121 results
People
PROJECT NUMBER • 2002-652
PROJECT STATUS:
COMPLETED

Aquatic Animal Health Subprogram: enhancement of the emergency disease management capability in Victoria - developing a Victorian Control Centres Management Manual

AQUAVETPLAN and its associated manuals, and in particular the ‘AQUAVETPLAN Control Centres Management Manual’ provide the necessary framework for the development of a Victorian management/operational manual that would meet the planning needs in relation to aquatic animal diseases. The...
ORGANISATION:
Agriculture Victoria
TAGS
Workforce
Fisheries Management
Disease
Contamination
Biosecurity
SPECIES
Golden Perch
Australian Bass
Barramundi
Longfin Eel
Southern Shortfin Eel

SEF Industry Development Subprogram: agricultural trials of a fish-based fertiliser (BioPhos) produced from Australian seafood processing wastes - pasture trial during 205-06 irrigation season

Project number: 2002-250.20
Project Status:
Completed
Budget expenditure: $143,198.00
Principal Investigator: Aravind Surapaneni
Organisation: Agriculture Victoria
Project start/end date: 28 Jun 2006 - 30 Jun 2006
Contact:
FRDC

Need

Commercial in confidence. To know more about this project please contact FRDC.

Objectives

Commercial in confidence

SEF Industry Development Subprogram: agricultural trials of a fish-based fertiliser (BioPhos) produced from Australian seafood processing wastes

Project number: 2002-250
Project Status:
Completed
Budget expenditure: $543,784.00
Principal Investigator: Aravind Surapaneni
Organisation: Agriculture Victoria
Project start/end date: 30 Jan 2003 - 15 Sep 2007
Contact:
FRDC
TAGS
Waste
Sustainability
Consumer
Bycatch
Agriculture

Need

Fisheries by-catch and processing wastes are principally organic in nature and therefore can be classified as “organic wastes”. Today there are three major forces operating, which are in effect beginning to control the movement of organic wastes. These are (a) the need for waste minimisation, (b) opportunity to utilise the high nutrient value in waste materials, and (c) increasing barriers for the disposal of waste products (especially those rich in organic content) in waterways or landfills
There are significant benefits to the seafood industry if these criteria can be met. The relevance to the processing industry and minimisation of off-site impacts should be of prime concern when considering the criteria listed above. Some targets to achieve these criteria are:
- Lowering volumes of waste streams leaving the processing industry
- Seeking lower cost disposal options
- Opting for profitable alternatives through value adding
- Increasing public acceptance through adoption of environmentally friendly practices

As well as the above, major benefits to the agricultural industry (especially the organic sector) can also be achieved from the availability of fisher waste-based fertilisers.

These fertilizers have potential use in both conventional and organic agriculture. However, the growing organic sector is of particular interest due to the relative lack of suitable organic fertilizers.

Organic production is a growing industry in Australia. The dearth of effective and tested, nutrient rich products that could be certified as "organic" is recognised within this industry. Provision of successful and a proven certified organic fertilizer has the potential to lift yields from organic farms, in turn encouraging greater adoption of organic farming. There is a strong belief that fish waste-based fertilizers could be designated as “organic”.

Although organic fertiliser products from fishery wastes have been available in the market for considerable time, long-term field evaluation of these products have been scarce. Such evaluation is essential to further extend the current market availability for fish-based fertiliser products. Effective extension of the organic market is only possible by capturing the broadacre organic production market.
Trials with fish-based fertilisers need to be first evaluated in a glasshouse, under controlled conditions to study the short- and long-term availability of nutrients on several soil types and plant crops. Armed with this information, field trials in selected high intensity horticultural production areas need to be conducted to work out appropriate rates and methods of application. Any trials conducted should be aimed at building confidence within the farming community so that a greater adoption rate is assured. Field trials need to be conducted on farmer properties so that tangible benefits from products tested are visually and financially convincing to both the conventional and organic farmer.

To demonstrate ongoing and long-term benefits from application of fish-based organic fertilisers for conventional and organic farming production, any field trial should be conducted over at least two cropping cycles. In addition, several types of products available in the market should be tested against commercially available, traditional inorganic and other organic (e.g. Dynamic Lifter) fertiliser sources.

