About aquatic habitats
What is 'aquatic habitat'?
Healthy and diverse habitats mean healthy and diverse populations of fish. Habitats are simply those places where aquatic species live.
Aquatic habitats can be described in many ways including:
- the natural materials that comprise the habitat (e.g. rocks, coral, gravel, sand and mud),
- the type of vegetation present (e.g. macrophytes, snags, seaweeds, seagrasses, mangroves and saltmarsh),
- the shape and nature of the habitat (e.g. pools and riffles, billabongs, reefs), or
- the overall ecosystem (e.g. wetlands, floodplains, streams, estuaries, lakes, beaches).
How fish use aquatic habitat
Did you know ...
Silver perch and golden perch can live for 25-35 years.
We all know fish live in water. However, water alone will not ensure that a fish is able to survive. Fish need habitat!
The habitat is the water and all the other things that the fish needs to complete its lifecycle: like food and places to shelter (like snags or coral) and to breed (like gravel beds or seagrass). Some native fish also have to move between different habitats as they mature and breed.
Different species have different habitat requirements and these may change throughout a fish’s life.
A fish’s habitat is more than just the water. The water has to be the right type (freshwater, estuarine or saltwater), temperature, quantity (depth and flow) and quality.
Water flow and quality
Did you know ...
Fish LOVE floods! 60,000 golden perch moved through Menindee Weir during a flood.1
Native fish have adapted to the cycles of high and low water flow that occur naturally in their habitat from droughts, floods and seasonal rainfall patterns. Flooding can be important for breeding. Golden perch, a popular inland recreational fish, show enhanced breeding during floods. Both silver perch and golden perch respond to a rise in river flow by increasing their breeding activity. Even a rise of only 20 to 30cm will cause a response, however this is not uniform across the year.1
Water flow is regulated by dams and weirs and extracting water for drinking, stock and irrigation. In regulated rivers, water is captured in winter, stored, then released for irrigation purposes over summer. This has reversed the natural flow pattern to which native species have adapted.
Native fish are adapted to survive periodic drying of habitat. Lachlan River 2001. Photo: Allan Lugg
Fish are also very sensitive to the quality of water in which they live. Sediments, pesticides or other pollutants in the water may prevent native fish from living in affected habitat areas. Pest species, such as carp, are more tolerant of poor water quality.
The temperature of the water can also be important. For example, at 16-18°C silver perch start to migrate upstream and by 18°C 80% of the fish in an area will be moving. Golden perch prefer slightly warmer water. Adults start to move at 18° while juveniles prefer the water to be 22°C or higher.
Rapid changes in temperature are not desirable. For example, cold water pollution can occur when water is released from the bottom of large dams and this pulse of cold water down a river reduces the potential for reproduction of native fish, sometimes for up to 100km downstream.
Places to eat
Did you know ...
Home delivery for fish: Terrestrial organisms (insects etc) falling into water out of overhanging vegetation can provide over 40% of native fishes’ food intake.2
The sorts of things that fish eat include:
- plants, for example: seagrasses,
- macroalgae (seaweed),
- plankton (microscopic animals and plants),
- invertebrates, eg: mosquitoe larvae, dragonflies, water beetles, boatmen, shrimp, mayflies, and
- other fish.
All of the things that fish eat have habitat requirements of their own. So, changes to habitat might not affect the fish directly but might affect their food source. This, in turn, means that the fish can no longer survive in that habitat.
Strapweed seagrass, Posidonia australis.
Photo: David Harasti
Places to shelter
Fish need to be able to hide from predators. They also need to shelter from extreme conditions such as flood flows and harsh sunlight. In freshwater, areas behind rocks, around submerged logs and branches (snags), among patches of vegetation, in deep pools or undercut banks all provide fish with places to shelter. In estuaries, seagrasses and mangrove forests provide shelter for juvenile fish from predators.
The Murray cod uses snags for shelter and breeding. Photo: Luke Pearce.
If these features are removed from fish habitat, then they become vulnerable to predators.
Some native freshwater fish prefer areas with at least 80% coverage of snags. Both Murray cod and trout cod use snags. Murray cod prefer snags closer to the river bank whilst trout cod prefer snags in the middle of a river.3
Around 80% of Murray cod are found within 1 metre of a snag they can use for shelter.
