This unit of study is for students who gained 65 marks or better in HSC Physics or equivalent. The lecture series contains three modules on the topics of mechanics, thermal physics, and oscillations and waves.

This unit of study is designed for students who have not studied Physics previously or scored below 65 in HSC Physics. The lecture series contains modules on the language of physics, mechanics, and oscillations and waves.

This unit of study is intended for students who have a strong background in Physics and an interest in studying more advanced topics. It proceeds faster than Physics 1 (Regular), covering further and more difficult material. The lecture series contains modules on the topics of mechanics, thermal physics, oscillations and waves and chaos. The laboratory work also provides an introduction to computational physics using chaos theory as the topic of study.

This unit of study is designed for students majoring in physical and engineering sciences and emphasis is placed on applications of physical principles to the technological world. The lecture series contains modules on the topics of fluids, electromagnetism, and quantum physics.

This unit of study has been designed specifically for students interested in further study in environmental and life sciences. The lecture series contains modules on the topics of properties of matter, electromagnetism, and radiation and its interactions with matter.

This unit of study is a continuation of the more advanced treatment of Physics 1A (Advanced). Students who have completed PHYS1001 or PHYS1002 at Distinction level may enrol. It proceeds faster than Physics 1 (Technological), covering further and more difficult material. The lecture series contains modules on the topics of fluids, electricity and magnetism, and quantum physics.

This unit of study provides a broad understanding of the structure, scale and diversity of the universe and an appreciation of the scientific methods used to achieve this understanding. Current areas of investigation, new ideas and concepts which often receive wide media attention will be used to demonstrate how science attempts to understand new and remote phenomena and how our ideas of our place in the universe are changing. The range of topics includes the planets, the solar system and its origin, spacecraft discoveries, stars, supernova, black holes, galaxies, quasars, cosmology and the Big Bang. It also includes day and night sky observing sessions. This unit of study cannot be counted as part of the 12 credit points of Junior Physics necessary for enrolment in Intermediate Physics.

In combination with two semesters of Junior Physics, this unit of study continues a first pass through the major branches of classical and modern physics, providing students with a sound basis for later Physics units or for studies in other areas of science or technology. Hence, this unit suits students continuing with the study of Physics at the Intermediate level, and those wishing to round out their knowledge of physics before continuing in other fields. The modules in this unit of study are: Optics: The wave nature of light, and its interactions with matter; applications including spectroscopy and fibre optics. Thermodynamics: The thermal properties of matter. Computational Physics: In a PC-based computing laboratory students use simulation software to conduct virtual experiments in physics, which illustrate and extend the relevant lectures. Students also gain general skills in the use of computers to solve problems in physics. An introductory session of MATLAB is held in the first three lab sessions for students who are not familiar with programming. Practical: Experimental Physics is taught as a laboratory module and includes experiments in the areas of electrical circuits, nuclear decay and particles, properties of matter, and other topics. Assessment is based on mastery of each attempted experiment. At the end of the semester students prepare a short report on one experiment and make an oral presentation on it.

This unit of study is designed for students with a strong interest in Physics. The lecture topics are as for PHYS2011. They are treated in greater depth and with more rigorous attention to derivations than in PHYS2011. The assessment reflects the more challenging nature of the material presented.
Computational Physics: As for PHYS2011, but at a more advanced level.
Practical: As for PHYS2011.

This unit of study is designed for students continuing with the study of Physics at the general Intermediate level, and represents the beginning of a more in-depth study of the main topics of classical and modern physics. The modules in this unit of study are: Quantum Physics: The behaviour of matter and radiation at the microscopic level. Electromagnetic Properties of Matter: Electric and magnetic effects in materials; the combination of electric and magnetic fields to produce light and other electromagnetic waves; the effects of matter on electromagnetic waves. Computational Physics: The computational physics component is similar to that of PHYS2011.

This unit of study builds on the foundation provided by Junior Physics and first semester of Intermediate Physics, to provide introductions to Cosmology (Structure and evolution of the Universe), and Special Relativity (Space and time at high velocities). Practical: Experimental Physics is taught as a laboratory module and includes experiments in the areas of analysis of stellar images, electromagnetic phenomena, electronic instrumentation, quantum physics, and other topics. Assessment is based on mastery of each attempted experiment. At the end of the semester students may work in teams on a project. Students prepare a written report and oral presentation on their project or one experiment.

Refer to PHYS2911 for an overall description of the Advanced Intermediate Physics program. The lecture topics are as for PHYS2012 with some advanced content. Computational Physics: As for PHYS2012, but at a more advanced level.

