Abstract
A two-dimensional coupled tide-surge model was used to investigate the effects of tide-surge interactions on storm surges along the coast of the Bohai Sea, Yellow Sea, and East China Sea. In order to estimate the impacts of tide-surge interactions on storm surge elevations, Typhoon 7203 was assumed to arrive at 12 different times, with all other conditions remaining constant. This allowed simulation of tide and total water levels for 12 separate cases. Numerical simulation results for Yingkou, Huludao, Shijiusuo, and Lianyungang tidal stations were analyzed. Model results showed wide variations in storm surge elevations across the 12 cases. The largest difference between 12 extreme storm surge elevation values was of up to 58 cm and occurred at Yingkou tidal station. The results indicate that the effects of tide-surge interactions on storm surge elevations are very significant. It is therefore essential that these are taken into account when predicting storm surge elevations.
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References
Antony C, Unnikrishnan A S. 2013. Observed characteristics of tide-surge interaction along the east coast of India and the head of Bay of Bengal. Estuar Coast Shelf Sci, 131: 6–11
Chen W B, Liu W C, Hsu M H. 2012. Predicting typhoon-induced storm surge tide with a two-dimensional hydrodynamic model and artificial neural network model. Nat Hazards Earth Syst Sci, 12: 3799–3809
Fan L L, Liu M M, Chen H B, Lv X Q. 2011. Numerical study on the spatially varying drag coefficient in simulation of storm surges employing the adjoint method. Chin J Oceanol Limnol, 29: 702–717
Fang G H, Kwok Y K, Yu K J, Zhu Y H. 1999. Numerical simulation of principal tidal constituents in the South China Sea, Gulf of Tonkin and Gulf of Thailand. Cont Shelf Res, 19: 845–869
Haigh I D, Wijeratne E M S, MacPherson L R, Pattiaratchi C B, Mason M S, Crompton R P, George S. 2014. Estimating present day extreme water level exceedance probabilities around the coastline of Australia: Tides, extra-tropical storm surges and mean sea level. Clim Dynam, 42: 121–138
Jelesnianski C P. 1965. A numerical calculation of storm tides induced by a tropical storm impinging on a continental shelf. Mon Weather Rev, 93: 343–358
Kong X P. 2014. A numerical study on the impact of tidal waves on the storm surge in the north of Liaodong Bay. Acta Oceanol Sin, 33: 35–41
Li Y N, Peng S Q, Yan J, Xie L. 2013. On improving storm surge forecasting using an adjoint optimal technique. Ocean Model, 72: 185–197
Lin N, Emanuel K, Oppenheimer M, Vanmarcke E. 2012. Physically based assessment of hurricane surge threat under climate change. Nat Clim Change, 2: 462–467
Lu X Q, Zhang J C. 2006. Numerical study on spatially varying bottom friction coefficient of a 2D tidal model with adjoint method. Cont Shelf Res, 26: 1905–1923
Maspataud A, Ruz M, Vanhee S. 2013. Potential impacts of extreme storm surges on a low-lying densely populated coastline: the case of Dunkirk area, Northern France. Nat Hazards, 66: 1327–1343
Olbert A I, Nash S, Cunnane C, Hartnett M. 2013. Tide-surge interactions and their effects on total sea levels in Irish coastal waters. Ocean Dynam, 63: 599–614
Park Y H, Suh K D. 2012. Variations of storm surge caused by shallow water depths and extreme tidal ranges. Ocean Eng, 55: 44–51
Peng S Q, Xie L. 2006. Effect of determining initial conditions by fourdimensional variational data assimilation on storm surge forecasting. Ocean Model, 14: 1–18
Peng S Q, Xie L, Pietrafesa L J. 2007. Correcting the errors in the initial conditions and wind stress in storm surge simulation using an adjoint optimal technique. Ocean Model, 18: 175–193
Pousa J L, D’ Onofrio E E, Fiore M M E, Kruse E E. 2013. Environmental impacts and simultaneity of positive and negative storm surges on the coast of the Province of Buenos Aires, Argentina. Environ Earth Sci, 68: 2325–2335
Tang J, Shi J, Li X Q, Deng B, Jin M M. 2013. Numerical simulation of typhoon waves with typhoon wind model (in Chinese). Trans Oceanol Limnol, 2: 24–30
Sinha P C, Jain I, Bhardwaj N, Rao A D, Dube S K. 2008. Numerical modeling of tide-surge interaction along Orissa coast of India. Nat Hazards, 45: 413–427
Wen B, Wang P, Wan L, Zhang F R. 2008. Experiments on the simulation of typhoon waves in the inshore area of China Sea (in Chinese). Marine Sci Bull, 27: 1–6
Wu J. 1982. Wind-stress coefficients over sea surface from breeze to hurricane. J Geophys Res, 87: 9704–9706
Yang G B, Lu L G, Yuan Y L, Jiang Y, Liu Z W, Yang C M, Liu H M, Chen Z. 2015. Observations and analysis of environment and acoustic field changed by the passage of typhoon Damrey in the Yellow Sea in 2012. Sci China Earth Sci, 58: 2260–2270
Yang Z Q, Wang T P, Leung R, Hibbard K, Janetos T, Kraucunas I, Rice J, Preston B, Wilbanks T. 2014. A modeling study of coastal inundation induced by storm surge, sea-level rise, and subsidence in the Gulf of Mexico. Nat Hazards, 71: 1771–1794
Yin B S, Xu Z H, Huang Y, Lin X. 2009. Simulating a typhoon storm surge in the East Sea of China using a coupled model. Prog Nat Sci, 19: 65–71
You S H, Seo J W. 2009. Storm surge prediction using an artificial neural network model and cluster analysis. Nat Hazards, 51: 97–114
Zhang S W, Xie L L, Zhao H, Hou Y J. 2014. Tropical storm-forced near-inertial energy dissipation in the southeast continental shelf region of Hainan Island. Sci China Earth Sci, 57: 1879–1884
Zhang W Z, Hong H S, Shang S P, Chen D W, Chai F. 2007. A two-way nested coupled tide-surge model for the Taiwan Strait. Cont Shelf Res, 27: 1548–1567
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Xu, J., Zhang, Y., Cao, A. et al. Effects of tide-surge interactions on storm surges along the coast of the Bohai Sea, Yellow Sea, and East China Sea. Sci. China Earth Sci. 59, 1308–1316 (2016). https://doi.org/10.1007/s11430-015-5251-y
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DOI: https://doi.org/10.1007/s11430-015-5251-y