Objectives

1. Comparison of the agronomic effectiveness of BioPhos with superphosphate in tomato production.
2. Comparison of the agronomic effectiveness of BioPhos with superphosphate in the dryland pasture production.
3. Comparison of the agronomic effectiveness of BioPhos with superphosphate in the irrigated dairy industry.
4. Communication of the outcomes of the trials to agricultural industries.
5. Comparison of the agronomic effectiveness of Biophos with triple superphosphate in the irrigated dairy industry.
6. Semi quantification of water borne losses of soluble phosphorus in irrigation water for the two products.

Final report

ISBN: 978-1-74146-370-5
Author: Aravind Surapaneni
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Industry

Using information for 'data-rich' species to inform assessments of 'data-poor' species through Bayesian stock assessment methods

Project number: 2002-094
Project Status:
Completed
Budget expenditure: $176,237.00
Principal Investigator: David Smith
Organisation: Agriculture Victoria
Project start/end date: 29 Sep 2002 - 30 Nov 2005
Contact:
FRDC
TAGS
Wild Catch
Stock Assessment
Mortality
Modelling
Data

Need

Over 300 species are caught in the SEF, of which around 100 have commercial value. Twenty five species comprise around 90% of the landed catch. Each year, however, quotas are set for only around 17 species. There are 10 of these species for which there is (or has been) some formal stock assessment (that may not occur every year). For all of the remaining quota species and some of the more important non-quota species, no formal assessment is undertaken and the only assessment that can be made is based on investigation of trends in catch and effort and size distribution and anecdotal input from scientists and industry. There is simply not enough resources to undertake formal stock assessments for the wide range of commercial species landed in the SEF. Yet, each of these species is an important component of the catch of fishers. If the fishery is to continue to operate in its current form and meet the strategic assessments required under the EPBC Act, some form of formal assessment is required.

A recently completed ARF project (Production parameters from the fisheries literature for SEF-like species - Project no R99/0308) demonstrated the utility of using information for "similar" species when conducting assessments for SEF species. Using key parameters such as the virgin biomass, the rate of natural mortality, and the “steepness” of the stock-relationship relationship, a simple formula was developed for identifying “similar” stocks / species and an algorithm was developed for constructing prior probability distributions for these parameters. The resultant distributions can be used in Bayesian stock assessments and as the basis for sensitivity tests when applying other methods of stock assessments. The current project will refine the prior distributions for the production parameters and develop and test methods of stock assessment that use the results of assessments for well-studied species in a formal manner to inform assessments of ‘data-poor’ species. If successful, the methods developed would lead to significant benefits not only for the assessment and management of "data poor" SEF low priority, by-product and by-catch species, but also for a range of new and developing fisheries in Australia.

Objectives

1. Expand the database of production parameters for SEF-like species
2. Develop prior probability distributions for steepness and the coefficient of variation about the stock-recruitment relationship using Bayesian meta-analysis
3. Develop a Bayesian framework within which the results for data-rich species can 'inform' assessments for data-poor species.
4. Apply the framework to three case-studies to determine the robustness of the framework.
5. Test the framework by means on Monte Carlo simulation

Final report

ISBN: 1-74146-524-9
Author: David Smith
Final Report • 2009-04-23 • 5.99 MB
2002-094-DLD.pdf
Final Report • 2009-04-23 • 5.99 MB
2002-094-DLD.pdf
Final Report • 2009-04-23 • 5.99 MB
2002-094-DLD.pdf
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Final Report • 2009-04-23 • 5.99 MB
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Final Report • 2009-04-23 • 5.99 MB
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Final Report • 2009-04-23 • 5.99 MB
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Final Report • 2009-04-23 • 5.99 MB
2002-094-DLD.pdf
Environment

Australian aquaculture - practical solutions to the triple bottom line - a national workshop

Project number: 2001-257
Project Status:
Completed
Budget expenditure: $63,910.00
Principal Investigator: Richard McLoughlin
Organisation: Agriculture Victoria
Project start/end date: 30 Dec 2001 - 1 Dec 2003
Contact:
FRDC
TAGS
Toxin
Health And Safety
Food Safety

Need

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry. In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs. There is thus a regulatory imperative to defining the ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable is often not substantiated by scientific fact, but can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. A negative public perception can also enhance the influence of uninformed pressure groups on Government policy development. This is a constraint to future development of the whole industry.

