Coastal lagoon systems in Tasmania form a fundamental part of coastal ecosystems. Healthy lagoons support local biodiversity, and play a key role in nutrient cycling and flood protection. They provide opportunities for sustainable aquaculture, fishing and tourism, while also being appreciated for their recreational amenity and cultural values. Sustainable management of coastal lagoons is essential to environmental and socioeconomic development.

There is limited information about the ecosystem drivers that are influencing the changes being observed in Pipe Clay Lagoon, leading to knowledge gaps in decision making tools and monitoring strategies required to identify and mitigate these changes. The proposed application is a multifaceted approach to investigate the environmental drivers of change in Pipe Clay Lagoon. The findings can then be used to provide valuable guidance for the management and conservation of other coastal lagoons in Tasmania facing similar challenges, providing a model for proactive monitoring and ongoing sustainability.

The FRDC has a responsibility to ensure that research is undertaken to assist in the management of fisheries and aquaculture resources for ongoing sustainability. The changes being experienced in Pipe Clay Lagoon will have implications on the availability and suitability of the lagoon as a sustainable aquaculture site. The planned approach and objectives of the application align with the FRDC’s R&D Plan for 2020-2025 through:

- Building people's capacity and capability
- Ensuring that resulting knowledge and innovation is adopted for impact through awareness of the needs of the ‘adopter’, local context and effective networking
- Continual improvement and collaboration of industry and community to deliver competitive advantage, healthier ecosystems and community support
- Provision of foundational information

Equally and importantly the application aligns with the NRM Strategy for Southern Tasmania 2030 for Pipe Clay Lagoon and similar systems in that wetland health is improved for socio-economically important systems by working with key partners and encouraging investment in monitoring, land and water management practices and on-ground works.
The enthusiasm of those engaged in the stakeholder consultation process was a strong indication of the need, interest and urgency of the application.

Building on the circularity discussions and work being undertaken by FRDC and the industry, this project seeks to undertake the legwork required to establish a nationwide on-demand End of life (EOL) fishing gear recovery system for Australia and pilot it in key locations. The materials that many nets and ropes are made of are highly valuable and recyclable and in fact in many other countries, is already being recycled or remanufactured. Until now, having a national system has been cost prohibitive due to the large distances and need for economies of scale and limited local buyer interest. As a part of the national targets set by the Australian Government relating to plastics use and recycling, commercial fishing and aquaculture sectors have been exploring how to move to a circular economy model and reduce plastic inputs through a variety of projects run by FRDC and others. However, with fishing gear the biggest plastic polymer input, and contamination challenges, there has yet to be a suitable system established.

This project seeks to enable the opportunities that addressing EOL gear provides in Australia to the commercial fishing and aquaculture sector through the establishment of an effective EOL fishing gear recovery system for the country to reduce the landfill costs to industry. It seeks to build on the learnings from previous projects as well as the ten years of experience of our partner Bureo has in in operating an EOL fishing gear recovery program. Bureo currently have an EOL gear recovery system active in 9 countries.

The key objectives are:
● By the end of 2026 there is an effective end-of-life fishing/aquaculture gear recovery system implemented across key fishing ports, and key aquaculture centres benefiting regional communities and fisheries conservation and assisting the Australian Government to address plastic recovery/recycling targets.
● By the end of 2024, the enabling environment for an effective and fit for purpose EOL fishing/aquaculture gear recovery system is in place within Australia, with commencement of recycling underway in key pilot locations.

In Australia, up to 90% of critical fish habitat for coastal fisheries, including seagrass, giant kelp, saltmarsh, and shellfish reefs, has been lost or significantly degraded. Many research studies have linked habitat with fisheries productivity, with habitat loss particularly impacting juvenile nurseries. Yet despite this information fish habitat restoration is not a recognised management tool in fisheries/harvest management strategies. Given this situation there is a strong need for a cohesive partnership across all fisheries sectors to support repairing productivity through fish habitat restoration and to create a forum where key sectors concerned for or dependent on aquatic habitat condition, can discuss problems and opportunities. This project will address a number of barriers limiting the restoration of fish habitat around Australia; accessibility of data relating fisheries production to habitat condition, limited penetration of this information into management and building a forum for the key fishing sectors to consider this information and develop responses.

