Simulation of Storm Surge in Seto Inland Sea with Wind Field Estimated by Empirical Typhoon Model and Mesoscale Model

The New European Wind Atlas (https://map.neweuropeanwindatlas.eu) is developed based on the simulated wind field over Europe from a mesoscale model coupled to a microscale component through a statistical downscaling approach. The simulation that provides mesoscale inputs within the model chain has been decided upon a careful sensitivity analysis of potential model configurations. In order to accomplish model resolutions of 3 km over Europe, the broader European domain is partitioned into a set of 10 partially overlapping tiles. The wind field is simulated with the WRF model over these tiles and finally blended into a single domain. The wind outputs from a reference simulation is evaluated on the basis of its comparison with an observational database specifically compiled and quality controlled for the purpose of validating the wind atlas over the complete European domain. The observational database includes surface wind observations at ca. 4000 sites as well as 16 masts datasets. The observational dataset of surface wind (WISED) is informative about the spatial and temporal variability of the wind climatology, punctuated with singular masts that provide information of wind velocities at height. The validation of the mesoscale simulation aims at investigating the ability of the high-resolution simulation to reproduce the observed intra-annual variability of daily wind within the entire domain.Observed and simulated winds are higher at the British, North Sea and Baltic shores and lowlands. Correlations are typically over 0.8. Surface wind variability tends to be overestimated in the northern coasts and underestimated elsewhere and inland. Mast wind variability tends to be overestimated except for some southern sites. Seasonal differences seem minor in these respects. Biases and RMSE can help identifying if systematic errors in specific tiles take place.Therefore, performing model simulations of a high horizontal resolution over the broader European domain is possible. We can learn about the variability of surface and height wind both from observations and model simulations. Model observations are not perfect, but observations also present uncertainties. Good quality wind data, both at the surface and in masts are a requisite for robust evaluation of models. European wide features of wind variability can be recognized both in observations and simulations.

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Wind Field Prediction in Coastal Zone: Operational Mesoscale Model Evaluation and Simulations with Increased Horizontal Resolution

Journal of Coastal Research ◽

10.2112/05-0450.1 ◽

2007 ◽

Vol 2007 (233) ◽

pp. 721 ◽

Cited By ~ 4

Keyword(s):

Coastal Zone ◽

Model Evaluation ◽

Wind Field ◽

Mesoscale Model ◽

Horizontal Resolution

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Investigation typhoon induced storm surge and high wave in Vietnam using coupled Delft3d-FLOW – WAVE models combined with weather research forecast (WRF) output wind field

Science & Technology Development Journal - Engineering and Technology ◽

10.32508/stdjet.v4i1.774 ◽

2021 ◽

Vol 4 (1) ◽

pp. first

Author(s):

LE TUAN ANH ◽

DANG HOANG ANH ◽

MAI THI YEN LINH ◽

NGUYEN DANH THAO

Keyword(s):

Storm Surge ◽

Wave Height ◽

Wind Field ◽

Mekong Delta ◽

Coastal Areas ◽

Coupled Models ◽

High Wave ◽

Wave Models ◽

The Impact ◽

Weather Research

Introduction: Typhoon-induced disasters including storm surge and high wave are obvious threats to coastal areas in Vietnam. Thus, many researchers have paid their attention to this issue. The approaching methods are varied, including statistical methods and also numerical methods. This study suggests the coupled models Delft3D-FLOW and WAVE, using the meteorological output data from the Weather Research Forecast (WRF) for investigating the typhoon induced disasters in the coastal areas in Viet Nam. Method: WRF is run in multiple domains with different grid resolutions simultaneously and there is an interaction between them to reproduce the wind field during the typhoon events. Delft3D-FLOW is coupled with Delft3D-WAVE (SWAN) through a dynamic interaction, in which the FLOW module considers the received radiation stresses calculated by the wave module. On the other side, the updated water depth including the contribution of the storm surge will be used by the WAVE module. Both Delft3D-FLOW and Delft3D-WAVE models used wind fields from the WRF simulation output as the meteorological input data. The total surge level includes the storm surge, wave-induced setup and the tidal level. Results: The case of extreme weather event Typhoon Kaemi (2000) was used to validate the wind field and the wave height. The calibration process of the the storm surge level was based on the observed data during Typhoon Xangsane (2006), while Typhoon Durian (2006) were used to validate the coupled models. The comparisons show the good agreement between simulated results and observed data, especially in terms of the peak water level and highest significant wave height, which mainly governed by the typhoon wind field. The simulated results reveal that the surge height durring Typhoon Durrian period along its path was ranged from 1.2 to more than 1.4m, which can be considered to pose the greatest risk to low-lying coastal areas of the Mekong Delta. Conclusion: The suggested coupled models can be used to investigate the impact of typhoon induced disasters.

