Potential erosion capacity of gravity currents created by changing initial conditions
<p>We investigate to what extent the initial conditions (in terms of buoyancy and geometry) of saline gravity currents flowing over a horizontal bottom influence their runout and entrainment capacity. In particular, to what extent the effect of the introduction of an inclined channel reach, ju...
| Main Authors: | , , |
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| Format: | Article |
| Language: | English |
| Published: |
Copernicus Publications
2019-04-01
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| Series: | Earth Surface Dynamics |
| Online Access: | https://www.earth-surf-dynam.net/7/377/2019/esurf-7-377-2019.pdf |
| Summary: | <p>We investigate to what extent the initial conditions (in terms of buoyancy and
geometry) of saline gravity currents flowing over a horizontal bottom
influence their runout and entrainment capacity. In particular, to what
extent the effect of the introduction of an inclined channel reach, just
upstream from the lock gate, influences the hydrodynamics of gravity currents
and consequently its potential erosion capacity is still an open question.
The investigation presented herein focuses on the unknown effects of an
inclined lock on the geometry of the current, on the streamwise velocity, on
bed shear stress, and on the mechanisms of entrainment and mass exchange.
Gravity currents were reproduced in the laboratory through the lock-exchange
technique, and systematic tests were performed with different initial
densities, combined with five initial volumes of release on horizontal and
sloped locks. The inclination of the upstream reach of the channel (the lock)
was varied from 0 % to 16 %, while the lock length was reduced by up to <span class="inline-formula">1∕4</span> of
the initial reference case. We observed that the shape of the current is
modified due to the enhanced entrainment of ambient water, which is the
region of the current in which this happens most. A counterintuitive relation
between slope and mean streamwise velocity was found, supporting previous
findings that hypothesized that gravity currents flowing down small slopes
experience an initial acceleration followed by a deceleration. For the
steepest slope tested, two opposite mechanisms of mass exchange are
identified and discussed, i.e., the current entrainment of water from the
upper surface due to the enhanced friction at the interface and the head
feeding by a rear-fed current. The bed shear stress and the corresponding
potential erosion capacity are discussed, giving insights into the
geomorphological implications of natural gravity currents caused in different
topographic settings.</p> |
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| ISSN: | 2196-6311 2196-632X |