and conference papers, published between 2000 and 2023, Italy has the highest number of publications and citations in this field. The number of publications has increased significantly, especially after the 2004 Indian Ocean, 2011 Tohoku, and 2018 Palu tsunamis. According to the keyword analysis, the terms “tsunami”, “earthquake”, “hazard”, “wave”, “Mediterranean”, “coast”, and “tectonic” were the most frequently used in these publications. Research themes consist of four classifications: motor themes, such as seismic hazard; specific but well-developed themes, like tsunamiite; emerging or disappearing themes, for example, climate change; and general or basic themes, such as equations and megaturbidite. The number of publications related to the motor theme classification continued to grow throughout 2000–2023. Topics from 2011–2023 are more complex compared to 2000–2010, characterized by the emergence of new keywords such as evacuation planning, risk reduction, risk mitigation, building vulnerability, coastal vulnerability, climate change, probabilistic tsunami hazard assessment (PTVA-3 and PTVA-4). However, topics that were popular in the 2000–2010 period (e.g., paleotsunami deposits, earthquake, and tsunami propagation analysis) also increased in 2011–2023. Conclusions Research topics with high centrality and density such as seismic hazard will continue to develop and prospect. The cluster network of this topic includes seismoturbidites, sedimentary features, tsunami modeling, active faults, catalog, and historical earthquakes.

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The lower ionosphere disturbances observed during the chain of the meteotsunamis in the Mediterranean Sea in June 2014

Cited by 3 publications

References 33 publications

Special issue on the global perspective on meteotsunami science: editorial

Special issue on the global perspective on meteotsunami science: editorial

Prospects for meteotsunami detection in earth’s atmosphere using GNSS observations

Exploring the Mediterranean tsunami research landscape: scientometric insights and future prospects

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