Flow interactions with an aquatic macrophyte: a field study using stereoscopic particle image velocimetry

This paper reports the morphology of a natural patch of Ranunculus penicillatus and presents high-resolution measurements of flow velocities in its wake using a stereoscopic PIV field measurement system. The patch was 3.80 m long, 1.24 m wide and caused substantial changes to downstream mean velocities and turbulence. Vertical profiles of streamwise mean velocity were not logarithmic and flow was redirected under the positively buoyant canopy, enhancing vertical turbulent mixing in the wake and generating a large region where the velocity covariance u'w' was positive. Turbulent kinetic energy was enhanced downstream from the patch lateral shear layer, but not at the centre of the wake. Spectra downstream from the patch showed that turbulence was neither dominated by fine-scale nor large-scale structures, likely due to the low energy of the flow conditions and lack of a developed vortex street within the measurement domain. Sedimentation was observed at the upstream end of the patch, but not underneath the floating canopy. The methods and results of this work will be useful for planning other in situ studies. Also, the reported data on macrophyte geometry and biometrics will assist with the design of more realistic replicas for use in laboratory studies

The impact of inter-basin water tranfers on the macroinvertebrate fauna of the River Wear

SIGLEAvailable from British Library Document Supply Centre-DSC:DXN019071 / BLDSC - British Library Document Supply CentreGBUnited Kingdo

Impacts of an inter-basin water transfer: Distribution and abundance of Micronecta poweri (Insecta: Corixidae) in the River Wear, north-east England

1. Micronecta poweri (Insecta: Corixidae) is potentially sensitive to changes in river flow. A field experiment was designed to assess the impact of an inter-basin water transfer on the distribution and abundance of M. poweri in the receiving River Wear, north-east England. 2. The transfer increased river discharge threefold for a period of 1 h; the transfer discharge was then reduced to a rate equivalent to double the receiving flow. Velocity changes were variable: some parts of the river channel were subjected to order of magnitude increases in near-bed velocity, others suffered no perceptible change. Losses of fine particulate organic material were associated with the areas of greatest velocity increase. 3. Downstream of the transfer outlet, average total M. poweri abundance in replicate samples was reduced by approximately 50% during the transfer. Losses were variable within the 250 m reach monitored, with some areas gaining and some losing animals. Differences could not be explained simply as a function of proximity to the transfer outlet. 4. Results suggest that transfer impacts are location specific, varying greatly even over short (250 m) distances. For flow sensitive taxa, even relatively minor flow changes (increasing discharge to the 50 percentile flow value) may be considered as disturbance events when viewed at the patch or reach scales. 5. Despite the impacts identified for M. poweri, transfers are generally viewed as having a beneficial effect on the conservation of aquatic habitat in the River Wear. They ensure that water abstractions for potable and industrial supply can continue during the summer months without reducing the availability of suitable salmonid habitat. However, there remains a need to assess the possible transfer of biological material from the donor River Tyne to the receiving River Wear. Copyright (C) 2000 John Wiley and Sons, Ltd

Impacts of an inter-basin water transfer: Distribution and abundance of Micronecta poweri (Insecta: Corixidae) in the River Wear, north-east England

1. Micronecta poweri (Insecta: Corixidae) is potentially sensitive to changes in river flow. A field experiment was designed to assess the impact of an inter-basin water transfer on the distribution and abundance of M. poweri in the receiving River Wear, north-east England. 2. The transfer increased river discharge threefold for a period of 1 h; the transfer discharge was then reduced to a rate equivalent to double the receiving flow. Velocity changes were variable: some parts of the river channel were subjected to order of magnitude increases in near-bed velocity, others suffered no perceptible change. Losses of fine particulate organic material were associated with the areas of greatest velocity increase. 3. Downstream of the transfer outlet, average total M. poweri abundance in replicate samples was reduced by approximately 50% during the transfer. Losses were variable within the 250 m reach monitored, with some areas gaining and some losing animals. Differences could not be explained simply as a function of proximity to the transfer outlet. 4. Results suggest that transfer impacts are location specific, varying greatly even over short (250 m) distances. For flow sensitive taxa, even relatively minor flow changes (increasing discharge to the 50 percentile flow value) may be considered as disturbance events when viewed at the patch or reach scales. 5. Despite the impacts identified for M. poweri, transfers are generally viewed as having a beneficial effect on the conservation of aquatic habitat in the River Wear. They ensure that water abstractions for potable and industrial supply can continue during the summer months without reducing the availability of suitable salmonid habitat. However, there remains a need to assess the possible transfer of biological material from the donor River Tyne to the receiving River Wear. Copyright (C) 2000 John Wiley and Sons, Ltd

The replacement of a native freshwater amphipod by an invader: roles for environmental degradation and intraguild predation

We assessed the extent to which an invader, Gammarus pulex (Crustacea: Amphipoda), has replaced a native, Gammarus duebeni celticus, over a 13-year period in a European river system and some of the abiotic and biotic factors that could account for this. Between 1988 and 2001, 56% of mixed-species sites had become invader-only sites, whereas no mixed sites had become native only again. The native dominated areas of higher dissolved oxygen and water quality, with the reciprocal true for the invader. Field transplant experiments revealed that native survivorship was lower in areas where it had been replaced than in areas where the invader does not yet occur. In invader-only areas, native survivorship was lower than that of the invader when kept separately and lowest when both species were kept together. We also observed predation of the native by the invader. Laboratory oxygen manipulation experiments revealed that at 30% saturation, the native's survivorship was two thirds that of the invader. We conclude that decreasing water quality favours replacement of the native by the invader.9 page(s