Structure and Evolution of High Brightness Temperature Cores of Quasars and Galaxies. Interstellar scintillation, ISS, is a revolutionary new and powerful technique which we will use to study the highest brightness temperature cores of radio quasars with unprecedented angular resolution, and probe the interstellar medium of our Galaxy in a way not previously possible. The combination of scintillation and conventional VLBI allows imaging with light-month to light-year resolution across the known ....Structure and Evolution of High Brightness Temperature Cores of Quasars and Galaxies. Interstellar scintillation, ISS, is a revolutionary new and powerful technique which we will use to study the highest brightness temperature cores of radio quasars with unprecedented angular resolution, and probe the interstellar medium of our Galaxy in a way not previously possible. The combination of scintillation and conventional VLBI allows imaging with light-month to light-year resolution across the known Universe. Scintillation observations are challenging basic synchrotron physics by uncovering quasar cores with temperatures possibly as high as 10^15 K, and lifetimes many times longer than theory. The Ceduna and Hobart telescopes are cornerstones of our scintillation and VLBI proposals.
Read moreRead less
Formation of Supermassive Black Holes. One of the most remarkable discoveries in astronomy is the observation that supermassive black holes, weighing as much as a billion suns, are found in the centers of galaxies, including our own Milky Way. Astronomers do not understand how these black holes came to be, or their role in the evolution of galaxies. This Discovery Project will address these issues by analysing data on supermassive black holes from the local and early universes. Black holes fasci ....Formation of Supermassive Black Holes. One of the most remarkable discoveries in astronomy is the observation that supermassive black holes, weighing as much as a billion suns, are found in the centers of galaxies, including our own Milky Way. Astronomers do not understand how these black holes came to be, or their role in the evolution of galaxies. This Discovery Project will address these issues by analysing data on supermassive black holes from the local and early universes. Black holes fascinate students both young and old. This Discovery Project will train a new generation of young Australian astronomers at the leading edge of astrophysics.
Read moreRead less
Collaboration with The NANTEN2 International Star Formation Consortium. Through this collaboration Australia, for a very modest sum, will gain its first direct access to the astronomical facilities of the Atacama plateau, one of the best sites for investigating star formation on the Earth. The project fosters international collaboration, and raises the profile of Australian science and facilities by bringing together astronomers from Australia, Japan, Germany, Korea, Chile and Switzerland.The co ....Collaboration with The NANTEN2 International Star Formation Consortium. Through this collaboration Australia, for a very modest sum, will gain its first direct access to the astronomical facilities of the Atacama plateau, one of the best sites for investigating star formation on the Earth. The project fosters international collaboration, and raises the profile of Australian science and facilities by bringing together astronomers from Australia, Japan, Germany, Korea, Chile and Switzerland.The collaborations formed during this project will enable Australian scientists future access to new front-line telescopes such as the Atacama Large Millimeter Array (ALMA), due to commence operations in 2010. Read moreRead less
Before Planets: The Mineralogy and Chemistry of Pre-Planetary Disks. Planets form within the circumstellar disks around young stars. Samples of the solid material composing our own primitive disk are found in meteorites and interplanetary dust particles. Using the powerful technique of astronomical mid-infrared spectropolarimetry, we will ascertain the composition of the material existing within the disks around young stars. By studying a range of disk ages we will determine how the composition ....Before Planets: The Mineralogy and Chemistry of Pre-Planetary Disks. Planets form within the circumstellar disks around young stars. Samples of the solid material composing our own primitive disk are found in meteorites and interplanetary dust particles. Using the powerful technique of astronomical mid-infrared spectropolarimetry, we will ascertain the composition of the material existing within the disks around young stars. By studying a range of disk ages we will determine how the composition evolves with time, and what physical processes affect it, in order to better understand how our own solar system formed. Further, we will image these disks in mm-wave molecular emission and constrain their chemistry and rotational properties.Read moreRead less
Habitable planets and stellar oscillations with the NASA Kepler mission. This project will ensure Australia's participation in a large space mission, which will detect habitable planets, like our own, around stars. We will build strong links to leading international institutions, supply high-level training for students in information processing skills, and develop new techniques for data analysis that are directly relevant to future space missions. This will position Australia in space explorati ....Habitable planets and stellar oscillations with the NASA Kepler mission. This project will ensure Australia's participation in a large space mission, which will detect habitable planets, like our own, around stars. We will build strong links to leading international institutions, supply high-level training for students in information processing skills, and develop new techniques for data analysis that are directly relevant to future space missions. This will position Australia in space exploration, with potential spin-offs for Australian industry. The science of this project will lead to a breakthrough in our understanding of the structure and evolution of stars and their planets, which will enhance Australia's reputation in these two fields of research.Read moreRead less