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GENERATION AND PROPAGATION FORECAST OF STORM SURGE IN THE SETO INLAND SEA

Coastal Engineering 2006 ◽

10.1142/9789812709554_0115 ◽

2007 ◽

Author(s):

Katsuaki Komai ◽

Tadashi Hibino ◽

Tatsuo Ohgama

Keyword(s):

Storm Surge ◽

Seto Inland Sea ◽

The Seto Inland Sea

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Study on Storm Surge Using Parametric Model with Geographical Characteristics

Water ◽

10.3390/w12082251 ◽

2020 ◽

Vol 12 (8) ◽

pp. 2251

Author(s):

Yeon-joong Kim ◽

Tea-woo Kim ◽

Jong-sung Yoon

Keyword(s):

Storm Surge ◽

Wind Field ◽

Global Climate ◽

Grid Point ◽

Storm Surges ◽

Parametric Model ◽

Hazard Map ◽

Proposed Model ◽

Pass Through ◽

Geographical Characteristics

The coastal area of Japan has been damaged yearly by storm surges and flooding disasters in the past, including those associated with typhoons. In addition, the scale of damage is increasing rapidly due to the changing global climate and environment. As disasters due to storm surges become increasingly unpredictable, more measures should be taken to prevent serious damage and casualties. The Japanese government published a hazard map manual in 2015 and obligates the creation of a hazard map based on a parametric model as a measure to reduce high-scale storm surges. Parametric model (typhoon model) accounting for the topographical influences of the surroundings is essential for calculating the wind field of a typhoon. In particular, it is necessary to calculate the wind field using a parametric model in order to simulate a virtual typhoon (the largest typhoon) and to improve the reproducibility. Therefore, in this study, the aim was to establish a hazard map by assuming storm surges of the largest scale and to propose a parametric model that considers the changing shape of typhoons due to topography. The main objectives of this study were to analyze the characteristics of typhoons due to pass through Japan, to develop a parametric model using a combination of Holland’s and Myers’s models that is appropriate for the largest scale of typhoon, and to analyze the parameters of Holland’s model using grid point values (GPVs). Finally, we aimed to propose a method that considers the changing shape of typhoons due to topography. The modeling outcomes of tide levels and storm surge heights show that the reproduced results obtained by the analysis method proposed in this study are more accurate than those obtained using GPVs. In addition, the reproducibility of the proposed model was evaluated showing the high and excellent reproducibility of storm surge height according to the geographic characteristics.

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Numerical Study of Storm Surge Hindcast Simulations in the Seto Inland Sea by Surge-Wave-Tide Coupled Model and Mesoscale Atmospheric Model WRF

PROCEEDINGS OF COASTAL ENGINEERING JSCE ◽

10.2208/proce1989.55.331 ◽

2008 ◽

Vol 55 ◽

pp. 331-335 ◽

Cited By ~ 2

Author(s):

Tomohiro YASUDA ◽

Tatsuya YAMAGUCHI ◽

Soo Youl KIM ◽

Hiroaki SHIMADA ◽

Taisuke ISHIGAKI ◽

...

Keyword(s):

Storm Surge ◽

Numerical Study ◽

Coupled Model ◽

Atmospheric Model ◽

Seto Inland Sea ◽

The Seto Inland Sea ◽

Mesoscale Atmospheric Model

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The Effects of Complex Terrain on Severe Landfalling Tropical Cyclone Larry (2006) over Northeast Australia

Monthly Weather Review ◽

10.1175/2008mwr2429.1 ◽

2008 ◽

Vol 136 (11) ◽

pp. 4334-4354 ◽

Cited By ~ 17

Author(s):

Hamish A. Ramsay ◽

Lance M. Leslie

Keyword(s):

Boundary Layer ◽

Tropical Cyclone ◽

Land Surface ◽

Wind Field ◽

Complex Terrain ◽

Mesoscale Model ◽

Surface Wind ◽

Small Scale ◽

Precipitation Pattern ◽

Intense Storm

Abstract The interaction between complex terrain and a landfalling tropical cyclone (TC) over northeastern Australia is investigated using the fifth-generation Pennsylvania State University–National Center for Atmospheric Research (PSU–NCAR) Mesoscale Model (MM5). Severe TC Larry (in March 2006) made landfall over an area of steep coastal orography and caused extensive damage. The damage pattern suggested that the mountainous terrain had a large influence on the TC wind field, with highly variable damage across relatively small distances. The major aims in this study were to reproduce the observed features of TC Larry, including track, intensity, speed of movement, size, decay rate, and the three-dimensional wind field using realistic high-resolution terrain data and a nested grid with a horizontal spacing of 1 km for the finest domain (referred to as CTRL), and to assess how the above parameters change when the terrain height is set to zero (NOTOPOG). The TC track for CTRL, including the timing and location of landfall, was in close agreement with observation, with the model eye overlapping the location of the observed eye at landfall. Setting the terrain height to zero resulted in a more southerly track and a more intense storm at landfall. The orography in CTRL had a large impact on the TC’s 3D wind field, particularly in the boundary layer where locally very high wind speeds, up to 68 m s−1, coincided with topographic slopes and ridges. The orography also affected precipitation, with localized maxima in elevated regions matching observed rainfall rates. In contrast, the precipitation pattern for the NOTOPOG TC was more symmetric and rainfall totals decreased rapidly with distance from the storm’s center. Parameterized maximum surface wind gusts were located beneath strong boundary layer jets. Finally, small-scale banding features were evident in the surface wind field over land for the NOTOPOG TC, owing to the interaction between the TC boundary layer flow and land surface characteristics.

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