Australian Council Of Prawn Fishers Industry Partnership Agreement - Environment RD&E Program
Funder
Fisheries Research and Development Corporation
Funding Amount
$1,103,000.00
Summary
Australia's commitment to 30% of marine protected area by 2030 in response to global concern about ocean health has focussed scrutiny directly on Australia's commercial net fishing sector. The handling of the Macquarie Island Marine Park announcement followed by the closure of gill net fishing in Qld in 2023 and marine protection proposals in WA have all challenged the commercial fishing sector's reliance on objective, risk based, scientific fisheries management and resource allocation. The fo ....Australia's commitment to 30% of marine protected area by 2030 in response to global concern about ocean health has focussed scrutiny directly on Australia's commercial net fishing sector. The handling of the Macquarie Island Marine Park announcement followed by the closure of gill net fishing in Qld in 2023 and marine protection proposals in WA have all challenged the commercial fishing sector's reliance on objective, risk based, scientific fisheries management and resource allocation. The focus on the commercial fishing sector appears incongruous to Australia’s effectiveness addressing greater impacts on coastal and marine health as identified in the five yearly Statement of Environment reports.
Australia's prawn trawl sector must continue its front-footed environmental stewardship actions to address Net Zero targets and the proposed Nature Positive Act. The ACPF must now build on its transparent community engagement activity with further investment as evidence of the sector's priorities. The ACPF's concerted community engagement activity commenced under FRDC Project 2018/172 and continued under the ACPF's 2021-2026 Community Engagement Plan. The sector must continue to actively reduce trawl impact at the same time as demonstrate its outstanding sustainability credentials as a food supplier.
The project invests within the scope of the FRDC's Environment Program with delivery into Communities, People, Adoption and Industry Programs. The project delivers on the following ACPF RD&E strategic activities against ACPF's Strategic Goals:
Strategic activity: Reduce impacts of fishing on bycatch and the marine environment (and continue to identify environmental risks to natural resource access). ACPF + cross-jurisdiction. (Delivering against Goal 1: Sustainability; Ecological. Goal 2: Stewardship marine resources. Goal 5: Society and Consumers trust, respect and value.)
Strategic activity: Co-investment opportunities in ecosystem health, climate change, carbon footprint. (Delivering against Goal 2: Stewardship of marine and aquatic environments)
Strategic activity: Best practice/Responsible fishing practices communication. (Delivering against Goal 2: Stewardship of marine and aquatic environments)
Strategic activity: Profile RD&E addressing social licence risks. (Delivering against Goal 1: Sustainability; Social. Goal 2: Stewardship marine resources and aquatic environments. Goal 3. A culture that is inclusive and forward thinking. Goal 4. Fair, equitable and secure access. Goal 5: Society and Consumers trust, respect and value.)
The project proposes to collate baseline data, invests in trawl impact RD&E, invests in nature positive initiatives across the environment metrics of the ESG framework and communicates all in a way that engages identified audiences.
The project will contain subprojects which will be identified and scoped in line with the overarching project strategy. Applications for subprojects will be sought using a range of mechanisms - competitive applications, direct or select tender as recommended by the project's steering committee (industry representatives, FRDC, an eNGO and a technical expert). Subprojects seeking national funding must demonstrate Return on Investment to a significant proportion of the sector. Subprojects will be contracted by the ACPF and report deliverables to the FRDC.
Co-investment will be sought from stakeholder partners and/or made by the project into externally managed projects. Objectives: 1. Australian wild prawn sector is Ecologically, Economically and Socially sustainable through pursuing low impact, fuel efficient and financially viable prawn trawl gear technology 2. Australian wild prawn sector plays a critical lead role in the stewardship of our marine resources seeking partnership with stakeholders 3. Through strategic co-investment to address threats on the horizon, the Australian wild prawn sector invests in new innovation that enables fair, equitable and secure access to marine resources 4. Australian society and consumers trust, respect and value the Australian wild prawn sector and its product achieved via its stewardship 5. The Australian wild prawn sector's people are equipped to adapt to climate challenges and the environmental performance standards required of all marine users Read moreRead less
Fish LIGHT - Low Impact Gears And Innovative Harvest Technologies
Funder
Fisheries Research and Development Corporation
Funding Amount
$9,050,000.00
Summary
This program of works supports the trial, implementation, and evaluation of innovative and alternative low-impact harvest technologies (fishing gears) within Queensland’s inshore fisheries (East Coast and Gulf of Carpentaria). The program will be developed in a way that supports an evidence-based approach to developing and trialling sustainable alternative commercial fishing gears, and be run in collaboration with relevant Government agencies and fisheries stakeholders.
