The group's primary interest is the mathematical modelling of fundamental physical properties exhibited by nanoparticles and nanoparticle composite materials. In particular, they are interested in the thermal, electrical, magnetic, optical and mechanical characteristics of nanoparticles and their composites.
Current areas of research include: quantum dots in LEDs and solar cells and biolabelling, plasmonics, energy transfer mechanisms in nanoscale systems, nanomechanics, smart functional materials, nanofabrication techniques and nanocrystal doping.
The Master of Nanoelectronic Engineering will enable students to become familiar with theories governing nano-electronic systems and become proficient in the design and fabrication of nano-electronic systems and integrated circuits. Theory, concepts and design methodologies taught in the course are put into practice during laboratory sessions and used for the design project.
Materials science at the University of Melbourne extends across a range of fields including physics, chemistry, biology, medicine and engineering. The center showcases materials research under five interdisciplinary themes: Materials conservation, Materials for medicine, Quantum and nanophotonic materials, Materials for energy and Materials processing.
This program leads to the award of a Bachelor of Science in Nanotechnology over four years of full-time study, with Honours for students who perform with merit. At present, the principal entry point into this degree is at Stage 1 level. Students are normally expected to complete each stage before proceeding to the next stage. A total of 192 units of credit (UOC) must be completed for the award of this degree.
The Laboratory for Dynamics and Control of Nanosystems (LDCN) is a multi-million dollar state of the art research facility dedicated to the advancement of nanotechnology through innovations in systems theory and control engineering. The main thrust of research in the Laboratory is to develop methodologies, technologies and the necessary instrumentation for fast and accurate interrogation and manipulation of matter at the nanoscale.
The unique capabilities of the AIBN come from merging the skills of the engineer, chemist, biologist and computational scientist to conduct a world-class research program in nano-scale science, technology and engineering, technology transfer and commercialization.
The Innovation Management Dual Majors prepare students for the growing focus of Biotechnology organizations and University/Public Sector based research groups on seeking markets for their scientific outputs.
An interdisciplinary research centre focussing on cutting-edge research in the area of molecular scale computations. This involves a range of important application-based modelling in targeted areas of biological science, materials science, nanotechnology and environmental science as well as a world-leading program in the development of new molecular theory and computational methodologies.