Difference between revisions of "Wave set-up"

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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.  
 
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 [[Shallow-water wave theory#Radiation Stress (Momentum Flux)|radiation stress]]. The radiation stress is defined as the excess flow of momentum due to wave orbital motions. Gradients in the radiation stress induce 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]]:
+
The changes in mean sea level are related to the so-called [[Shallow-water wave theory#Radiation Stress (Momentum Flux)|radiation stress]]. The radiation stress is defined as the excess flow of momentum due to wave orbital motions. Gradients in the radiation stress induce 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#Wave set-down and set-up]]:
  
 
<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, \qquad (1)</math>
 
<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, \qquad (1)</math>

Revision as of 21:19, 29 June 2022

Definition of Wave set-up:
Elevation of the mean water level at the shoreline due to wave breaking in the surf zone.
This is the common definition for Wave set-up, other definitions can be discussed in the article


Notes

Fig. 1. Definition sketch wave set-down, wave set-up and wave run-up.

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 is defined as the excess flow of momentum due to wave orbital motions. Gradients in the radiation stress induce 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#Wave set-down and set-up:

[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, \qquad (1)[/math]

where [math]\gamma = H_b/h_b[/math] is the breaker index (values in the range 0.5-1.2), [math]H_b[/math] is the wave height at the breakpoint and [math]h_b[/math] the depth at the breakpoint (see Fig. 1). Values compatible with Eq. (1) were found in several field measurements. [1][2]

Besides monochromatic waves and applicability of shallow-water wave theory, other assumptions are:

  • a constant shoreface seabed slope [math]m = \tan\beta[/math], i.e. depth [math]h(x) = m \, x[/math];
  • shallow water, [math]2kh_b \lt 1[/math] ([math]k=2 \pi / L[/math] is the wave number);
  • depth-limited wave amplitude [math]H/h=\gamma \;[/math] throughout the surf zone (saturated wave breaking);
  • wave skewness and asymmetry can be ignored;
  • roller energy of breaking waves can be ignored;
  • no momentum loss through dissipation at the seabed.

The numerous assumptions underlying Eq. (1) strongly limit its practical usefulness. Numerical modeling shows that neglecting momentum dissipation at the seabed (mainly momentum dissipation related to the undertow current) yields an underprediction of the wave set-up[3]

In practice, empirical formulas derived from field and laboratory measurements are often used for determining the wave set-up. Many different formulas can be found in the literature[4]. Most of these formulas relate the wave set-up to the offshore significant wave height [math]H[/math], the deep-water wave length [math]L = g T^2 \ /2 \pi[/math] and the average surf zone bed slope [math]m=\tan \beta[/math]. A popular formula is[5][6][7]

[math]\eta_u = C \, H \, \xi = C \, m \, \sqrt{H\, L}, \qquad (2)[/math]

where [math]\xi=m/ \sqrt{H/L}[/math] is the surf similarity parameter . The constant [math]C[/math] can take values in the range 0.15 – 0.4.

Other empirical formulas differ from Eq. (2) especially regarding the dependence on the surf zone slope [math]m[/math], either by no dependence on [math]m[/math][8] or by an inverse relationship with [math]m[/math].[2][9]

The great diversity of empirical formulas and associated values for the wave set-up illustrates the limitations inherent to simple parameterizations of the shoreface. The shoreface bathymetry is highly variable and differs greatly among coasts, even among nearby locations. Complex bathymetries are ubiquitous due to the presence of nearshore sandbars and other rhythmic shoreline features. Reliable estimates of the wave-set-up require in-situ observations or detailed numerical models.


Related articles

Shallow-water wave theory
Wave run-up
Breaker index


References

  1. Guza, R.T. and Thornton, E.B. 1981. Wave set-up on a natural beach. J. Geophys. Res. 86: 4133–4137
  2. 2.0 2.1 Raubenheimer, B., Guza, R.T.and Elgar, S. 2001. Field observations of wave-driven setdown and setup. J. Geophys. Res. 106: 4629–4638 Cite error: Invalid <ref> tag; name "R1" defined multiple times with different content
  3. Apotsos, A., Raubenheimer, B., Elgar, S., Guza, R.T. and Smith, J.A. 2007. Effects of wave rollers and bottom stress on wave setup. J. Geophysical Research 112, C02003
  4. Gomes da Silva, P., Coco, G., Garnier, R. and Klein, A.H.F. 2020. On the prediction of runup, setup and swash on beaches. Earth-Science Reviews 204, 103148
  5. Holman, R.A. and Sallenger, A.H. 1985. Setup and swash on a natural beach. J. Geophys. Res. 90: 945–953
  6. Stockdon, H.F., Holman, R.A., Howd, P.A. and Sallenger, A.H. 2006. Empirical parameterization of setup, swash, and runup. Coast. Eng. 53: 573–588
  7. Medellín, G., Brinkkemper, J.A., Torres-Freyermuth, A., Appendini, C.M., Mendoza, E.T. and Salles, P. 2016. Run-up parameterization and beach vulnerability assessment on a barrier island: a downscaling approach. Nat. Hazards Earth Syst. Sci. 16: 167–180
  8. Hanslow, D.J. and Nielsen, P. 1992. Wave setup on beaches and in river entrances. In: Proc. of the 23rd International Conference on Coastal Engineering. Venice, Italy, pp. 240–252
  9. Didier, D., Caulet, C., Bandet, M., Bernatchez, P., Dumont, D., Augereau, E., Floc’h, F. and Delacourt, C. 2020. Wave runup parameterization for sandy, gravel and platform beaches in a fetch-limited, large estuarine system. Continental Shelf Research 192: 104024