The Reef Rescue Marine Monitoring Program (herein referred to as the MMP) undertaken in the Great Barrier Reef (GBR) lagoon assesses the long-term effectiveness of the Australian and Queensland Government's Reef Water Quality Protection Plan (Reef Plan) and the Australian Government's Reef Rescue initiative. The MMP was established in 2005 to help assess the long-term status and health of GBR ecosystems and is a critical component in the assessment of regional water quality as land management practices are improved across GBR catchments. The program forms an integral part of the Reef Plan Paddock to Reef Integrated Monitoring, Modelling and Reporting Program (P2R program) supported through Reef Plan and Reef Rescue. This report details the sampling that has taken place under the Reef Rescue Marine Monitoring Program: Terrestrial discharge into the Great Barrier Reef (project 3.7.2b) for the 2010-11 sampling year, led by James Cook University (JCU).
A group of four NESP Northern Australia Environmental Resources Hub projects operating in the Fitzroy River catchment (Western Australia) used a transdisciplinary (participatory, interdisciplinary and outcomes-focused) approach by having water resource management as a common theme. The projects partly integrated their research processes and outputs and developed strong links with research users. The transdisciplinary project team included researchers from four projects, who integrated their research processes and outputs in pairs: 1.3.3 (Environmental water requirements) and 1.5 (Indigenous water requirements); 1.6 (Multi-objective planning) and 5.4 (Showing and sharing knowledge). Project 6.2 (this research) aimed to support the development of a transdisciplinary research (TDR) approach in the Fitzroy catchment and contribute to the emerging body of knowledge on transdisciplinarity more broadly. We achieved that aim by conducting a formative evaluation (i.e. during project implementation) of the collaboration between the four projects above. This involved: (1) the development of the Theory of Change of this collaboration, (2) a literature review, (3) interviews of research users, and (4) researchers' reflection on the previous steps. The team identified different research impacts occurring because of people's participation in, or access to the outputs of research. Research impacts, on both researchers and research users, included: • learning and increased understanding of scientific information • development of new skills or social learning (i.e. learning from working together with other stakeholders) • empowerment (e.g. meeting and deliberating with peers regarding collective action because of the projects) • enhancing communication with other groups and a better understanding of their perspectives • creating new contacts (e.g. meeting new people) and strengthening existing relationships. Two projects (Environmental water requirements and Indigenous water requirements) have directly contributed to the Fitzroy catchment water allocation plan and to stakeholders' submissions on the draft water plan consultation (i.e. Western Australian Department of Water and Environmental Regulation [DWER] Discussion Paper). The Multi-objective planning and Showing and sharing knowledge projects contributed with less tangible outcomes such as enhancing communication, and strengthening relationships and Indigenous institutions. Researchers identified processes or outputs that contributed positively to knowledge uptake by research users, for example, the use of videos and interactive maps, which can help users such as Traditional Owners to assimilate and use project information. They also identified things that hindered the use of project outcomes, such as confusion between the roles of research and government planning, and the limited capacity of some organisations to use research outputs.
As the global environmental crisis grows in scale and complexity, conservation professionals and policymakers are increasingly called upon to make decisions despite high levels of uncertainty, limited resources, and insufficient data. Global efforts to protect biodiversity in areas beyond national jurisdiction require substantial international cooperation and negotiation, both of which are characterized by unpredictability and high levels of uncertainty. Here we build on recent studies to adapt forecasting techniques from the fields of hazard prediction, risk assessment, and intelligence analysis to forecast the likelihood of marine protected area (MPA) designation in the Southern Ocean. We used two questionnaires, feedback, and a discussion round in a Delphi-style format expert elicitation to obtain forecasts, and collected data on specific biophysical, socioeconomic, geopolitical, and scientific factors to assess how they shape and influence these forecasts. We found that areas further north along the Western Antarctic Peninsula were considered to be less likely to be designated than areas further south, and that geopolitical factors, such as global politics or events, and socioeconomic factors, such as the presence of fisheries, were the key determinants of whether an area was predicted to be more or less likely to be designated as an MPA. Forecasting techniques can be used to inform protected area design, negotiation, and implementation in highly politicized situations where data is lacking by aiding with spatial prioritization, targeting scarce resources, and predicting the success of various spatial arrangements, interventions, or courses of action.
A risk assessment method was developed and applied to the Great Barrier Reef (GBR) to provide robust and scientifically defensible information for policy makers and catchment managers on the key land-based pollutants of greatest risk to the health of the two main GBR ecosystems (coral reefs and seagrass beds). This information was used to inform management prioritisation for Reef Rescue 2 and Reef Plan 3. The risk assessment method needed to take account of the fact that catchment-associated risk will vary with distance from the river mouth, with coastal habitats nearest to river mouths most impacted by poor marine water quality. The main water quality pollutants of concern for the GBR are enhanced levels of suspended sediments, excess nutrients and pesticides added to the GBR lagoon from the adjacent catchments. Until recently, there has been insufficient knowledge about the relative exposure to and effects of these pollutants to guide effective prioritisation of the management of their sources.