Long range interactions of atoms. Atomic physics is often described as both a basic and enabling discipline and the present project on long range atomic interactions fits within both of those categories. The results of the project will lead to a more thorough understanding of the details of long range atom-atom interactions. This will lead to Australian expertise making a significant contribution in a number of cutting edge areas in atomic and molecular physics.
Application of variational methods in atomic and molecular physics. Atmoic physics is both a basic an enabling science and this project will improve fundamental knowledge about the interactions of electrons and positrons with atoms and molecules. Research will be directly relevant to the activities of the National Positron Beam-Line (located at the Australian National University) which is directed to break-through research in matter-antimatter interactions and materials characterisation.
....Application of variational methods in atomic and molecular physics. Atmoic physics is both a basic an enabling science and this project will improve fundamental knowledge about the interactions of electrons and positrons with atoms and molecules. Research will be directly relevant to the activities of the National Positron Beam-Line (located at the Australian National University) which is directed to break-through research in matter-antimatter interactions and materials characterisation.
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Defining the links between climate change, marine disease and food security. This project will deliver critical new knowledge on the causes of marine pathogen outbreaks that threaten Australia’s $1.6 billion aquaculture industry. Several members of the same genus of bacteria have been implicated in recent mass mortality events in aquaculture species, as well as human illness in consumers of seafood, yet the triggers for unprecedented outbreaks of these pathogens are unknown. By coupling a suite ....Defining the links between climate change, marine disease and food security. This project will deliver critical new knowledge on the causes of marine pathogen outbreaks that threaten Australia’s $1.6 billion aquaculture industry. Several members of the same genus of bacteria have been implicated in recent mass mortality events in aquaculture species, as well as human illness in consumers of seafood, yet the triggers for unprecedented outbreaks of these pathogens are unknown. By coupling a suite of sophisticated molecular biological tools and physiological measurements, this research will resolve the role of environmental disturbances including marine heat waves, floods and plastic pollution in stimulating marine pathogen outbreaks, thereby informing efforts to safeguard Australia’s food security and food safety.Read moreRead less
Density regulation as a major determinant of population persistence: advancing empirical and theoretical approaches to conserve biodiversity. Without efficient application of limited conservation resources, more species will go extinct and invasive species will continue to proliferate. With a better understanding of extinction processes, a higher benefit:cost ratio will ensure better outcomes for biodiversity. We will directly address (1) the sustainable use of Australia's biodiversity by provid ....Density regulation as a major determinant of population persistence: advancing empirical and theoretical approaches to conserve biodiversity. Without efficient application of limited conservation resources, more species will go extinct and invasive species will continue to proliferate. With a better understanding of extinction processes, a higher benefit:cost ratio will ensure better outcomes for biodiversity. We will directly address (1) the sustainable use of Australia's biodiversity by providing evidence-based support for minimum viable population size targets to avoid extinction; (2) responding to climate change by determining the species- and environmentally specific contexts leading to elevated risks of extinction; and (3) protecting Australia from invasive diseases and pests by determining density targets that maximise eradication success.Read moreRead less