Revisiting the Link Between Curvature and
Migration
Rate: How Meander Cutoffs Rejuvenate River
Migration
and Initiate Counter Point Bars
Abstract
One of the long and widely held ideas about the dynamics of meandering rivers is that migration
slows down in bends with higher curvatures. Identifying the radius of curvature at which
migration
is fastest is standard practice in field studies of meandering rivers. High-resolution measurements of local
migration
rates in time-lapse Landsat images from rapidly migrating rivers in the Amazon Basin suggest that the variation of
migration
rate closely follows that of the local curvature, with a roughly
constant
phase lag between the two; and a quasi-linear relationship exists between curvature and
migration
rate if this lag is considered. A simple numerical model of channel meandering illustrates the link between curvature and
migration
rate and reproduces observations from the studied rivers. The implication is that meandering rivers migrate fastest at, and slightly downstream of, locations of high local curvature; and one of the most important ways river
migration
is rejuvenated and meandering patterns are reshuffled is the generation of generation of high curvature bends at neck cutoff locations. In these short, newly formed bends, rapid
migration
is driven by high curvature and the short bend length causes the maximum
migration
point to fall on the downstream limb, resulting in translation. These conditions are favourable for counter-point bar development. Although counter point bars are usually thought of as the result of confinement, we suggest that they can also form without any external forcing by banks with low erodibility. The location and definition of the counter point bars can be quantified using a ‘bar type index’, which is the product of two dimensionless signed curvatures: one that corresponds to the actual curvature, and one that is equivalent to the ratio of
migration
rate and erodibility. Large negative values of the bar type index are likely to represent well-developed counter point bars with low N/G deposits. This new framework for modeling and analyzing meandering rivers and their deposits is directly applicable in predicting reservoir architecture and distribution of heterogeneities.
AAPG Datapages/Search and Discovery Article #90323 ©2018 AAPG Annual Convention and Exhibition, Salt Lake City, Utah, May 20-23, 2018