Overfishing: Difference between revisions
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Introduction | <b>Introduction</b><br> | ||
Ecological extinction precedes that by all other factors (Jackson et al. 2001) | Ecological extinction precedes that by all other factors (Jackson et al. 2001)<br> | ||
global fishing effort has steadily increased since 1970 (Antimcamara et. al, 2011) | global fishing effort has steadily increased since 1970 (Antimcamara et. al, 2011)<br> | ||
History (Jackson et al. 2001) | History (Jackson et al. 2001)<br> | ||
Time periods | Time periods <br> | ||
Paleological sedimentary records | Paleological sedimentary records<br> | ||
Archeological records from human coastal settlements | Archeological records from human coastal settlements<br> | ||
Written historical documents | Written historical documents<br> | ||
Ecological records from scientific literature | Ecological records from scientific literature<br> | ||
Geographic effects | Geographic effects<br> | ||
Aboriginal use (subsistence exploitation) | Aboriginal use (subsistence exploitation)<br> | ||
Colonial use (systematic exploitation) | Colonial use (systematic exploitation)<br> | ||
Global use | Global use<br> | ||
Causes | Causes<br> | ||
Socioeconomic | Socioeconomic<br> | ||
Exploitation of coral reef fisheries is largely due to a high demand on the global market rather than the density of the local human population. | Exploitation of coral reef fisheries is largely due to a high demand on the global market rather than the density of the local human population. (Cinner and McClanahan, 2006)<br> | ||
Overfishing cannot be quickly stopped because it is heavily tied to economic growth. Fishing pressure is increasing even as global catch declines (Bradbury, 2012) | Overfishing cannot be quickly stopped because it is heavily tied to economic growth. Fishing pressure is increasing even as global catch declines (Bradbury, 2012)<br> | ||
Effects | Effects<br> | ||
Food web | Food web<br> | ||
Herbivorous Fish | Herbivorous Fish<br> | ||
Dense populations of grazing fish and sea urchins abate harmful algae growth (Smith 2010) | Dense populations of grazing fish and sea urchins abate harmful algae growth (Smith 2010)<br> | ||
They too become overfished or die of diseases due to overcrowding (Jackson et al. 2001) | They too become overfished or die of diseases due to overcrowding (Jackson et al. 2001)<br> | ||
Can have profound top-down ecosystem effects from removing top predators (Scheffer et al. 2005) | Can have profound top-down ecosystem effects from removing top predators (Scheffer et al. 2005)<br> | ||
Algae/Corals | Algae/Corals<br> | ||
Excessive fishing of predatory fish leads to explosions in the populations of lower level consumers. These populations then overgraze on coralline algae and cause coral abundance to decrease (Stephens, 2012) | Excessive fishing of predatory fish leads to explosions in the populations of lower level consumers. These populations then overgraze on coralline algae and cause coral abundance to decrease (Stephens, 2012)<br> | ||
Can cause phase shift and eventual replacement of slow-growing corals by fast-growing seaweeds (Smith 2010) | Can cause phase shift and eventual replacement of slow-growing corals by fast-growing seaweeds (Smith 2010)<br> | ||
Coralline algae reduced through cascading trophic effects that increase sea urchin populations (O’Leary et al. 2012) | Coralline algae reduced through cascading trophic effects that increase sea urchin populations (O’Leary et al. 2012)<br> | ||
Some species important for coral recruitment | Some species important for coral recruitment<br> | ||
Causes indirect cascading effects on settlement | Causes indirect cascading effects on settlement<br> | ||
Physical effects | Physical effects<br> | ||
Coral structure can be physically damaged by netting and trapping techniques. Use of explosives and chemicals in fishing is more rare, but can also damage the corals and substrate (Jennings and Polunin, 1996) | Coral structure can be physically damaged by netting and trapping techniques. Use of explosives and chemicals in fishing is more rare, but can also damage the corals and substrate (Jennings and Polunin, 1996)<br> | ||
Losses of biomass and abundance (Jackson et al. 2001) | Losses of biomass and abundance (Jackson et al. 2001)<br> | ||
Precursor for eutrophication, disease, and species introduction as it makes populations more vulnerable (Jackson et al. 2001) | Precursor for eutrophication, disease, and species introduction as it makes populations more vulnerable (Jackson et al. 2001)<br> | ||
Fisheries Management | Fisheries Management<br> | ||
Integrated management for multiple goals on ecosystem scale (Jackson et al. 2001) | Integrated management for multiple goals on ecosystem scale (Jackson et al. 2001)<br> | ||
Aquaculture | Aquaculture<br> | ||
