An experiment was performed to assess the influence of coarse bank rou
ghness on flow within a sharply curved bend of the Ocklawaha Creek, a
sand-bedded stream in northern Florida. This involved obtaining system
atic measurements of flow velocity and water-surface topography when t
he outer bank was rough with natural vegetation, and obtaining an iden
tical set of measurements after removing the vegetation and constructi
ng a smooth wall along the outer bank. Results suggest that the roughn
ess from bank vegetation systematically influences the flow field, par
ticularly the secondary current strength and the position of the high-
velocity core, because of its effect on the transverse boundary layer.
The roughness essentially produces a backwater effect that inhibits o
utwardly directed surface flow from closely approaching the outer bank
. This suppresses superelevation on the outside bank and, therefore, w
eakens the inwardly directed transverse pressure gradient and secondar
y current. The flow is steered in a downstream direction, and the core
of high velocity is nearly centered in the channel. In absence of rou
ghness from vegetation, outwardly directed surface flows approach the
outer bank more directly (and earlier in the bend), superelevation on
the outside bank is enhanced, and the transverse pressure gradient and
secondary current are strengthened. The core of high velocity is disp
laced toward the outer bank, and its magnitude is increased. Moreover,
the streamwise position where the high-velocity core is closest to th
e outer bank shifts downstream from its position of closest approach i
n the presence of roughness. This, in principle, should contribute to
asymmetrical bend migration, whereas migration in presence of roughnes
s should be nearly in phase with bend curvature such that bends grow i
n amplitude, albeit slower, and with less asymmetry.