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

The Tasmanian Commercial Dive Fishery (TCDF) is transitioning from a fishery with minimal controls on catch with no annual assessment, to a carefully managed fishery with annual robust fishery assessments. Two of the three key species Shortspined Sea Urchin (Heliocidaris erythrogramma) and Wavy Periwinkle (Lunella undulata), have similar life histories to abalone, while the third – Longspined Sea Urchin (Centrostephanus rodgersii), has an intermediate life history. All three species have a time-series of catch and effort data, and some level of biological data, and thus don’t fall into the class of data-poor fisheries. However, just as for haliotid fisheries, all the complexities identified by Orensanz et al (1995) for S-Fisheries (small-scale, spatial structured, sedentary target species) apply here, meaning that integrated assessment models assuming Dynamic Pool should not be used. Instead, Empirical Harvest Strategies based on standardised catch rates are the most appropriate approach to underpin annual assessments and determination of stock status. Given the similarities between these species and abalone (life history, habitat, fishing practices), it is desirable to utilise the considerable investment in research on data collection and assessment methods in that fishery. This project will therefore attempt to adopt and adapt ground-breaking research on Abalone, including utilization of high-resolution spatial data from GPS and depth data loggers, as a short-cut to worlds best practices in the TCDF.

Consideration of stock status for the TCDF species to date has been on the basis of graphical inspection of crude catch rates. As Empirical Harvest Strategies rely heavily on robust catch rate metrics, adopting a model for standardizing catch rates is a critical step for the TCDF fisheries. While there are a diversity of philosophies around catch rate standardization, choosing the optimal standardization model is only part of the challenge. The key challenge for the three key TCDF species are that catch is spatially and temporally fragmented. Both urchin species are highly seasonal, and Shortspined Sea Urchin and Wavy Periwinkle fisheries are spatially discrete with a few high catch areas, and a larger proportion of spatially and temporally disparate low productivity fishing grounds. Similarly, catch is largely landed by a small number of highly active participants, with a larger number of primarily part-time fisheries. This fragmented nature (time, space, people) of the dataset creates challenges for applying standardisation models to establish a robust time-series. Primarily this manifests as highly volatile time-series, that can flip above or below Reference Points over consecutive years. In some fisheries, this challenge is addressed by fitting a multi-year running mean through catch rates, essentially smoothing the trend. While this might have the desired effect of removing hyper-variability in catch rates, it will slow action required as the stocks decline, as well slow catch increases under rebuilding. Preferably, we will instead use environmental variables, quantify fisher experience and make use of fine-scale location data on fishing activity in our catch rate standardization methods.

An additional complication in the Tasmanian Commercial Dive fishery is mixed species fishing. This feature is also present in a sub-set of assessment areas within the Tasmanian Abalone fishery where H. rubra and H. laevigata co-occur, as well as in the Central and Western Zone abalone fisheries in South Australia. Developing a clear catch rate signal in these mixed species fisheries is challenging and an optimal solution has not yet been found, although spatial and depth information most likely will enable differentiation of fishing grounds across species. Through this project we will engage with South Australia specifically to collaborate on logger based approaches to improve assessment of mixed species fishing regions.

As with abalone fisheries, TCDA divers are able to modify their in-water fishing behaviour (swim faster and further) to achieve desired daily catches which has the effect of masking decline in abundance. However, this is not the only form of hyperstability expected in the TCDA fisheries. The highly fragmented stock structure and diver experience are likely to interact to create a second form of hyperstability more common in emerging fisheries, and that is serial depletion, or at least serial fishing of discrete patches. This latter form of hyperstability occurs when more experienced divers with greater knowledge are able to move when more accessible patches become over-exploited.

Local scale depletion is addressed by the establishment of size limits for Wavy Periwinkle and the Shortspined Sea Urchin. Robust size limits have recently been adjusted for Wavy Periwinkle (increase from 30 to 45 mm; FRDC 2011-024) and Shortspined Sea Urchin (increase from 60 to 75 mm FRDC 2017-033); No size limit is intended to be set for range-extending Longspined Sea Urchin, as the objective in this fishery continues to be to achieve localised depletion.

From the 2022/2023 season diver GPS and depth loggers will be compulsory to collect detailed spatial information about the fishery. Several key divers have been using dataloggers for the past eight years, providing a valuable time-series from the more experienced TCDF fishers. The availability of such data creates a new opportunity and leads to the key aim of this project, to develop methodologies and tools to incorporate the detailed spatial catch data into formal stock assessment and harvest strategies. In doing so, methods to facilitate the accurate standardisation of historical logbook data to facilitate transition into logger data to preserving the continuum of the time series is required. The development of reliable fishery dependent assessment metrics is essential in these smaller fisheries where there is no scope for cost-prohibitive fishery independent surveys.

In summary, this project is needed to develop strategies to produce robust standardized catch rate trends, that can be utilized in an Empirical Harvest Strategy. Spatial based Catch Per Unit Effort (CPUE) measures and spatial performance indicators and indices of hyperstability will be critical to facilitate the creation of appropriate stock assessment and harvest strategies for small scale dive fisheries, including smaller haliotid fisheries.