PHYSICS 7565B - M. Philosophy Physics Part B
North Terrace Campus - Semester 2 - 2015
General Course Information
Course Code PHYSICS 7565B Course M. Philosophy Physics Part B Coordinating Unit School of Physical Sciences Term Semester 2 Level Postgraduate Coursework Location/s North Terrace Campus Units 15 Contact Up to 6 hours per week Available for Study Abroad and Exchange Y Prerequisites PHYSICS 7565A Assumed Knowledge Completed undergraduate degree in Physics or equivalent Restrictions Available to M. Philosophy in Physics & Astrophysics students only Course Description This course covers a range of advanced topics in physics, the methods of presentation and assessment of which vary according to module. Students enrolled in this course select three of the following modules (and not already undertaken as part of the course PHYSICS 7565A `M. Philosophy Physics A') : Advanced Astrophysics, Advanced Atmospheric Physics, Electrodynamics, Fourier Techniques and Applications, Gauge Field Theories, General Relativity, Non-Linear Optics, Nuclear And Radiation Physics, Quantum Field Theory and Relativistic Quantum Mechanics & Particle Physics. Students may be given permission by the Postgraduate Coordinator to substitute equivalent modules offered within the Faculty of Sciences and the Faculty of Faculty of Engineering, Computer & Mathematical Sciences.
Students should consult the Postgraduate Coordinator regarding the selection of modules.
Course Coordinator: Dr Rodney Crewther
The full timetable of all activities for this course can be accessed from Course Planner.
Course Learning Outcomes
1. demonstrate a detailed physical and mathematical understanding of a variety of systems and processes in a range of advanced topics in physics;
2. apply the concepts and theories of a range of advanced topics in physics;
3. demonstrate specialised analytical skills and techniques necessary to carry out advanced calculations in a range of advanced topics in physics;
4. approach and solve new problems in a range of advanced topics in physics;
5. demonstrate an understanding of the close relationship between scientific research and the development of new knowledge in a global context;
6. undertake independent research in a physical or mathematical field.
University Graduate Attributes
This course will provide students with an opportunity to develop the Graduate Attribute(s) specified below:
University Graduate Attribute Course Learning Outcome(s) Knowledge and understanding of the content and techniques of a chosen discipline at advanced levels that are internationally recognised. 1, 2, 3, 4 The ability to locate, analyse, evaluate and synthesise information from a wide variety of sources in a planned and timely manner. 2, 3, 4 An ability to apply effective, creative and innovative solutions, both independently and cooperatively, to current and future problems. 2, 3, 4, 5, 6 Skills of a high order in interpersonal understanding, teamwork and communication. 5, 6 A proficiency in the appropriate use of contemporary technologies. 3 A commitment to continuous learning and the capacity to maintain intellectual curiosity throughout life. 5, 6 A commitment to the highest standards of professional endeavour and the ability to take a leadership role in the community. 5, 6 An awareness of ethical, social and cultural issues within a global context and their importance in the exercise of professional skills and responsibilities. 5
Learning & Teaching Activities
Learning & Teaching Modes2 hours of lectures per module per week
The information below is provided as a guide to assist students in engaging appropriately with the course requirements.
A student enrolled in a 3 unit course, such as this, should expect to spend, on average 12 hours per week on the studies required. This includes both the formal contact time required to the course (e.g., lectures and practicals), as well as non-contact time (e.g., reading and revision).
Learning Activities Summary
Ø Advanced Astrophysics
- Fundamentals of Radiative Transfer and Scattering
- Interstellar Hydrogen, the Violent ISM and Star Formation
- Cosmic Ray and Gamma-ray Observations and Techniques
- Astrophysical Neutrinos
- Radiation by Accelerated Charge and Relativistic Bremsstrahlung
- Synchrotron and Inverse Compton Radiation
- Cosmic Ray Diffusion and Acceleration
- Relativistic Doppler Factor and Active Galactic Nuclei
- Thermal Bremsstrahlung
- Attenuation of photons in the Universe
Ø Advanced Atmospheric Physics
- Introduction to Planetary Atmospheres
- Radiation and Radiative Transfer
- Atmospheric Dynamics and the Role of Waves
- Ionospheric Physics
- Inhomogeneous wave equations
- Propagation issues
- Scattering and radiation reaction
Ø Fourier Techniques and Applications
- One-dimensional FT and applications, including convolution and wavelets
- Two-dimensional FT and applications, including diffraction and antennas
- Three-dimensional FT and applications to weak scattering
- Heat Conduction and Diffusion
Ø Gauge Field Theories
- Principles of Gauge Invariance
- Gauge invariance in Abelian gauge field theories
- Group theory in particle physics
- U(1) gauge group
- Internal symmetries
- Special unitary groups SU(n), SU(2)
- Gauge invariance in non-Abelian gauge field theories
- Gauge invariance and geometry
- Functional methods
- Path integral quantization and gauge theories
- Generating functional methods
- Non-Abelian gauge fields and the Fadeev-Popov method
- Massive gauge bosons: Spontaneous breaking of gauge symmetry
- Higgs mechanism
- Electroweak unification and the Standard Model
- Electroweak interactions
- CKM matrix
- Perturbation theory
- Regularization and renormalization procedure
Ø General Relativity
- Special Relativity - Review
- Principle of Equivalence
- Classical Field Theory
- Stress-Energy Tensor
- Differential Geometry
- Curved Space-Time
- Einstein's Theory of Gravitation
- Schwarzschild Metric
- Introduction to Cosmology
Ø Non-Linear Optics
- Introduction: Overview and review of nonlinear optics.