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives. What is required is a national framework and standards for assessing the environmental performance of aquaculture. Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The Standing Committee on Fisheries and Aquaculture (SCFA) adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework. To date the focus of SCFA framework case studies has been on wild fisheries. This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.

In addition, internationally benchmarked environmental management systems (such as ISO 14000) are options that should be explored to implement ESD frameworks and have already been developed for aquaculture sectors in other parts of the world (Gavine et al 1996, Boyd, 1999).

Advantages for the aquaculture industry in adopting the principles of ESD and documenting environmental performance include:

(1) Improved public perception of the industry;
(2) Reduction in waste and improved efficiency at site level;
(3) A competitive advantage in the market place if accreditation is used as a branding tool; and
(4) Ability to effectively engage new Government policies (such as Tradeable Emissions Policies).

This workshop will be the first step in bringing together the stakeholders to identify issues and develop practical solutions that will allow the Australian aquaculture industry to continue to develop in a sustainable manner.

Boyd, C. 1999. The aquaculture industry must learn to deal effectively with environmental issues, beginning with recognising the role of the different players involved. World Aquaculture 30 (2):10.
Gavine, F. M., Rennis, D. S. and Windmill, D. 1996. Implementing environmental management systems in the UK finfish aquaculture industry. J.C.I.W.E.M 10, October: 341-347.

Objectives

1. To identify practical solutions to ESD issues which will enable aquaculture organisations to develop in a sustainable and cost effective manner.
2. To develop an action plan that achieves a) standard auditing and reporting protocols for environmental performance of aquaculture operations within and ESD framework and b) adapts the existing SCFA ESD framework to incorporate the requirements of aquaculture operations.

Final report

ISBN: 1-74106-536-4
Author: Richard McLoughlin
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 
Final Report • 2003-05-26 • 540.13 KB
2001-257-DLD.pdf

Summary

Federal and state legislation is increasingly demanding more stringent environmental controls on aquaculture activities and place the onus of proof for demonstrating environmental performance on the industry.  In addition, regulation for and approval of aquaculture activities is increasingly directed through state EPAs.  There is thus a regulatory imperative to defining ESD sustainability indicators for the aquaculture industry.

Public perception of the industry as environmentally unsustainable, although not always substantiated by scientific fact, can have a detrimental affect on aquaculture development through objections to individual aquaculture planning applications. 

To address these two issues, there is a clear need to identify the issues related to various aquaculture sectors and develop protocols and frameworks through which organisations can demonstrate their compliance with environmental objectives.  What is required is a national framework and standards for assessing the environmental performance of aquaculture.  Additionally, industry needs to be equipped with practical tools and solutions for dealing with these issues.

The then Standing Committee on Fisheries and Aquaculture (SCFA), now the Australian Fisheries Managers Forum, adopted an ESD framework for fisheries in 1998 and a FRDC/SCFA-funded project has undertaken a number of case studies using this framework.  To date the focus of these case studies has predominantly been on wild fisheries.  This approach needs to be expanded to a broader range of stakeholders involved in aquaculture and fine-tuned to ensure it is appropriate for all aquaculture systems and sectors.  The workshop program involved leading representatives from the aquaculture industry, indigenous communities, non-government organisations, science and government. The workshop was attended by 106 delegates. 

The presentations covered a range of perspectives from many leading industry, government and non-government organisations. It brought to the front a number of key issues and challenges facing the implementation of ESD across the aquaculture industry and highlighted a range of pathways to achieve ESD at a business, regional or National level.

