97 results

NCCP: Expanded modelling to determine anoxia risk in main river channel and shallow wetlands

Project number: 2017-055
Project Status:
Completed
Budget expenditure: $205,269.00
Principal Investigator: Justin Brookes
Organisation: University of Adelaide
Project start/end date: 30 Jun 2017 - 30 Dec 2018
:

Need

Need
The National Carp Control Plan (NCCP), operating within the Fisheries Research and Development Corporation (FRDC), is developing a plan for potential release of the virus known as Cyprinid herpesvirus 3 (CyHV-3) to control invasive common carp, Cyprinus carpio, in Australian freshwater environments.

If the carp virus is approved for release, major carp mortality events are likely. It is necessary to better understand the potential ecological consequences of such events, and hence to inform clean-up strategies for carp biomass post-release. One potential risk is hypoxia or anoxia in the river system associated with microbial degradation of carp carcasses in accumulation hotspots. As carp inhabit a range of habitat types, including reservoirs, lakes, river and wetlands it is necessary to understand the oxygen dynamics in each of these habitats so that the risk can be adequately managed.

Objectives
The aim of this project is to predict the impact of mass carp mortality on the dissolved oxygen concentration of wetlands, rivers and floodplain habitats. This requires assessment of how the key processes that affect oxygen in these different environments respond to changes in hydrologic flushing, temperature and other environmental attributes, and consideration of the likelihood of carp accumulation.

This modelling will be used to inform the cost-benefit analysis of the carp control program of FRDC, aid assessment of what ecological and infrastructure assets are at greatest risk, and determine whether flow can be used as a strategy to re-aerate water in the event of hypoxia.

Objectives

1. The aim of this project is to predict the impact of mass carp mortality on the dissolved oxygen concentration of wetlands, rivers and floodplain habitats. This requires assessment of how the key processes that affect oxygen in these different environments respond to changes in hydrologic flushing, temperature and other environmental attributes, and consideration of the likelihood of carp accumulation.This modelling will be used to inform the cost-benefit analysis of the carp control program of FRDC, aid assessment of what ecological and infrastructure assets are at greatest risk, and determine whether flow can be used as a strategy to re-aerate water in the event of hypoxia.

Report

Authors: Justin D. Brookes Brendan Busch Phillip Cassey Matthew R. Hipsey Mark Laws Sanjina Upadhyay Richard Walsh
Report • 2019-10-18 • 74.69 MB
2017-055-DLD.pdf

Summary

This investigation was undertaken by the University of Adelaide and the University of Western Australia as a part of the research priorities for the National Carp Control Plan. While proposed biological control agents to reduce carp numbers may have positive impacts to aquatic ecosystems, it is possible that wide-spread carp mortality may present considerable risks to the quality of water in Australian wetlands and waterways that need to be managed. Specifically, large-scale carp mortality in aquatic systems will lead to the generation of: 

  • High oxygen demand
  • A pulse of fish-derived nutrients

There is a concern that these impacts will generate water quality risks for humans and ecosystems associated with persistent low oxygen (hypoxia and anoxia), excessive levels of ammonia, and the build-up of cyanobacteria blooms, including the associated challenges of cyano-toxin release, and further deoxygenation during bloom collapse. This study modelled risks to water quality that could arise from carp inputs to a representative set of Australian waterways using data from field and laboratoty trials.

Industry
Environment
Environment
PROJECT NUMBER • 2018-034
PROJECT STATUS:
COMPLETED

Effects of climate change and habitat degradation on Coral Trout

Fishes are at considerable risk from changing environmental conditions because they are, for most part, unable to regulate their body temperature. Exposure to high temperatures may therefore compromise critical biological functions, resulting in reduced performance, fitness and ultimately survival....
ORGANISATION:
James Cook University (JCU)
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Climate resilient wild catch fisheries

Project number: 2021-089
Project Status:
Completed
Budget expenditure: $292,985.00
Principal Investigator: Veronica Papacosta
Organisation: Seafood Industry Australia (SIA)
Project start/end date: 30 Jan 2022 - 29 Sep 2022
:

Need

The need for this project is to activate and engage industry in viable options towards climate resilience by 2030. This includes the need to demonstrate that immediate options exist and are viable and meaningful, while also gaining support for a clear plan to transform the industry and supply chain with support both internally and beyond the sector. The key needs are:

01 | Industry awareness of the problems and solutions around climate change and resilience is below where it needs to be to activate broad transformation. There is little action towards climate resilience (1 player) in comparison to other agricultural sectors.

02 | There will be increasing competition within the protein market to validate and promote sustainable practices and positive contributions to the environment/climate.

03 | Leaders and innovators in the industry are attempting to act in isolation with few resources to support industry and supply chain coordination and acceleration.

04 | Change around the edges that can be achieved by some stakeholders operating alone will not deliver the transformation at a scale or pace that is required to meet growing and broadly felt consumer expectations that indicate demonstrable action on climate change.

05 | There is a surplus of tools, resources and research around climate change and resilience, but to this point, little of that work has been translated into forms fishers find usable and valuable.

06 | There is a need to identify early adopters and innovators in the space to lead new ways operating into the future.

07 | There is an FRDC funded project to undertake a Lifecycle Assessment being concluded early November. This work has been preliminarily identified fuel, transport, and refrigeration as key challenges requiring new solutions/opportunities for industry.

08 | Propulsion and fuel have been identified as key challenges in wild catch fisheries achieving climate resilience and reducing carbon emissions, and will be the focus of this project.

Objectives

1. To understand challenges facing the commercial wild-harvest sector relating to a changing climate
2. To determine opportunities to respond to those challenges, and validate solutions
3. To engage with industry leaders and innovators to explore and validate viable, feasible and scalable options towards climate resilience
4. To demonstrate rapid and practical progress towards climate resilience and elements of SIA’s Our Pledge
5. To build partnerships and relationships with global leaders to enable advancement of prioritised solutions that will enable improved climate resilience

Final report

Authors: Veronica Papacosta Clayton Nelson Tom Cosentino Allen Haroutonian Angus McDonald
Final Report • 2023-12-12 • 8.11 MB
2021-089-DLD.pdf

Summary

This report outlines the impending need for the fishing industry to reduce GHG emissions by 2030. Over 8 months, the project evaluated alternative fuels' potential to cut emissions, recognising challenges in regulatory stimulus and incomplete research. Among numerous options, certain solutions emerged, while others like ammonia and liquid hydrogen faced constraints. The analysis prioritised solutions based on maturity and industry suitability. Economic assessments underscored the significance of fuel prices in shaping viability. The report introduces the "energy transition paradox," emphasising incremental positive steps toward change. Scenarios and roadmaps were crafted, identifying renewable diesel and battery/electric outboards as short-term solutions, while green methanol and emissions capture show promise for the medium term.
Adoption
PROJECT NUMBER • 2018-049
PROJECT STATUS:
COMPLETED

A Better Way to Fish: testing the feasibility of tunnel net ‘fish trap’ gear in North Queensland

This study found that tunnel nets are technically feasible in this location. In spite of the weather conditions, the fishing gear remained intact and successfully captured significant numbers of marketable fishes. Importantly, SOCI species were released alive and in excellent condition, as were...
ORGANISATION:
James Cook University (JCU)
Adoption
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