Culturing suspension feeders such as oysters can mitigate eutrophication and improve water quality (Jackson et al. 2001) | Culturing suspension feeders such as oysters can mitigate eutrophication and improve water quality (Jackson et al. 2001)<br> | ||
Management Practices | Management Practices<br> | ||
Most coral reefs exhibit an inverted biomass pyramid | Most coral reefs exhibit an inverted biomass pyramid<br> | ||
Fisheries management has predominantly focused on bottom-up processes, but the increasing role effects of overfishing has altered trophic level interactions (Valentine and Heck, 2005) | Fisheries management has predominantly focused on bottom-up processes, but the increasing role effects of overfishing has altered trophic level interactions (Valentine and Heck, 2005)<br> | ||
Large-scale connectivity of organisms in coral reef ecosystems makes small-scale management practices difficult and often ineffective (Roberts, 1997) | Large-scale connectivity of organisms in coral reef ecosystems makes small-scale management practices difficult and often ineffective (Roberts, 1997)<br> | ||
Increase scale of management in areas with upstream reefs | Increase scale of management in areas with upstream reefs<br> | ||
Local management may be effective in areas with low connectivity | Local management may be effective in areas with low connectivity<br> | ||
Manage reefs for higher cover of settlement-inducing crustose coralline algae (O’Leary et al. 2012) | Manage reefs for higher cover of settlement-inducing crustose coralline algae (O’Leary et al. 2012)<br> | ||
Ecosystem-based management necessary for predicting and avoiding cascading effects (Scheffer et al. 2005) | Ecosystem-based management necessary for predicting and avoiding cascading effects (Scheffer et al. 2005)<br> | ||
References | References<br> | ||
Revision as of 19:00, 25 February 2013
Overfishing
Introduction
Ecological extinction precedes that by all other factors (Jackson et al. 2001)
global fishing effort has steadily increased since 1970 (Antimcamara et. al, 2011)
History (Jackson et al. 2001)
Time periods
Paleological sedimentary records
Archeological records from human coastal settlements
Written historical documents
Ecological records from scientific literature
Geographic effects
Aboriginal use (subsistence exploitation)
Colonial use (systematic exploitation)
Global use
Causes
Socioeconomic
Exploitation of coral reef fisheries is largely due to a high demand on the global market rather than the density of the local human population. (Cinner and McClanahan, 2006)
Overfishing cannot be quickly stopped because it is heavily tied to economic growth. Fishing pressure is increasing even as global catch declines (Bradbury, 2012)
Effects
Food web
Herbivorous Fish
Dense populations of grazing fish and sea urchins abate harmful algae growth (Smith 2010)
They too become overfished or die of diseases due to overcrowding (Jackson et al. 2001)
Can have profound top-down ecosystem effects from removing top predators (Scheffer et al. 2005)
Algae/Corals
Excessive fishing of predatory fish leads to explosions in the populations of lower level consumers. These populations then overgraze on coralline algae and cause coral abundance to decrease (Stephens, 2012)
Can cause phase shift and eventual replacement of slow-growing corals by fast-growing seaweeds (Smith 2010)
Coralline algae reduced through cascading trophic effects that increase sea urchin populations (O’Leary et al. 2012)
Some species important for coral recruitment
Causes indirect cascading effects on settlement
Physical effects
Coral structure can be physically damaged by netting and trapping techniques. Use of explosives and chemicals in fishing is more rare, but can also damage the corals and substrate (Jennings and Polunin, 1996)
Losses of biomass and abundance (Jackson et al. 2001)
Precursor for eutrophication, disease, and species introduction as it makes populations more vulnerable (Jackson et al. 2001)
Fisheries Management
Integrated management for multiple goals on ecosystem scale (Jackson et al. 2001)
Aquaculture
Culturing suspension feeders such as oysters can mitigate eutrophication and improve water quality (Jackson et al. 2001)
Management Practices
Most coral reefs exhibit an inverted biomass pyramid
Fisheries management has predominantly focused on bottom-up processes, but the increasing role effects of overfishing has altered trophic level interactions (Valentine and Heck, 2005)
Large-scale connectivity of organisms in coral reef ecosystems makes small-scale management practices difficult and often ineffective (Roberts, 1997)
Increase scale of management in areas with upstream reefs
Local management may be effective in areas with low connectivity
Manage reefs for higher cover of settlement-inducing crustose coralline algae (O’Leary et al. 2012)
Ecosystem-based management necessary for predicting and avoiding cascading effects (Scheffer et al. 2005)
References