The general relationship between channel morphology and the grain size
of sediment in the channel bcd is an important but poorly known aspec
t of alluvial rivers. An analysis of an equation for total sediment fl
ux in the limits of suspension-, bedload-, and mixed-modes of transpor
t indicates distinct, steady-state regimes of channel morphology. Such
regimes are readily seen in published data for modern alluvial rivers
by way of a conventional Shields plot or a plot of channel slope as a
function of relative grain size d/h and the ratio w(s)/u(/) where d
and w(s) are, respectively, mean diameter and fall speed of bed sedime
nts, and h and u. are, respectively, mean depth and friction velocity
of the flow. With slope and mode of transport in an alluvial river co
nstrained by grain size and channel depth alone, estimates of discharg
e and sediment flux follow directly, introduction of the sediment flux
relationship into conventional diffusion models for the evolution of
an alluvial system provides nominal estimates of the response time for
channel adjustment to some external changes. For some major modern ri
vers, this time of response along the entire length of channel is in t
he range 10(3)-10(5) yr, underscoring the potential for complicated, l
ong-time interaction of large alluvial systems with, for example, clim
atic variability.