- Wave equation description of NLO: Second Harmonic Generation, phase matching,
- Second, Third and higher order
- Intensity dependent index of refraction, general tensor formulation of susceptibility.
- Nonlinear optical processes: intensity dependent index
- Semiconductor and molecular nonlinearities
- Inelastic nonlinear optical processes: Stimulated Raman, Brillouin etc.
- Optical Phase conjugation
- Nonlinear Fibre Optics: Fibre Fundamentals: overview of basic fibre concepts, types, properties and applications. Photonic Crystals: concepts, 1- 2- and 3-dimensional photonic crystals, Fibre Bragg Gratings
- Optical Glasses: concepts, optical and thermal properties, fabrication,
- Microstructured Fibres: guidance mechanisms, optical properties, fabrication and applications, Nonlinear fibre devices based on microstructured fibres: review of operation of a range of devices
- Thermonuclear laser fusion
- Quantum optics, quantum cryptography
Ø Nuclear And Radiation Physics
- Nuclear Physics
- Nuclear Reactions
- Radiation Physics
Ø Quantum Field Theory
- Classical Field Theory
- Field Quantisation
- Invariant Functions
- Fermion Fields
- Interacting Theories
- Introductory Quantum Electrodynamics
- Cross Sections and Decay Rates
Ø Relativistic Quantum Mechanics & Particle Physics
- Relativistic Quantum Mechanics
- Particle Physics
The University's policy on Assessment for Coursework Programs is based on the following four principles:
- Assessment must encourage and reinforce learning.
- Assessment must enable robust and fair judgements about student performance.
- Assessment practices must be fair and equitable to students and give them the opportunity to demonstrate what they have learned.
- Assessment must maintain academic standards.
Assessment task Type of assessment Percentage of total assessment for grading purposes #
Yes or No #
Objectives being assessed / achieved Assignments Formative & Summative 30% - 100% * No 1 – 6 Written Exams Summative 0% - 70% * No 1 – 6
Assignments: (30%-100% of total course grade) *
Depending on the modules selected, assignments constitute 30% to 100% of the total course grade.
The standard assessment consists of 2 assignments per module or 3 assignments if there is no written exam (8 to 12 assignments in total). This may be varied by negotiation with students at the start of the semester.
Assignments are used during the semester to address understanding of and ability to use the course material and to provide students with a benchmark for their progress in the course.
Written Examination: (0%-70% of total course grade) *
Depending on the modules selected, written exams constitute 0% to 70% of the total course grade (1 exam per module, up to 3 exams in total). Written exams are used to assess the understanding of an ability to use the material covered in modules during the semester.
* Assignment and examination weighting depends on modules selected by students.
Final result and grade
The final result for this course will be combined to the final result of PHYSICS 7565A ‘M. Philosophy Physics A’ and the appropriate grade will be awarded (after 15 units of study).
SubmissionIf an extension is not applied for, or not granted then a penalty for late submission will apply. A penalty of 10% of the value of the assignment for each calendar day that the assignment is late (i.e. weekends count as 2 days), up to a maximum of 50% of the available marks will be applied. This means that an assignment that is 5 days late or more without an approved extension can only receive a maximum of 50% of the marks available for that assignment.
Grades for your performance in this course will be awarded in accordance with the following scheme:
M10 (Coursework Mark Scheme) Grade Mark Description FNS Fail No Submission F 1-49 Fail P 50-64 Pass C 65-74 Credit D 75-84 Distinction HD 85-100 High Distinction CN Continuing NFE No Formal Examination RP Result Pending
Further details of the grades/results can be obtained from Examinations.
Grade Descriptors are available which provide a general guide to the standard of work that is expected at each grade level. More information at Assessment for Coursework Programs.
Final results for this course will be made available through Access Adelaide.
The University places a high priority on approaches to learning and teaching that enhance the student experience. Feedback is sought from students in a variety of ways including on-going engagement with staff, the use of online discussion boards and the use of Student Experience of Learning and Teaching (SELT) surveys as well as GOS surveys and Program reviews.
SELTs are an important source of information to inform individual teaching practice, decisions about teaching duties, and course and program curriculum design. They enable the University to assess how effectively its learning environments and teaching practices facilitate student engagement and learning outcomes. Under the current SELT Policy (http://www.adelaide.edu.au/policies/101/) course SELTs are mandated and must be conducted at the conclusion of each term/semester/trimester for every course offering. Feedback on issues raised through course SELT surveys is made available to enrolled students through various resources (e.g. MyUni). In addition aggregated course SELT data is available.
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