Through the addi ....This program of works supports the trial, implementation, and evaluation of innovative and alternative low-impact harvest technologies (fishing gears) within Queensland’s inshore fisheries (East Coast and Gulf of Carpentaria). The program will be developed in a way that supports an evidence-based approach to developing and trialling sustainable alternative commercial fishing gears, and be run in collaboration with relevant Government agencies and fisheries stakeholders.
Through the additional support of co-investment of $4.5 million by FRDC (in line with this application and the approved funds listed under project 2023-154), the program will be delivered in two stages across a six-year timeframe (up to a total investment of $9 million).
The fishing methods to be trialled as part of the first stage will range from exploring enhancements of existing low-impact gear types, through to trials of innovative harvest technologies. The alternative low-impact harvest technologies will first be trialled in order to demonstrate their triple bottom line credentials. After this, the second stage will support broader implementation and evaluation of commercial application over a three-year period.
The program of works will also explore additional opportunities to enhance the economic value and social profile of the fishery, to ensure that any new harvest technologies align with global best practice standards, product value adding to enhance profitability margins, and improvements in social acceptability.
Wild caught seafood also allows for a diverse mix of species that appeal to a range of consumers and seafood businesses. It is planned that this work will explore potential opportunities for market expansion. Objectives: 1. Undertake gear trials with clear monitoring and assessment of gear performance against economic, ecological (including SOCI interactions) and social indicators. 2. Evaluate different gear trial pathways to understand the cost benefit trade-offs, timeframes and identify principles for success 3. Identify attitudinal, behavioural, and contextual factors affecting the adoption and perception of the alternative gear, and design and implement interventions to alleviate this. 4. Support developmental fishery implementation and optimisation of gears and business models to ensure long-term sustainability. 5. Understand the market and consumer preferences associated with caught combination of new gears and undertake optimisation of post-harvest processes and business models to support profitability. 6. Develop forums and communication materials to support responsible innovation and knowledge transfer for and across Australian community, and with a focus on commercial fisheries and key rightsholders and stakeholders Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC170100032
Funder
Australian Research Council
Funding Amount
$4,272,072.00
Summary
ARC Training Centre in Fire Retardant Materials and Safety Technologies. The ARC Training Centre in Fire Retardant Materials and Safety Technologies aims to train a cohort of industry-focused researchers to improve the fire safety of lightweight materials and structures and fire protection systems. The Training Centre expects to create knowledge on novel green and durable fire retardant materials, advanced fire models for urban and built environment, fire suppression technologies, and new flamma ....ARC Training Centre in Fire Retardant Materials and Safety Technologies. The ARC Training Centre in Fire Retardant Materials and Safety Technologies aims to train a cohort of industry-focused researchers to improve the fire safety of lightweight materials and structures and fire protection systems. The Training Centre expects to create knowledge on novel green and durable fire retardant materials, advanced fire models for urban and built environment, fire suppression technologies, and new flammability tests for compliance with fire safety regulatory standards. An expected outcome of this Training Centre is to accelerate the transformation of Australia’s industries in fire retardant materials, products and engineering services.Read moreRead less
DROP DEFORMATION IN CONFINED MICROFLUIDIC GEOMETRIES. Increasingly, high technology applications in biotechnology and microtechnology industries need to process complex (non-Newtonian) fluids with dispersed particles/droplets in channels as small as several microns (microfluidics). A computational fluid dynamic model of non-Newtonian droplet deformation in microfluidic geometries will be developed, and validated using experimental measurements of the flow field in this project. The aim is to und ....DROP DEFORMATION IN CONFINED MICROFLUIDIC GEOMETRIES. Increasingly, high technology applications in biotechnology and microtechnology industries need to process complex (non-Newtonian) fluids with dispersed particles/droplets in channels as small as several microns (microfluidics). A computational fluid dynamic model of non-Newtonian droplet deformation in microfluidic geometries will be developed, and validated using experimental measurements of the flow field in this project. The aim is to understand and quantify factors influencing droplet deformation. Coupling non-Newtonian characteristics with microfluidic geometries will allow the continuous manufacture of micro-particles of specified size and shape for existing and new applications, and will provide guidance for further extending the process to nano-particle manufacture.Read moreRead less
