Spatial and temporal variation in growth conditions for young juveniles may
determine the ultimate success of salmonid populations. To assess this asp
ect of habitat quality, we developed a spatially explicit bioenergetics mod
el to predict age-0 Atlantic salmon Salmo salar growth rate potential (GRP)
in rearing streams of the Connecticut River, from the time of stocking in
the spring, to the end of the summer. During the first month after stocking
, there appears to be a paucity of suitable habitat. Most available habitat
is predicted to result in low foraging success of small fish and to be ene
rgetically stressful because of the combination of high spring discharge an
d low water temperature. Although less than 14% of available habitat was pr
edicted to support positive growth in the spring, 47% of the fish we observ
ed occupied microhabitats predicted to yield positive growth, indicating th
e importance of habitat selection. In contrast, from mid-June to August, 67
% of available habitat was predicted to yield positive growth, and 92% of a
ll fish occupied positive growth microhabitats. Consistent with these resul
ts, sites with higher salmon GRP in the early season, but not in the mid- o
r late season, had higher final salmon densities by the end of August. Hydr
oclimatic regimes characteristic of more southerly rearing streams in the C
onnecticut River basin were predicted from our model to cause a potential s
hift from early-season to late-season habitat-related growth constraints al
ong this environmental gradient. This work demonstrates the value of applyi
ng a bioenergetics approach to issues related to conservation of Atlantic s
almon and provides a framework for future research on early life history en
ergetic determinants of habitat duality.