Density‐dependent growth of young‐of‐the‐year Atlantic salmonSalmo salarin Catamaran Brook, New Brunswick

Abstract

SummaryWhile density‐dependent mortality and emigration have been widely reported in stream salmonid populations, density‐dependent growth is less frequently detected. A recent study suggests that density‐dependent growth in stream salmonids occurs at low densities, whereas density‐dependent mortality and emigration occur at high densities.To test the hypothesis that density‐dependent growth occurs primarily at low rather than at high densities, we examined the relationship between average fork length and population density of young‐of‐the‐year (YOY) Atlantic salmon at the end of the growing season using a 10‐year data set collected on Catamaran Brook, New Brunswick. We tested whether (1) average body size decreases with increasing density; (2) the effect of density on average body size is greatest at low densities; (3) growth rate will decrease most rapidly at low effective densities [Σ(fork length)2]; (4) density‐dependent growth is weaker over space than over time; and (5) the strength of density‐dependent growth increases with the size of the habitat unit (i.e. spatial scale) when compared within years, but not between years.There was a strong negative relationship between the average body size and population density of YOY Atlantic salmon in the autumn, which was best described by a negative power curve. Similarly, a negative power curve provided the best fit to the relationship between average body size and effective density. Most of the variation in average body size was explained by YOY density, with year, location and the density of 1+ and 2+ salmon accounting for a minor proportion of the variation.The strength of density‐dependent growth did not differ significantly between comparisons over space vs. time. Consistent with the last prediction, the strength of density‐dependent growth increased with increasing spatial scale in the within‐year, but not in the between‐year comparisons.The effect of density on growth was strongest at low population densities, too low to expect interference competition. Stream salmonid populations may be regulated by two mechanisms: density‐dependent growth via exploitative competition at low densities, perhaps mediated by predator‐induced reductions in drift rate, and density‐dependent mortality and emigration via interference competition at high densities.