- Impacts of removing snags (in-stream woody habitat)
- Rehabilitating habitat by putting snags back into rivers
Did you know ...
Nine species of native fish are now locally extinct upstream of the Tallowa dam wall (Shoalhaven River).5
Fish often travel a great distance between where they live and where they reproduce. Fish must be able to swim from one area to another. Golden perch will migrate over 1000km during flood events to find new habitat areas to live or breed.4
Barriers, such as road crossings, weirs, dams or floodgates, can block fish movement. Our native fish cannot jump nor can they swim very fast, therefore pipes (with high velocity water) and wet causeways with small, 10cm drops downstream are barriers to movement. This can have devastating impacts on local populations of fish. Barriers like these mean that fish cannot move upstream because the height and velocity of the water flowing over or through the structure are too strong to swim against.
- Barriers to fish passage
- Rehabilitating fish passage with fishways, fish friendly road crossings, and actively managed floodgates and by removing weirs
Boomi Weir, showing significant headloss which will limit native fish passage.
Places to breed
For many freshwater native fish, breeding is triggered by rising water temperatures and increases in day length. Processes that alter the natural water temperature of a stream, such as the release of cold water from the bottom of dams during summer, can prevent fish from breeding.
The timing, quantity and duration of water flow can also have an impact on fish reproduction. Water flows can be significantly altered by river regulation (constructing dams and weirs and large-scale withdrawal of water for irrigation).
In addition, fish are particular about the type of habitat on which they lay their eggs. For instance, some native fish lay their eggs in hollow logs or on snags, others use undercut banks or aquatic vegetation. Some, like the freshwater catfish, make a nest from gravel and will return to the same nest year after year. When snags are removed, banks collapse due to clearing of riparian vegetation and erosion, or sand and gravel is extracted or washed out the fish that rely on these features lose their places to breed.
An artificial breeding chamber for Murray cod. Photo: Steven Thurston
Murray cod larvae. Photo: Steven Thurston
Case study - Eggs out of water
Galaxias brevipinnis. Photo: Gunther Schmida.
The broad-finned galaxias, Galaxias brevipinnis, spawns during high water flows in mid autumn. Spawning takes place over inundated streamside areas where eggs are laid amongst cobbles and pebbles. Before the next high flow eggs can be out of the water for days or weeks, lying up to 7m from the water's edge. When exposed, eggs need the streamside to remain damp, so shading by surrounding forest is critical. Hatching occurs when eggs are inundated by a subsequent flood.
When these conditions were tested in the laboratory, eggs remained unhatched for up to 57 days under moist conditions but out of water, and up to 120 days when kept in water. However those kept under drier conditions died. It would appear that riparian cover may be important in providing shaded and moist conditions for the survival of eggs in the wild.6
- Mallen-Cooper, M, Stuart, I.G., Hides-Pearson, F. and Harris, J.H. (1995). Fish migration in the Murray River and assessment of the Torrumbarry fishway. Final report to the Murray-Darling Basin Commission for NRMS project N002
- Cadwallader, PL., Eden, AK, and Hook, RA. Role of streamside vegetation as a food source for Galaxias olidus Gnnther (Pisces : Galaxiidae), Australian Journal of Marine and Freshwater Research 31(2): 257 – 262.
- Koehn, J. and Nicol, S. (1998). Habitat and movement requirements of fish. In proc. 1998 Riverine Environmental Forum (Eds. R.J. Banens and R. Lehane) pp. 1-6. October 1998, Brisbane, Queensland. Murray-Darling Basin Commission.
- Reynolds, L.F. (1983) Migration patterns of five fish species in the Murray-Darling river system, Australian Journal of Marine and Freshwater Research, 34: 857-871.
- Gehrke P. C., Gilligan D. M., and Barwick, M. (2002) Changes in fish communities of the Shoalhaven River 20 years after construction of Tallowa Dam, Australia, River Research and Applications 18:3 pp 265-286.
- O'Connor, WG; and Koehn, JD. (1998) Spawning of the broad-finned Galaxias, Galaxias brevipinnis Guenther (Pisces: Galaxiidae) in coastal streams of southeastern Australia, Ecology of Freshwater Fish 7(2):95-100.