Postgraduate Opportunities at CAOUS
CAOUS welcomes enquiries from academically strong and motivated students wanting to undertake a PhD, MSc or Honours at Swinburne.
Reasons for coming to CAOUS for your higher degree include:
- Exciting projects, in the areas of femtosecond laser applications, atom optics, laser trapping and cooling of atoms and molecules and applied optics.
- Well-equipped, modern laboratories and facilities
- Your own up-to-date computer, in a stylish and comfortable office space
 Postgraduate studies poster (pdf)
Swinburne offers a number of scholarship
opportunities, and interested students are encouraged to apply. To fill out the
scholarship application form, you need to contact a
potential supervisor from the list below, and include the project in the application. Further information is available the university's scholarship
website.
CAOUS has projects available for good research students.
Ph.D. projects available for 2009 |
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2-colour 2-dimensional spectroscopy: resolving the mechanisms of coherent coupling in condensed matter systems
Supervisor: Dr Jeff Davis
Until recently, all experimental realisations of optical 2D spectroscopy have used single colour excitation due to experimental complexities.
We have developed a method that utilises a data-processing technique known as phase-retrieval and allows the realisation of two-colour 2D
spectroscopy. This project will enhance and utilise this technique in order to gain deep insight into coherent energy transport dynamics
in coherently coupled quantum systems, including chains of coupled semiconductor quantum dots and quantum wells.
More details (pdf) |
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Exploring the role of quantum coherence in photosynthesis
Supervisor: Dr Jeff Davis
This project will explore the role of quantum coherence in photosynthesis by studying the dynamics of both coherent and classical
energy transfer, within the isolated molecules and between the molecules within light-harvesting complexes. The ultimate aim is
to develop an in depth understanding of the mechanisms responsible for the efficient energy transfer in photosynthesis.
More details (pdf) |
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Coherent dynamics in semiconductor nanostructures
Supervisor: Dr Jeff Davis
Semiconductor nanostructures, such as quantum dots (QDs) and quantum wells (QWs), have been the subject of intense research over the past 2
decades because of their intrinsic quantum mechanical properties. In this project the coherent dynamics within and between coupled quantum dots
and/or wells will be investigated using novel two-colour experimental
techniques. This will shed light on the mechanisms of coherent coupling, and the role played by coherent phonons, and many-body effects within the
semiconductor lattice
More details (pdf) |
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Mechanical Modeling of Cochlear Implants
Supervisor: Dr Paul Stoddart
Cochlear implants are surgically implanted to provide a sense of hearing for people who are profoundly or severely deaf. Approximately 100,000 people
worldwide have received cochlear implants so far. However, the delicate internal structures of the ear can easily be damaged when the implant is
inserted. This project aims to develop an "Optical Fibre Touch Sensor" that will guide the surgeon when inserting the cochlear implant into the
human ear. This will help to protect the delicate internal structures of the cochlea and preserve any residual existing hearing.
More details (pdf) |
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A Surface-Enhanced Raman Scattering Array for Sensitive Chemical Imaging
Supervisors: Prof. Neso Sojic (Bordeaux), Dr Paul Stoddart (Swinburne), A/Prof. Sally McArthur (Swinburne)
Surface-enhanced Raman scattering (SERS) provides a sensitive analytical technique with great potential for chemical imaging.
The student will initially evaluate the SERS activity of arrays based on thin
metal films and immobilised metal nanoparticles. They will then investigate the potential for further miniaturisation of
the probe by tapering the image fibre to reduce the tip diameter. The resultant probes will then be used to study a variety
of surfaces containing ordered micro and nanoscale patterns of chemistry and biomolecules. A successful imaging system
based on SERS-active fibre arrays will offer a powerful - but relatively simple - approach to rapid, high-resolution chemical imaging.
This is a "Cotutelle" project where the student will be awarded a double-badged doctoral degree. The student will
divide his/her time between Swinburne University of Technology and University of Bordeaux.
More details (pdf) |
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Hyperspectral imaging applied to concentration profiling in electrochemical systems at the microscopic level
Supervisors: Dr Peter Mahon and Dr Paul Stoddart
The project involves the development of a hyperspectral microscopic imaging system for studying the processes occurring in the space above an electrode in
an electrochemical cell. The system requires the development of a novel kind of supercontinuum (broad band) light source based on tapered optical fibres.
This light source will allow chemical concentrations to be mapped from absorption measurements performed with microscopic resolution. This application of
optics and spectroscopy will enable electrochemical reactions to be fully characterized based on simultaneous spectral and spatial measurements.
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Development of an optical fibre sensing system for detection and monitoring of localised strain concentrations on Defence platforms
Supervisors: Dr Paul Stoddart and Dr Claire Davis (DSTO)
This project will involve the development and validation of a low-cost self-diagnostic fibre-optic sensing system which can detect regions of
localised strain concentration. The sensor will be validated on materials and structures for defence applications. The project is located at Swinburne
but is a collaboration with the Defence Science and Technology Organisation.
More details (pdf) |
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Molecular condensates and Degenerate Fermi gases
Supervisors: Chris Vale, Wayne Rowlands, Peter Hannaford
In the cold molecules lab we have several research programs underway which use 6Li gas cooled to quantum degeneracy.
Our primary goals are to study Bragg scattering of paired superfluids, coherence properties of molecular BECs and p-wave
molecule formation. We have PhD and Honours level projects available in these areas.