Enabling low greenhouse gas emissions from road vehicles through the proper use of alternative fuels. A major increase in alternative transport fuel use appears necessary in our response to the challenges of climate change and energy security. This proposal will advance our fundamental understanding of key aspects of the combustion of particular alternative fuels, thus enabling proper engine design and so maximising greenhouse and energy security benefits. Further, the Australian automotive indu ....Enabling low greenhouse gas emissions from road vehicles through the proper use of alternative fuels. A major increase in alternative transport fuel use appears necessary in our response to the challenges of climate change and energy security. This proposal will advance our fundamental understanding of key aspects of the combustion of particular alternative fuels, thus enabling proper engine design and so maximising greenhouse and energy security benefits. Further, the Australian automotive industry is a major employer and exporter, and needs to develop and/or maintain international leadership in low emission technologies to ensure its long term viability. This proposal builds a consortium of local organisations with common interests, thus helping local industry respond to several, significant challenges that they presently face.Read moreRead less
Bycatch Reduction Devices (BRDs) To Reduce The Incidental Catch Of Cuttlefish In The Spencer Gulf Prawn Trawl Fishery
Funder
Fisheries Research and Development Corporation
Funding Amount
$71,000.00
Summary
The Giant Cuttlefish population in Spencer Gulf is the largest in the world and is highly valued by local residents, the tourism industry and the recreational diving sector. But surveys over the last 13 years has indicated that the northern population has, and continues to, decline markedly - leading to major public consternation.
The Spencer Gulf Prawn Fishery is known as one of the best managed trawl fisheries in the world and is permitted to only land three species, the western kin ....The Giant Cuttlefish population in Spencer Gulf is the largest in the world and is highly valued by local residents, the tourism industry and the recreational diving sector. But surveys over the last 13 years has indicated that the northern population has, and continues to, decline markedly - leading to major public consternation.
The Spencer Gulf Prawn Fishery is known as one of the best managed trawl fisheries in the world and is permitted to only land three species, the western king prawn, bugs and southern calamari
A recent SARDI study correlated the observed decline in Cuttlefish abundances with a range of potential factors including: water temperature, weather, pollution (including those from increased shipping activities), predators, prey, habitats, diseases, fishing pressure and tourism. Of these, rainfall was the only factor found to correlate inversely with peak cuttlefish abundance. The study noted the incidental capture of Giant Cuttlefish in the Prawn Fishery but found no clear association between the decline in cuttlefish and fishing intensity. The study noted a positive correlation between trawl effort and the size of the cuttlefish population but this relationship is counter-intuitive and is likely to be coincidental. The evidence therefore does not support an assertion that the recent decline in the abundance of Giant Cuttlefish in northern Spencer Gulf has been caused by prawn trawling or any other forms of fishing.
Nevertheless, due to the low population numbers, all sources of potential mortality of cuttlefish, including that from prawn trawl bycatch, need to be minimized urgently and carefully managed. This project is focused on an attempt to reduce the bycatch of cuttlefish in this fishery using modifications to the trawls used (termed ‘bycatch reduction devices’ or ‘BRDs’). If successful, such BRDs should be suitable for use in locations and at times where cuttlefish bycatches are significant.
Objectives: 1. To test four grid-based designs to determine the best way forward in developing a BRD for this fishery that excludes cuttlefish and crabs, yet does not reduce prawn catch by any more than approx 6% and has a negligible variation in the grade composition of prawns. Read moreRead less
Improved Harvesting Efficiency Of Pearl Oysters Through Modifications To Dive Profiles
Funder
Fisheries Research and Development Corporation
Funding Amount
$188,897.00
Summary
Objectives: 1. To evaluate and recommend modifications to dive profiles used in the WA pearling industry so that the profiles are in accord with safe levels of the Doppler bubble classification system that is widely accepted as a standard for evaluating dive profiles 2. To provide an analysis of the field data collected in relation to diver safety
Reduction Of Oyster Waste: Establishing Best Practices For Controlling Wild Spat Under Commercial Production
Funder
Fisheries Research and Development Corporation
Funding Amount
$100,000.00
Summary
‘Overcatch’ or ‘fouling’, whereby juvenile oysters (wild spat) or other aquatic organisms attach themselves to semi-mature oysters, is the largest farming challenge for Sydney rock oyster (SRO; Saccostrea glomerata) growers in Australia and represents a major barrier to efficient and sustainable production (Wayne Hutchinson, FRDC, personal comm.; Durr & Watson, 2010). Without timely intervention, fouling often renders the oysters unmarketable, leading to substantial proportions of product being ....‘Overcatch’ or ‘fouling’, whereby juvenile oysters (wild spat) or other aquatic organisms attach themselves to semi-mature oysters, is the largest farming challenge for Sydney rock oyster (SRO; Saccostrea glomerata) growers in Australia and represents a major barrier to efficient and sustainable production (Wayne Hutchinson, FRDC, personal comm.; Durr & Watson, 2010). Without timely intervention, fouling often renders the oysters unmarketable, leading to substantial proportions of product being discarded or having growth rates considerably slowed (Watson et al. 2009; Adams et al. 2011). It is estimated that 30–50% of SRO grown in Qld and northern NSW are wasted as a result of fouling with a potential value of $13–30 million/annum (Tim Prowse, QOGA, personal comm.; FRDC, 2022); this is either because the products become unsellable or due to losses associated with current overcatch control treatments. The inability to effectively manage overcatch has contributed considerably to the decline of Qld’s oyster industry over the last century, and similarly remains a significant financial impost to NSW oyster growing operations (de Nys et al. 2002; Cox et al. 2012).