The lecture topics are as PHYS2013 with some advanced content. Practical: as for PHYS2013.

This unit is normally restricted to students not majoring in Physics, giving them the flexibility to take a combination of modules that is not offered in the standard units. Please obtain permission from the Senior Physics Coordinator.

This unit of study covers the same topics as PHYS3015, with some more challenging material.

This unit is normally restricted to students not majoring in Physics, giving them the flexibility to take a combination of modules that is not offered in the standard units. Please obtain permission from the Senior Physics Coordinator.

This unit of study covers the same topics as PHYS3025, with some more challenging material.

The lectures on Quantum Physics build on Intermediate Quantum Physics to cover more advanced topics, including atomic theory and spectroscopy, quantisation of the hydrogen atom, angular momentum in quantum mechanics, and perturbation theory.
The module on Computational Physics uses a mixture of lectures and computational lab sessions to explore problem solving using computers. It covers numerical schemes for solving ordinary and partial differential equations, with emphasis on choosing the best method to suit the problem, and on understanding numerical accuracy and stability. All coding is done in MATLAB, and no programming experience is assumed beyond that covered in Intermediate Physics.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3039, but with greater depth and some more challenging material.

The lectures cover the theory of electromagnetism, one of the cornerstones of classical physics. They introduce Maxwell's equations in their differential form, using the power of vector calculus. The main application will be to electromagnetic waves, including reflection and absorption, which have application in fields such as optics, plasma physics and astrophysics. In the practical laboratory classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3040, but with greater depth and some more challenging material.

The lectures cover the theory of electromagnetism, one of the cornerstones of classical physics. They introduce Maxwell's equations in their differential form, using the power of vector calculus. The main application will be to electromagnetic waves, including reflection and absorption, which have application in fields such as optics, plasma physics and astrophysics. The project is carried out in a research group within the School of Physics, working on a research experiment or theoretical project supervised by a researcher. The aim is for students to acquire an understanding of the nature of research, to apply their knowledge of physics and scientific practice, and to serve as preparation for a research project at Honours level and beyond.

The lectures on Quantum Physics build on Intermediate Quantum Physics to cover more advanced topics, including atomic theory and spectroscopy, quantisation of the hydrogen atom, angular momentum in quantum mechanics, and perturbation theory.
The lectures on Astrophysics cover the structure and evolution of stars. We will describe the processes that take place as stars evolve, and the eventual fates of different types of stars. We will show that the presence of a binary companion can greatly alter the fate of a star, and show how accretion can liberate large amounts of energy.
The lectures on Plasma Physics aim to provide an understanding of the physics of fundamental phenomena in plasmas and to introduce the basic methods of theoretical and experimental plasma physics. The course includes a study of collective phenomena and sheaths, collisional processes, single particle motions, fluid models, equilibria, waves, electromagnetic properties, instabilities, and introduction to kinetic theory. Examples will be given, where appropriate, of the application of these concepts to naturally occurring and man-made plasmas.

This unit covers the same topics as PHYS3042, but with greater depth and some more challenging material.

The lectures on Quantum Physics build on Intermediate Quantum Physics to cover more advanced topics, including atomic theory and spectroscopy, quantisation of the hydrogen atom, angular momentum in quantum mechanics, and perturbation theory.
The lectures on Astrophysics cover the structure and evolution of stars. We will describe the processes that take place as stars evolve, and the eventual fates of different types of stars. We will show that the presence of a binary companion can greatly alter the fate of a star, and show how accretion can liberate large amounts of energy.
The module on Computational Physics uses a mixture of lectures and computational lab sessions to explore problem solving using computers. It covers numerical schemes for solving ordinary and partial differential equations, with emphasis on choosing the best method to suit the problem, and on understanding numerical accuracy and stability. All coding is done in MATLAB, and no programming experience is assumed beyond that covered in Intermediate Physics.

This unit covers the same topics as PHYS3043, but with greater depth and some more challenging material.

The lectures on Quantum Physics build on Intermediate Quantum Physics to cover more advanced topics, including atomic theory and spectroscopy, quantisation of the hydrogen atom, angular momentum in quantum mechanics, and perturbation theory.
The lectures on Plasma Physics aim to provide an understanding of the physics of fundamental phenomena in plasmas and to introduce the basic methods of theoretical and experimental plasma physics. The course includes a study of collective phenomena and sheaths, collisional processes, single particle motions, fluid models, equilibria, waves, electromagnetic properties, instabilities, and introduction to kinetic theory. Examples will be given, where appropriate, of the application of these concepts to naturally occurring and man-made plasmas.
The module on Computational Physics uses a mixture of lectures and computational lab sessions to explore problem solving using computers. It covers numerical schemes for solving ordinary and partial differential equations, with emphasis on choosing the best method to suit the problem, and on understanding numerical accuracy and stability. All coding is done in MATLAB, and no programming experience is assumed beyond that covered in Intermediate Physics.