More details (pdf) |
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Matter Wave Interferometry on an Atom Chip
Supervisosr: Prof. Andrei Sidorov, Dr Brenton Hall and Prof. Peter Hannaford
Atom chips produce ultracold atomic clouds and can be used for the production and quantum control of Bose-Einstein condensates.
The research project is aimed at the production of degenerate quantum gases on a microwire chip, the development of double-well
atom interferometer and studies of coherence of matter waves. The project is a part of the ARC Centre of Excellence for
Quantum-Atom Optics and is well equipped with top-performance diode lasers, a versatile computer control and a
sophisticated imaging CCD system.
More details (pdf)
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Deterministic source of single photons
Supervisors: Prof. Andrei Sidorov, Dr Alexander Akulshin and Prof. Russell McLean
The ability to generate and manipulate single photons in a controllable way is of paramount importance for the development of
quantum communication and information processing. The project aims to develop a deterministic source of single photons using
ultracold trapped atoms and Raman scattering of photons. The scope of the project includes the production of the trapped atoms,
the realisation of a “write –read” process, the detection of the single photons and studies of coherence properties of the
photons.
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Magnetic lattices for ultracold atoms
Supervisors: Prof. Peter Hannaford, Prof. Andrei Sidorov and Prof Russell McLean
Periodic lattice potentials provide an important means for manipulating the properties of ultracold atoms and Bose-Einstein
condensates (BECs), allowing a variety of quantum phenomena to be investigated. This project will use a novel approach based on
magnetic lattices created by patterned magnetic films on an atom chip to study quantum phenomena associated with the tunnelling
of ultracold atoms and BECs between lattice sites. The basic BEC and atom chip apparatus has been constructed and is operational.
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Two-Mode Theory of Double Well Interferometry with Bose-Einstein Condensates
Supervisor: Assoc. Prof. Bryan Dalton
The project will involve developing computer codes for solving self-consistent equations for the fragmented state
amplitudes and the modes of an N-boson system, solve the equations numerically for typical processes, and determining
the first order quantum correlation function and number of bosons in the excited state at the end of the
interferometry process.
More details (pdf) |
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Honours projects for 2009 |
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Optical Fibre Bragg Grating Sensors
Supervisor: Dr Paul Stoddart
The Applied Optics group has a number of projects underway that utilise fibre Bragg gratings as sensitive
monitors of temperature and strain. These projects include an air flow rate sensor, cryogenic temperature sensor and a
fail-safe sensor for smart composite structures. The gratings are produced on our state-of-the-art grating fabrication system.
There is plenty of scope for student involvement in these exciting applied projects.
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Two-component Bose condensate on an atom chip
Supervisors: Prof. Andrei Sidorov and Dr Brenton Hall
The aim of the project is the investigation of coherence properties of a Bose condensate. The project
involves the production of a coherent superposition of two quantum states in the condensate using
two-photon microwave/radiofrequency fields and studies of coherent evolution of the states in the
running Atom Chip I setup.
More details (pdf) |
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Phase locking of two diode lasers
Supervisors: Prof. Andrei Sidorov and Dr Alexander Akulshin
Two laser beams with frequency separation of 6.8 GHz are required in studies of “slow light”
and “storage of light” phenomena and for the preparation of coherent superposition of hyperfine
states with 87Rb atoms. Mutual coherence of the beams is of paramount significance for the
successful realisations of these effects. A typical system involves beating laser beams on a
fast photodiode, mixing the microwave beat signal with a stable reference signal at 6.8 GHz,
and feeding back the error signal to a current control of one of the lasers. The project is of
experimental nature and will involve building electronic circuits, the diode laser operation and
laser spectroscopy experiments with atomic vapours and cold atoms.
More details (pdf) |
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Enhanced nonlinearity and spatial nonlinear effects of coherent atomic media
Supervisors: Alexander Akoulchine and Russell McLean
The aim of this project is the study of spatial nonlinear
effects, such as self-focusing, diffraction and waveguiding, in atomic media with light-induced ground-state
coherences. There is a room for modelling and theory within this mainly experimental project. Through
involvement in the project you will learn fundamental aspects of atomic physics and quantum mechanics and
will obtain hands-on experience with high-resolution laser spectroscopy..
More details (pdf) |
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Molecular condensates and Degenerate Fermi gases
Supervisors: Chris Vale, Wayne Rowlands, Peter Hannaford
In the cold molecules lab we have several research programs underway which use 6Li gas cooled to quantum degeneracy.
Our primary goals are to study Bragg scattering of paired superfluids, coherence properties of molecular BECs and p-wave
molecule formation. We have PhD and Honours level projects available in these areas.
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Gas Cell for High Harmonics Generation of Extreme Ultraviolet Beam
Supervisor: Dr Lap Van Dao
The generation of extreme ultraviolet pulse using high power femtosecond laser is a very exciting topic
not only for study of the interaction between intense laser field and matters but also for application
such as coherent diffraction imaging.
The aim of this project is to design different cell for generation of high harmonics in gas
medium. The properties of emission especial the quasi-phase matching will be studied.
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Two-Mode Theory of Double Well Interferometry with Bose-Einstein Condensates
Supervisor: Assoc. Prof. Bryan Dalton
The project will invilve developing computer codes for solving self-consistent equations for the fragmented state
amplitudes and the modes of an N-boson system, solve equations numerically for typical processes, and determining
the first order quantum correlation function and number of bosons in the excited state at the end of the
interferometry process.
More details (pdf) |
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For more details contact Professor Peter Hannaford (phannaford@swin.edu.au)
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