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Weather radar and ancillary observations of the convective system causing the northern Persian Gulf meteotsunami on 19 March 2017

Author

Listed:
  • Mohammad Hossein Kazeminezhad

    (Iranian National Institute for Oceanography and Atmospheric Science)

  • Ivica Vilibić

    (Institute of Oceanography and Fisheries)

  • Cléa Denamiel

    (Institute of Oceanography and Fisheries)

  • Parvin Ghafarian

    (Iranian National Institute for Oceanography and Atmospheric Science)

  • Samaneh Negah

    (I.R. Iran Meteorological Organization, Gilan Meteorology Office)

Abstract

This study documents the atmospheric system driving the observed meteotsunami waves that hit the northern Persian Gulf on 19 March 2017 during high tide. This destructive meteotsunami event resulted in coastal inundations that reached several hundred metres inland along the 100-km coastline between the cities of Dayyer and Asaluyeh and caused the death or injury of 27 persons. Based on previously published research, eyewitness reports, oceanic and atmospheric observations, including synoptic station and weather radar data, and available reanalysis ERA5 products, this study provides new insights into destructive events, particularly mesoscale atmospheric systems conjoined with observed meteotsunami waves. Precipitation intensity, maximum reflectivity and echo top height images provided by the weather radar covering the affected area and the area over which the meteotsunamigenic disturbance travelled revealed that a strong convective system that encompassed the mid- and upper troposphere entered the northern Persian Gulf approximately 4 h before the event and moved eastward. Two hours before reaching the affected coastline, this convective system was reshaped to an elongated and narrow squall line varying between 70 and 130 km in length with a width of less than 10 km and travelled at an average speed of approximately 24 m/s over the sea. The peak maximum reflectivity of the squall line always surpassed 40 dBZ, while it increased to 60 dBZ near the Dayyer area. As such, intense atmospheric disturbances are known to be associated with sharp air pressure increases, and these disturbances were found to resonantly pump energy to the ocean through Proudman resonance for over 12 or more disturbance wavelengths (i.e. up to 120 km in this study). A half-metre meteotsunami wave was presumably created in the open sea and then amplified while travelling towards the shore where it broke as a meteotsunami bore and inundated the coastal areas. Further research on the physical mechanisms driving the interactions between meteotsunamigenic disturbances and ocean responses, the recurrence of such events and meteotsunami hazard assessments along the affected coastline is envisaged.

Suggested Citation

  • Mohammad Hossein Kazeminezhad & Ivica Vilibić & Cléa Denamiel & Parvin Ghafarian & Samaneh Negah, 2021. "Weather radar and ancillary observations of the convective system causing the northern Persian Gulf meteotsunami on 19 March 2017," Natural Hazards: Journal of the International Society for the Prevention and Mitigation of Natural Hazards, Springer;International Society for the Prevention and Mitigation of Natural Hazards, vol. 106(2), pages 1747-1769, March.
    • Handle: RePEc:spr:nathaz:v:106:y:2021:i:2:d:10.1007_s11069-020-04208-0
    DOI: 10.1007/s11069-020-04208-0
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    References listed on IDEAS

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    1. Amir Salaree & Reza Mansouri & Emile A. Okal, 2018. "The intriguing tsunami of 19 March 2017 at Bandar Dayyer, Iran: field survey and simulations," Natural Hazards: Journal of the International Society for the Prevention and Mitigation of Natural Hazards, Springer;International Society for the Prevention and Mitigation of Natural Hazards, vol. 90(3), pages 1277-1307, February.
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