The instantaneous current velocity u_i is split into:

in which

${\displaystyle {\bar {u_{i}}}}$ = current (wave-averaged) velocity [m/s]

${\displaystyle {\tilde {u_{i}}}}$ = wave (oscillatory) velocity [m/s]with wave-average ${\displaystyle {\bar {\tilde {u_{i}}}}=0}$ below the wave trough

${\displaystyle u_{i}^{'}}$ = turbulent fluctuation [m/s] with ensemble average ${\displaystyle \langle u_{i}^{'}\rangle }$ = 0 and wave average ${\displaystyle {\bar {u_{i}^{'}}}}$ = 0

The wave-averaged total volume flux is defined as

where

${\displaystyle h}$ = wave-averaged water depth ${\displaystyle h={\bar {\eta }}-z_{b}}$ (Figure 2-1) [m]

${\displaystyle V_{i}}$ = total mean mass flux velocity or simply total flux velocity [m/s]

${\displaystyle \eta }$ = instantaneous water level with respect to the Still Water Level (SWL) [m]

${\displaystyle {\bar {\eta }}}$ = wave-averaged water surface elevation with respect to the SWL (Figure 2-1) [m]

${\displaystyle z_{b}}$ = bed elevation with respect to the SWL (Figure 2-1) [m]

The total flux velocity is also referred to as the mean transport velocity (Phillips 1977) and mass transport velocity (Mei 1983). The current volume flux is defined as

where ${\displaystyle U_{i}}$ is the depth-averaged current velocity. Similarly, the wave volume flux is defined as by

where

${\displaystyle U_{wi}}$ = depth-averaged wave flux velocity [m/s]

${\displaystyle \eta _{t}}$ = wave trough elevation [m]

Therefore the total flux velocity may be written as

References

• Mei, C. 1989. The applied dynamics of ocean surface waves. New York: John Wiley.

• Phillips, O. M. 1977. The dynamics of the upper ocean. (2nd Edition). Cambridge, England: Cambridge University Press.

Documentation Portal