Estimation of mean and extreme waves in the East China Seas

•The WAMC4 model is used to hindcast the long-term wave climate (1979–2013) in the whole East China Sea.•The Pearson-III distribution method is applied to calculate the extreme waves based on the long-term hindcast wave data.•The results based on the NCEP and ECMWF reanalysis wind data are comparati...

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Bibliographic Details
Published in:Applied ocean research 2016-03, Vol.56, p.35-47
Main Authors: Li, Jiangxia, Chen, Yongping, Pan, Shunqi, Pan, Yi, Fang, Jiayu, Sowa, Derrick M.A.
Format: Article
Language:English
Subjects:
East China Seas
ECMWF reanalysis wind data
Marine
NCEP reanalysis wind data
Numerical simulation
WAMC4 model
Wave statistics
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Summary:•The WAMC4 model is used to hindcast the long-term wave climate (1979–2013) in the whole East China Sea.•The Pearson-III distribution method is applied to calculate the extreme waves based on the long-term hindcast wave data.•The results based on the NCEP and ECMWF reanalysis wind data are comparatively studied.•The spatial and seasonal variations of extreme waves in the East China Sea are discussed.•The modeling results are verified by using the long-term measurement data at 8 field observation stations. Accurately estimating the mean and extreme wave statistics and better understanding their directional and seasonal variations are of great importance in the planning and designing of ocean and coastal engineering works. Due to the lack of long-term wave measurement data, the analysis of extreme waves is often based on the numerical wave hind-casting results. In this study, the wave climate in the East China Seas (including the Bohai Sea, the Yellow Sea and the East China Sea) for the past 35 years (1979–2013) is hind-casted using a third generation wave model – WAMC4 (Cycle 4 version of WAM model). Two sets of reanalysis wind data from NCEP (National Centers for Environmental Prediction, USA) and ECMWF (European Centre for Medium-range Weather Forecasts) are used to drive the wave model to generate the long-term wave climate. The hind-casted waves are then analysed to study the mean and extreme wave statistics in the study area. The results show that the mean wave heights decrease from south to north and from sea to land in general. The extreme wave heights with return periods of 50 and 100 years in the summer and autumn seasons are significantly higher than those in the other two seasons, mainly due to the effect of typhoon events. The mean wave heights in the winter season have the highest values, mainly due to the effect of winter monsoon winds. The comparison of extreme wave statistics from both wind fields with the field measurements at several nearshore wave observation stations shows that the extreme waves generated by the ECMWF winds are better than those generated by the NCEP winds. The comparison also shows the extreme waves in deep waters are better reproduced than those in shallow waters, which is partly attributed to the limitations of the wave model used. The results presented in this paper provide useful insight into the wave climate in the area of the East China Seas, as well as the effect of wind data resolution on the simulation of long-
ISSN:0141-1187
1879-1549
DOI:10.1016/j.apor.2016.01.005