At present, oyster growers typically attempt to mitigate the impacts of overcatch using methods like air drying and heat immersion; but both are labour intensive, have no clear guidelines or benchmarked specifications to support new growers in their implementation, and can result in significant mortalities or even total crop losses if undertaken incorrectly (Fitridge et al. 2012; 2014; Mayrand et al. 2015). While two relatively new technologies exist that hold promise for successfully managing overcatch, namely the ‘cold shock’ hypersaline system and FlipFarm system (Cox et al. 2012; Jackson, 2021), these have not yet been widely trialled or adopted in Australian oyster growing regions. There is thus a pressing need to better understand the optimal parameters for effectively eliminating overcatch while retaining host oyster health in commercial production settings.
The proposed project will respond to this longstanding need by evaluating and comparing the efficacy, practicality and cost-effectiveness of these various existing and emerging overcatch control methodologies under the same commercial environment, location and stock. Trials of these four treatments (air drying, heat immersion, cold shock system, FlipFarm system) will be carried out at established oyster leases in Qld’s Moreton Bay region, which is particularly prone to the impacts of fouling and therefore offers the ideal location to determine the efficacies of different methods in controlling overcatch in on-farm settings. The location also has no pre-existing incidences of QX disease that is currently decimating many other SRO growing regions in NSW and Southern QLD. The findings from this work will provide essential outputs, including validated methods and Best Management Practices (BMPs), which will be widely disseminated to the national oyster industry through various relevant forums.
With the Qld government in particular seeking to rejuvenate its oyster industry (McDougall, 2020), and the entire Australian oyster industry looking to expand and boost production (Oysters Australia, 2020), the timing of this project is optimal. The results will not only assist new growers entering the industry, but they will also provide essential learning to established growers throughout Australia who experience significant oyster losses and labour costs associated with overcatch management. The project also aligns with the Oysters Australia Strategic Plan 2020–2025 to (i) increase the sustainable, efficient production of oysters and their management on farm; (ii) manage industry risks; and (iii) increase industry knowledge, skills and networks. It will further help to meet the objectives of the FRDC’s R&D Plan 2020–2025, particularly Outcome 1 (i.e., ‘growth for enduring prosperity’), by providing the oyster industry with genuine opportunities to reduce crop losses, increase profitability, expand production and enhance their reputation in a stewardship context. From a broader societal perspective, the project outcomes will be crucial in building a properly functioning circular economy in the oyster industry, by preventing the creation of waste in the first place. Objectives: 1. To improve knowledge and establish critical information for controlling overcatch on SRO using existing air drying and heat immersion methods in commercial production settings. 2. To provide oysters growers with validated new technologies (cold shock system, FlipFarm system, temperature / RH sensors) that offer more effective and efficient control of overcatch on SRO in commercial production settings. 3. To reduce oyster losses/deaths, as well as labour requirements, associated with controlling overcatch on SRO, when compared to current practices. 4. To develop Best Management Practices for overcatch control that can be used for demonstration and training to the wider oyster-growing community and public. Read moreRead less
Identification And Development Of Tunas, Billfishes And Roughies
Funder
Fisheries Research and Development Corporation
Funding Amount
$122,625.90
Summary
Objectives: 1. Improved sighs to identify tuna, billfish & roughy larvae, juveniles & adults, using combination of electron microscopy & protein molecular biology.