Wave set-up

Notes

Wave transformation in shallow water generates changes in the mean water level, called set-up for an upward change and set-down for a downward change. The changes in mean sea level are related to the so-called "radiation stress". The radiation stress represents an effective momentum transfer from wave motion to steady motion that takes place when the wave amplitude changes along the direction of propagation. Wave set-down [math]\eta_d[/math] occurs in the shoaling zone where the wave amplitude increases; wave wet-up [math]\eta_u[/math] occurs in the surf zone where the wave amplitude decreases. Analytical expressions of the wave set-down at the breakpoint and the wave set-up at the shoreline can be derived for a monochromatic wave, see Shallow-water wave theory:

[math]\eta_d \approx -\frac{\gamma}{16} H_b , \qquad \eta_u \approx \eta_d +\frac{3 \gamma}{8} H_b \approx \frac{5 \gamma}{16} H_b,[/math]

where [math]\gamma = H_b/h_b[/math] is the breaker index (typical values in the range 0.5-1), [math]H_b[/math] is the wave height at the breakpoint and [math]h_b[/math] the depth at the breakpoint.

Assumptions are:

• a constant seabed slope [math]\beta[/math], i.e. depth [math]h(x) = \beta x[/math];
• shallow water, [math]2kh_b \lt 1[/math] ([math]k[/math] is the wave number);
• depth-limited wave amplitude [math]H/h=\gamma[/math] throughout the surf zone.

Observations at different field locations suggest that the wave set-up depends on the beach slope [math]\beta[/math] following the empirical relationship^[1]

[math]\eta_u \approx (0.02 + 0.003 / \beta) H_b .[/math]

Related articles

Shallow-water wave theory

Wave run-up

References