The break-out group sessions identified key issues facing each of seven aquaculture industry sectors and provided feedback on strategies to address those issues along with suggested performance indicators. Many of these issues were consistent across sectors and provided a firm basis for identifying and prioritisation key issues at the national level. 
The group discussion focussed on the drivers / needs to establish a framework for implementing ESD at the National level. Through this discussion there was widespread support to review the existing ESD Framework for the wild capture sector, in order to develop an equivalent framework for aquaculture. A process for reviewing the ESD framework was subsequently developed within the FRDC ESD subprogram. 

Marine Freshwater Research special issue: a complex quota-managed fishery: science and management in Australia's South East Fishery

Project number: 2001-105
Project Status:
Completed
Budget expenditure: $16,364.00
Principal Investigator: David Smith
Organisation: Agriculture Victoria
Project start/end date: 28 Oct 2001 - 30 Jun 2002
Contact:
FRDC
TAGS
Wild Catch
Stock Assessment
Modelling
Fisheries Management
Education

Objectives

1. To publish a special issue of Marine and Freshwater Research on previous research for the South East Fishery

Final report

Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Final Report • 2017-09-29 • 14.59 MB
2001-105-DLD.pdf
Environment

Assessment of the importance of different near-shore marine habitats to important fishery species in Victoria using standardised survey methods, and in temperate and sub-tropical Australia using stable isotope analysis

Project number: 2001-036
Project Status:
Completed
Budget expenditure: $553,689.00
Principal Investigator: Gregory Jenkins
Organisation: Agriculture Victoria
Project start/end date: 7 Nov 2001 - 15 Aug 2005
Contact:
FRDC
TAGS
Survey
Reproduction
Habitat
Food Web
Distribution

Objectives

1. To increase our understanding of fisheries/habitat links using a combination of standardised survey methods in Victoria and Queensland, and isotope analyses across southern Australia and Queensland.
2. To identify the importance of different near shore habitats for important fish species from recruitment to older-life stages, for individual habitats at broad scales and habitat mosaics at finer scales.
3. To improve the quality of data derived from isotope analyses by including a greater range of potential sources of primary production.
4. To understand the transfer of primary production from important habitats to food chains of fish that occur outside that habitat, and also the sources of primary production for fish inhabiting habitat mosaics.
5. To integrate existing near shore habitat data-sets with detailed descriptions of fish/habitat associations in a spatial information system (GIS) that can be accessed by a variety of user groups.

Final report

ISBN: 1-74146-474-9
Author: Gregory Jenkins
Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

Final Report • 2005-11-01 • 2.67 MB
2001-036-DLD.pdf

Summary

The first part of this project was a basic survey of fish use of intertidal habitats such as mangroves, mudflats and saltmarshes, which previously had hardly been considered in temperate Australian coastal waters.

Mangroves (Avicennia marina) and mudflats were used by at least 41 species of fish. Juvenile stages of 41% of the species were sampled and economic species were common. Mangrove habitat in temperate Australian waters supports a richer juvenile fish assemblage than adjacent mudflats, but there is little difference between habitats for the subadult/adult assemblage. Ultimately, the ‘value’ of mangrove habitats to fishes depends strongly on the time and place.

Saltmarshes were difficult to sample because of unpredictable amounts of water cover. Saltmarsh flats were generally only covered with water during low-pressure weather systems. Most fish caught in this habitat were not of commercial value. Water temperature, salinity, depth or barometric pressure did not explain variability in the number of fish species present or fish abundance. Fish species in the saltmarsh flats also live in other habitats such as seagrass, and the observed patterns of habitat use seemed to partly relate to feeding behaviour.

The second part of the fish-habitat survey work aimed to see how the use of habitats by fish changed within different parts of the habitat, and also with respect to the location of other habitats.

Results from the study will be valuable in the future detection of environmental perturbations, providing a baseline data set against which disturbance effects can be assessed. Information on habitat use, and how multiple habitats interact with each other, will put managers in a stronger position to argue for the preservation of important nursery habitat. Results from this project may also be important in advising on the appropriateness of marine park designs to ensure, among other things, fisheries sustainability.

Keywords: Mangrove, mudflat, saltmarshes, fish, zonation, landscape, seagrass, stable isotope, base for nutritional support, carbon and sulphur stable isotopes, commercial

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