A coupled hydrodynamic modeling system for PHAILIN cyclone in the Bay of Bengal

A coupled hydrodynamic modeling system for PHAILIN cyclone in the Bay of Bengal

East coast of India is characterized by low to medium topography and an extensive network of major estuaries, bays, mangrove creeks, rivers and tidal inlets that permit inland flooding during tropical cyclones. A coupled wave+surge hydrodynamic modeling system (ADCIRC+SWAN) is implemented to simulat...

Full description

Saved in:
Bibliographic Details
Published in:Coastal engineering (Amsterdam) Vol. 93; pp. 71 - 81
Main Authors: Murty, P.L.N., Sandhya, K.G., Bhaskaran, Prasad K., Jose, Felix, Gayathri, R., Balakrishnan Nair, T.M., Srinivasa Kumar, T., Shenoi, S.S.C.
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-11-2014
Elsevier
Subjects:
Coastal environments
Coastal oceanography, estuaries. Regional oceanography
Computer simulation
Coupled model
Cyclone Phailin
Cyclones
Earth, ocean, space
Exact sciences and technology
External geophysics
Hydrodynamics
Joining
Mathematical models
Physics of the oceans
Storm surge
Storm surges
Surface waves, tides and sea level. Seiches
Surges
Wave setup
Indian Ocean
Asia
Bay of Bengal
India
ISW, Bangladesh, Bengal Bay
ISW, North Indian Ocean
Coupled model
Storm surge
Wave setup
Cyclone Phailin
submergence
digital simulation
Surface gravity wave
coastal zone
Severe weather
Sea surge
Tropical cyclone
Risk assessment
Hydrodynamic model
Wind wave
Risk management
ocean waves
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:East coast of India is characterized by low to medium topography and an extensive network of major estuaries, bays, mangrove creeks, rivers and tidal inlets that permit inland flooding during tropical cyclones. A coupled wave+surge hydrodynamic modeling system (ADCIRC+SWAN) is implemented to simulate storm surge, still water level elevation and wave induced setup associated with ‘Phailin’, a very severe cyclonic storm that made landfall in the Odisha State, east coast of India, during October, 2013. The coupled model provides a realistic description on the dynamic interaction of tides, wind, waves and currents, which is critical for operational needs. The study assesses the role of wave-induced setup on the net water level elevation using time varying wave radiation stress that is dynamically updated in the coupled model run. Numerical experiments are carried out for both storm surge alone and coupled mode versions. Dependent upon complex bathymetry and coastal geometry, inclusion of wave-induced setup in coupled runs results in an additional 23–36% increase of peak surge relative to an uncoupled, surge-tide simulation. The significant wave height from coupled model also shows an excellent match with observed wave heights from a wave-rider buoy located off the Odisha coast. The comparison of surge residuals between model and observation also exhibits a good match. The study highlights the importance of having a coupled wave-hydrodynamic model for operational needs in the north Indian Ocean. •Numerical Modeling of Peak Storm Surge for Phailin Cyclone•Computed Total Water Level Elevation along coastal Odisha from Phailin Cyclone•Validation of model computation with field based measurements•Validation of near-shore water level variations and surge residuals with field data
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0378-3839
1872-7379
DOI:10.1016/j.coastaleng.2014.08.006