Interstellar Physics at the Epoch of Galaxy Formation. With large telescopes and major space observatories, we can finally reach back in time and see how galaxies were assembled in the first few billion years of our Universe. We need to determine how gas forms into stars, how massive black holes feed on and interact with their nascent galaxies, how heavy elements are produced, and how dust obscuration or re-radiation affects observations. This proposal brings a world-class team together to devel ....Interstellar Physics at the Epoch of Galaxy Formation. With large telescopes and major space observatories, we can finally reach back in time and see how galaxies were assembled in the first few billion years of our Universe. We need to determine how gas forms into stars, how massive black holes feed on and interact with their nascent galaxies, how heavy elements are produced, and how dust obscuration or re-radiation affects observations. This proposal brings a world-class team together to develop and apply new and unique pan-spectral tools based on physical models of the interstellar plasma and conceived to determine fundamental parameters of collapsing galaxies.Read moreRead less
How many bright stars of the night sky harbour planets? The search for planets around stars is one of the grand endeavours that defines the modern era of astronomy. This project will develop two innovative technologies that will lead this field into new observational terrain: high-contrast aperture masking interferometry at large telescopes, and very narrow angle astrometry at the Sydney University Stellar Interferometer. These new instruments will enable the search for planets around the bright ....How many bright stars of the night sky harbour planets? The search for planets around stars is one of the grand endeavours that defines the modern era of astronomy. This project will develop two innovative technologies that will lead this field into new observational terrain: high-contrast aperture masking interferometry at large telescopes, and very narrow angle astrometry at the Sydney University Stellar Interferometer. These new instruments will enable the search for planets around the bright intermediate-mass stars of our southern sky, and will target the critical orbital scales of planets at solar-system scale separations. This encompasses the habitable zone where conditions could support life, and the sample will have immediate impact on fundamental questions of planetary formation.Read moreRead less
The First Deep Infrared Study of the Nearby Galaxy Population. We will conduct two major near-infrared (IR) surveys: The Southern Galactic Cap near-IR survey, and the Local Sphere of Influence survey. These surveys will capitalise on the innovative and award winning Australian IRIS2 facility. The two surveys push the observational frontier by orders of magnitude. They will be used to explore the close connection between the near-IR global properties of a galaxy and its underlying physics and pro ....The First Deep Infrared Study of the Nearby Galaxy Population. We will conduct two major near-infrared (IR) surveys: The Southern Galactic Cap near-IR survey, and the Local Sphere of Influence survey. These surveys will capitalise on the innovative and award winning Australian IRIS2 facility. The two surveys push the observational frontier by orders of magnitude. They will be used to explore the close connection between the near-IR global properties of a galaxy and its underlying physics and provide a generic local reference for the upcoming next generation infrared space-telescope missions.
Read moreRead less
Particle astrophysics with the Pierre Auger observatory. Australia's scientific reputation is enhanced through participation in international collaborations that aim to solve long-standing mysteries in science. The Pierre Auger Observatory covers a huge 3000 square km in western Argentina, where we are attempting to solve one of the biggest puzzles in modern astrophysics - the origin of the highest energy cosmic rays, particles 100 million times more energetic than we can produce on Earth. Ade ....Particle astrophysics with the Pierre Auger observatory. Australia's scientific reputation is enhanced through participation in international collaborations that aim to solve long-standing mysteries in science. The Pierre Auger Observatory covers a huge 3000 square km in western Argentina, where we are attempting to solve one of the biggest puzzles in modern astrophysics - the origin of the highest energy cosmic rays, particles 100 million times more energetic than we can produce on Earth. Adelaide scientists were founding members of the Auger project, and now have leading roles within the experiment. This is providing our students with access to world-class facilities and researchers in a field which has moved to the mainstream of astrophysics research.Read moreRead less
Stellar oscillations from the ground and space. We are participating in the Danish-led satellite mission MONS. The main instrument is a 32-cm telescope that is being designed and built by an Australian company. It will measure tiny brightness fluctuations in stars that reveal exquisite details about their internal structures. We propose to develop sophisticated processing algorithms that will allow MONS to measure the brightness fluctuations with unprecedented precision. We will also exploit ....Stellar oscillations from the ground and space. We are participating in the Danish-led satellite mission MONS. The main instrument is a 32-cm telescope that is being designed and built by an Australian company. It will measure tiny brightness fluctuations in stars that reveal exquisite details about their internal structures. We propose to develop sophisticated processing algorithms that will allow MONS to measure the brightness fluctuations with unprecedented precision. We will also exploit our new method for detecting oscillations in the brightest stars from the ground using the world's largest telescopes.Read moreRead less