Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian N ....Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian Navy, adding up to 60% annually to the cost of propulsive fuel consumption in shipping. We will characterize the chemical and physical properties of the slime adhesives in order to understand how organisms control adhesion, and use these principles to develop new technology, anti-foul paints.Read moreRead less
Effects of global climate change on marine phytoplankton: interactions between UV radiation and elevated atmospheric carbon dioxide levels. Global climate change is one of the most significant ecological challenges for the 21st Century. Phytoplankton contribute over 45% of the planet's annual net primary production and form the basis of most aquatic food chains. Conversely, some phytoplankton are toxic and cause problems in marine and fresh waters. Climate change can potentially disrupt aquatic ....Effects of global climate change on marine phytoplankton: interactions between UV radiation and elevated atmospheric carbon dioxide levels. Global climate change is one of the most significant ecological challenges for the 21st Century. Phytoplankton contribute over 45% of the planet's annual net primary production and form the basis of most aquatic food chains. Conversely, some phytoplankton are toxic and cause problems in marine and fresh waters. Climate change can potentially disrupt aquatic foodchains by its impact on primary production by phytoplankton or stimulating growth of potentially toxic forms. Our project will investigate the combined impact of increasing carbon dioxide and ultraviolet light on phytoplankton and thereby help climate modellers assess the impact of climate change on aquatic ecosystems and particularly on the nation's and the world's fisheries.Read moreRead less
New approaches to measuring the composition and nutrient status of single phytoplankton cells. Phytoplankton support 90% of aquatic food webs, and are responsible for nearly half of global primary productivity. Conversely, blooms of some phytoplankton, often associated with excess nutrients, can cause major environmental problems, including fish kills and risks to human health. However, current methods for determining the nutrient status of phytoplankton are time consuming and ignore the complex ....New approaches to measuring the composition and nutrient status of single phytoplankton cells. Phytoplankton support 90% of aquatic food webs, and are responsible for nearly half of global primary productivity. Conversely, blooms of some phytoplankton, often associated with excess nutrients, can cause major environmental problems, including fish kills and risks to human health. However, current methods for determining the nutrient status of phytoplankton are time consuming and ignore the complexity of responses of different species in mixed populations. This project will develop new, rapid, ways of examining the nutrient condition of individual algal cells, which will be of considerable use to the water industry as well as to our understanding of aquatic ecology.Read moreRead less
Characterisation of Bioadhesives from Marine diatoms. Biofouling occurs at great expense to governments and industry, adding up to 60% annually to the cost of propulsive fuel consumption in shipping. Diatoms include the most common algal biofoulers of natural and artificial surfaces (e.g. ship hulls). The structure of diatom adhesives will be elucidated in order to determine the molecular basis of their adhesive properties. As diatoms are capable of reversible adhesion, an understanding of th ....Characterisation of Bioadhesives from Marine diatoms. Biofouling occurs at great expense to governments and industry, adding up to 60% annually to the cost of propulsive fuel consumption in shipping. Diatoms include the most common algal biofoulers of natural and artificial surfaces (e.g. ship hulls). The structure of diatom adhesives will be elucidated in order to determine the molecular basis of their adhesive properties. As diatoms are capable of reversible adhesion, an understanding of this mechanism may enable development of strategies to counter adhesion in antifouling products (e.g. paints). This knowledge will contribute to development of new adhesives or strategies to modify and/or prevent adhesion.Read moreRead less