Add to ORKGSalmon may sense and respond to a range of environmental variables within sea-cages, including light, temperature, salinity, dissolved oxygen, water currents and certain chemical treatments used during production. Environments within sea-cages are typically highly variable in both space and time, with the greatest variation occurring with depth. Preferred swimming depths and densities of salmon are the result of active trade-offs among environmental influences and an array of internal motivational factors such as feed and perceived threats. When preferred levels of multiple environmental cues exist at different depths, behavioural responses to temperature, light, the entry of feed, oxygen levels or the presence of treatment chemicals may do...
Background: Climate change is leading to increased water temperatures and reduced oxygen levels at s...
Stocking densities are commonly used to set limits for the production of fish in sea-cages, yet limi...
Due to increasing demand for salmon and environmental barriers preventing expansion in established s...
Salmon may sense and respond to a range of environmental variables within sea-cages, including light...
In recent years, fish welfare during aquaculture production has received increasing attention, and i...
This thesis aims to describe behavioural responses and welfare parameters for the physostome Atlanti...
Understanding how aquatic species respond to extremes of DO and temperature is crucial for determini...
Dissolved oxygen (DO) conditions in marine aquaculture cages are heterogeneous and fluctuate rapidly...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Atlantic salmon in marine farming environments are exposed to potentially detrimental conditions thr...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Understanding dissolved O2 flux in marine cages, and how individual fish respond to and experience s...
To predict the spatial distribution of animals it is necessary to quantify the energetic costs and g...
Background: Climate change is leading to increased water temperatures and reduced oxygen levels at s...
Stocking densities are commonly used to set limits for the production of fish in sea-cages, yet limi...
Due to increasing demand for salmon and environmental barriers preventing expansion in established s...
Salmon may sense and respond to a range of environmental variables within sea-cages, including light...
In recent years, fish welfare during aquaculture production has received increasing attention, and i...
This thesis aims to describe behavioural responses and welfare parameters for the physostome Atlanti...
Understanding how aquatic species respond to extremes of DO and temperature is crucial for determini...
Dissolved oxygen (DO) conditions in marine aquaculture cages are heterogeneous and fluctuate rapidly...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Atlantic salmon in marine farming environments are exposed to potentially detrimental conditions thr...
Positioning of sea cages at sites with high water current velocities expose the fish to a largely un...
Understanding dissolved O2 flux in marine cages, and how individual fish respond to and experience s...
To predict the spatial distribution of animals it is necessary to quantify the energetic costs and g...
Background: Climate change is leading to increased water temperatures and reduced oxygen levels at s...
Stocking densities are commonly used to set limits for the production of fish in sea-cages, yet limi...
Due to increasing demand for salmon and environmental barriers preventing expansion in established s...