posted on 2012-04-17, 00:00authored byNirmalya Chatterjee, Sergey Lapin, Markus Flury
In the vadose zone, air–water interfaces play
an important
role in particle fate and transport, as particles can attach to the
air–water interfaces by action of capillary forces. This attachment
can either retard or enhance the movement of particles, depending
on whether the air–water interfaces are stationary or mobile.
Here we use three standard PTFE particles (sphere, circular cylinder,
and tent) and seven natural mineral particles (basalt, granite, hematite,
magnetite, mica, milky quartz, and clear quartz) to quantify the capillary
forces between an air–water interface and the different particles.
Capillary forces were determined experimentally using tensiometry,
and theoretically assuming volume-equivalent spherical, ellipsoidal,
and circular cylinder shapes. We experimentally distinguished between
the maximum capillary force and the snap-off force when the air–water
interface detaches from the particle. Theoretical and experimental
values of capillary forces were of similar order of magnitude. The
sphere gave the smallest theoretical capillary force, and the circular
cylinder had the largest force due to pinning of the air–water
interface. Pinning was less pronounced for natural particles when
compared to the circular cylinder. Ellipsoids gave the best agreement
with measured forces, suggesting that this shape can provide a reasonable
estimation of capillary forces for many natural particles.