Bathymetry and topography changes o

Bathymetry and topography changes often occur as a result of storms and erosion, and also vary geographically. These geographic differences affect Base Flood Elevations (BFEs) and resultant coastal responses and flood hazard areas. For example, the Pacific coast is characterized by steep bathymetry and a narrow coastal shelf, and flooding is predominantly caused by large waves rushing up the shore (wave runup - the maximum extent of high-velocity uprush of individual waves above the average water level). In contrast, the Gulf and Atlantic coasts are characterized by wide, shallow coastal shelves, and flooding is dominated by storm surge and breaking waves. Water surface elevations at the shoreline are a combination of the average water level determined by wind setup (due to the direct action of wind stresses at the air-sea interface) and wave setup (due to breaking waves, see below), and a fluctuating water level caused by wave runup.

Hurricane winds generate waves in the ocean. As these waves propagate into shallow water, wave heights increase due to a process called “shoaling”. As the wave heights increase, the waves eventually break and impart their momentum to the water, causing onshore flow near the surface and offshore flow or “undertow” near the bottom, and an overall elevation in water level at the coast (“wave setup” – the rise in the water surface caused by breaking waves, and “wave runup” - the rush of wave water up a slope or structure).

Storm surge and coastal flooding have both vertical and horizontal dimensions. Storm surge can reach heights of more than 12 m (40 ft) near the center of a Category 5 hurricane, and fan out across several hundred miles of coastline, gradually diminishing away from the hurricane’s center. Coastal flooding can reach far inland, tens of miles from the shoreline. While the peak surge often occurs at the landfall of a storm along an open coastline, large surge has been found to occur hours before hurricane landfall as a “fore-runner” (e.g., during Hurricane Ike along the Texas coast in 2008) and/or after hurricane landfall as a “post-runner” (e.g, during Hurricane Wilma along SW Florida coast in 2005). These “fore-runner” and “post-runner” surges can actually cause unexpected coastal flooding, damage property, and endanger lives.
Local topographic features such as buildings, levees, wetlands, sand dunes, and barrier islands reduce storm surge, wave forces, and coastal flooding. At the same time, these topographic features may be reshaped or even removed during a severe storm (see Ecosystem Perspective: What can a hurricane do to the environment?. After the landfall and passage of Hurricane Katrina (2005), levees in New Orleans breached and catastrophic flooding followed shortly afterwards. Storm surge, wave, and coastal flooding are also complicated by the presence of estuaries. For example, a long and narrow estuary can significantly increase the storm surge due to a “funneling” effect. Storm surge can travel from the mouth to the head of an estuary, causing a delayed peak surge in that location when winds have already subsided. Diverse geographic variations in local bathymetry and topography result in very different responses of coastal regions to hurricanes. Hence, it is difficult to assign a uniform storm surge value for a hurricane of any given intensity. Due to this, the Saffir-Simpson Wind Scale no longer associates storm surge value to hurricane of any category.

b. Mechanics
At least five processes can be involved in altering tide levels during storms:
- The pressure effect,.
- The direct wind effect.
- The effect of the Earth's rotation.
- The effect of waves.
- The rainfall effect.

 The pressure effects: of a tropical cyclone will cause the water level in the open ocean to rise in regions of low atmospheric pressure and fall in regions of high atmospheric pressure. The rising water level will counteract the low atmospheric pressure such that the total pressure at some plane beneath the water surface remains constant. This effect is estimated at a 10 mm (0.39 in) increase in sea level for every millibar (hPa) drop in atmospheric pressure.

 The direct wind effect : strong surface winds cause surface currents at a 45 degree angle to the wind direction, by an effect known as the Ekman Spiral. Wind stresses cause a phenomenon referred to as "wind set-up", which is the tendency for water levels to increase at the downwind shore, and to decrease at the upwind shore. Intuitively, this is caused by the storm simply blowing the water towards one side of the basin in the direction of its winds. Because the Ekman Spiral effects spread vertically through the water, the effect is inversely proportional to depth. The pressure effect and the wind set-up on an open coast will be driven into bays in the same way as the astronomical tide.

 The Earth's rotation causes the Coriolis effect, which bends currents to the right in the Northern Hemisphere and to the left