This unit covers the same topics as PHYS3044, but with greater depth and some more challenging material.

The lectures on Condensed Matter Physics provide a basic introduction to condensed matter systems, specifically the physics that underlies the electromagnetic, thermal, and optical properties of solids. The course draws on basic quantum theory and statistical mechanics and considers recent discoveries and new developments in semiconductors, nanostructures, magnetism, and superconductivity.
The lectures on Optics introduce some aspects of modern optics, using the laser to illustrate the applications. They cover the Lorentz model for the optical properties of matter, spontaneous and stimulated emission of light, rate equation analysis of lasers, diffraction, Gaussian beam propagation, anisotropic media and nonlinear optics.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3068, but with greater depth and some more challenging material.

The lectures on High Energy Physics cover the basic constituents of matter, such as quarks and leptons, examining their fundamental properties and interactions. They include some discussion of extensions to the currently accepted Standard Model of Particle Physics, and of the relationships between High Energy Particle Physics, Cosmology and the early Universe.
The lectures on Optics introduce some aspects of modern optics, using the laser to illustrate the applications. They cover the Lorentz model for the optical properties of matter, spontaneous and stimulated emission of light, rate equation analysis of lasers, diffraction, Gaussian beam propagation, anisotropic media and nonlinear optics.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3069, but with greater depth and some more challenging material.

The lectures on Condensed Matter Physics provide a basic introduction to condensed matter systems, specifically the physics that underlies the electromagnetic, thermal, and optical properties of solids. The course draws on basic quantum theory and statistical mechanics and considers recent discoveries and new developments in semiconductors, nanostructures, magnetism, and superconductivity.
The lectures on High Energy Physics cover the basic constituents of matter, such as quarks and leptons, examining their fundamental properties and interactions. They include some discussion of extensions to the currently accepted Standard Model of Particle Physics, and of the relationships between High Energy Particle Physics, Cosmology and the early Universe.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3074, but with greater depth and some more challenging material.

The lectures on Condensed Matter Physics provide a basic introduction to condensed matter systems, specifically the physics that underlies the electromagnetic, thermal, and optical properties of solids. The course draws on basic quantum theory and statistical mechanics and considers recent discoveries and new developments in semiconductors, nanostructures, magnetism, and superconductivity.
The lectures on High Energy Physics cover the basic constituents of matter, such as quarks and leptons, examining their fundamental properties and interactions. They include some discussion of extensions to the currently accepted Standard Model of Particle Physics, and of the relationships between High Energy Particle Physics, Cosmology and the early Universe.
The lectures on Optics introduce some aspects of modern optics, using the laser to illustrate the applications. They cover the Lorentz model for the optical properties of matter, spontaneous and stimulated emission of light, rate equation analysis of lasers, diffraction, Gaussian beam propagation, anisotropic media and nonlinear optics.

This unit covers the same topics as PHYS3080, but with greater depth and some more challenging material.

The lectures on Statistical Mechanics aim to provide a theoretical foundation for statistical mechanics, including both classical and quantum distributions.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3090, but with greater depth and some more challenging material.

The lectures on Statistical Mechanics aim to provide a theoretical foundation for statistical mechanics, including both classical and quantum distributions.
In the Project, students will spend about 4 hours per week working on a research experiment or theoretical project supervised by a researcher. The aim is for students to acquire an understanding of the nature of research by carrying out a project under the supervision of a researcher, and as part of a research group.

The lectures on Statistical Mechanics aim to provide a theoretical foundation for statistical mechanics, including both classical and quantum distributions.
The lectures on Condensed Matter Physics provide a basic introduction to condensed matter systems, specifically the physics that underlies the electromagnetic, thermal, and optical properties of solids. The course draws on basic quantum theory and statistical mechanics and considers recent discoveries and new developments in semiconductors, nanostructures, magnetism, and superconductivity.
In the Laboratory Classes, students will choose from a range of experiments that aim to give them an appreciation of the analytical, technical and practical skills required to conduct modern experimental work.

This unit covers the same topics as PHYS3099, but with greater depth and some more challenging material.