Predicting juvenile salmonid drift-feeding habitat quality using a three-dimensional hydraulic-bioenergetic model
Authored by DJ Booker, MJ Dunbar, A Ibbotson
Date Published: 2004
DOI: 10.1016/j.ecolmodel.2004.02.006
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Abstract
This paper describes a physically based three-dimensional bioenergetic
model for prediction of physical habitat quality for drift-feeding
juvenile salmonids in a river. A three-dimensional Computational Fluid
Dynamics (3D-CFD) model is used to simulate hydraulic patterns in a 50 m
reach of the Bere stream, Dorset, UK. This information is then combined
with a bioenergetic model that uses behavioural and physiological
relationships to quantify the spatial pattern of energy gain when drift
feeding. The model was tested by comparing patterns of predicted energy
intake with observed habitat use by juvenile salmonids at different
times of day.
Hydraulic measurements or predictions are required as input to
bioenergetic models to calculate the foraging range of the fish.
Horizontal and vertical velocity gradients can be high and variable in
shallow streams with complex topography and roughness zones. In this
paper, a three-dimensional hydraulic model enables more realistic
calculation of the foraging area of the fish. This takes account of the
complexity of horizontal and vertical velocity gradients. Numerical
experiments are used to demonstrate the sensitivity of energetic gain to
changes in the method of calculating foraging area. Results support the
hypothesis that feeding fish preferentially select areas of high energy
gain, but move to areas of lower velocity when resting. (C) 2004
Elsevier B.V. All rights reserved.
Tags
Individual-based model
Brown trout
Mountain streams
Rainbow-trout
Grayling thymallus-arcticus
Hydrodynamic model
Computational fluid-dynamics
Young atlantic salmon
Incremental methodology
Reactive
distance