Laboratory experimentation in a large aimular flume (radius 3 m, channel width
and water depth 0.4 m) has been conducted using a geometrically and dynamically
similar Spariina anglica mimic (canopy height 0.21 m, stem density 1000 stems
m~^) to investigate the influence of submerged Spartina on hydrodynamics under
unidirectional currents {Uh = 0.2 m s~*) and the impact upon the dynamics of
suspended cohesive sediments near the bed within the canopy.
The vertical distribution of canopy biomass strongly influences vertical profiles
of time-averaged velocity and turbulent quantities. An inflected velocity profile is
observed in the region 0.79 < z/h < 0.9 which generates shear, T K E and Reynolds
Stress peaks within vicinity of the canopy top. In this region T K E peaks at 15
times the levels observed in un-vegetated experiments. Flows at the canopy top are
strongly intermittent with extremely efficient downward momentum transfer, uf]
and ufz (stream-wise and vertical zero-mean fluctuating velocity) skewness are 0.5
and -0.5 indicating the presence of intermittent downward penetrating gusts. Near
the bed (0 < z/h < 0.3) mean flow velocities are reduced by 88 - 90% in comparison
to un-vegetated flows but turbulence intensities are strongly augmented by wake
shedding from vegetative elements. TKE in this region is approximately equal to
that in un-vegetated flows.
Novel field observations in a low energ>', estuarine fringing marsh site on the Tavy
Estuary, UK, with a vertical array of synchronous velocimeters and optical backscatter
sensors exhibit low velocities (<0.6 ra s"*) and suspension concentrations (<100
mg L"*) in agreement with laboratory simulations. While field observations of
near bed flows exhibit similarity to those measured in the laboratory, magnitudes
of time-averaged flow throughout the water column are so small that the velocity
profile appears constant over depth. Superimposed upon the low field velocities are
small wind generated waves ( < 0.05 m in height and with periods < 3 s) which have
a considerable impact on flow energy and stress estimates, but crucially, cannot be
replicated in the laboratory experiments. Dissipation rates within the laboratory
canopy are 70-200x10"'* m~^s"^ giving reduced Kohnogorov length scales of 0.04 -
0.14 mm. Field values for dissipation are generally of similar magnitude but peak
at up to 600 X10"** m~^s~^. Kolmogorov length scales are consequently 0.06 - 2.6
mm. Using natural intertidal mud, suspension concentrations of 100-200 mg L~*
have been sheared through the mimic canopy. Observations from a vertical array
of miniaturised OBS sensors suggests sediments are maintained in suspension twice
as long, under constant unidirectional currents, compared to un-vegetated flows. In
the field initial concentrations of 100 mg L~* quickly decay to background levels of
<20 mg L"* indicating the rapid setthng of material from suspension.
Use of a novel digital in-line holographic particle iinaging system and the development
of a particle tracking methodology has enabled the high resolution observation
of both sample size and settling velocities of suspended cohesive particles. Laboratory
observations of sample averaged size (74.5 - 111.7 mm) and settling rates (0.35
- 1 mm s~*) are in agreement with published estimates and the limited observational
data that exists for settling rates in marsh systems. Settling velocities estimated
in the field at 0.1 - 0.8 mm s~^. Significantly larger and fast settling aggregates
have been observed than previously recorded. In the narrow range of experimental
suspension concentrations and shear stresses utilised in the present experiments,
significant diff^erences in particle size and settling velocity between vegetated and
un-vegetated flows cannot be identified. Contrasting flux estimates using sample
averaged settling rates and concentrations with full spectral estimates derived from
the holographic particle imager indicate an error in the former fluxes of, on average,
62%. The range of settling rates observed during the pr^ent study raises questions
regarding the accurate representation of marsh surface settling fluxes in numerical
simulations. Large magnitude flux errors may have significant implications for
accurate accretion rates in numerical models of marsh sedimentation.
Date of Award | 2008 |
---|
Original language | English |
---|
Awarding Institution | |
---|
Biomediation of Turbulence and Suspended Sediment Characteristics in Marsh Surface Flows - The Influence of Spartina anglica
Graham, G. W. (Author). 2008
Student thesis: PhD