Bachelor of Advanced Science
Minimum number of credit points for the degree | 72 |
Minimum number of credit points at 200 level or above | 42 |
Minimum number of credit points at 300 level or above | 18 |
Completion of a Qualifying Major for the Bachelor of Advanced Science | |
Completion of a designated People unit | |
Completion of a designated Planet unit | |
Completion of a designated PACE unit | |
Completion of other specific minimum requirements as set out below |
In order to graduate students must ensure that they have satisfied all of the general requirements of the award.
Astronomy and Astrophysics
ADSC05V3
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100 level
200 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Biology
ADSC10V1
Specific minimum requirements:
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100 level
300 level
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Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Biomolecular Sciences
ADSC11V1
Specific minimum requirements:
Credit points
100 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Chemistry
ADSC12V1
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100 level
300 level
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TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Mathematics
ADSC06V3
Specific minimum requirements:
Credit points
100 level
200 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Palaeobiology
ADSC13V1
Specific minimum requirements:
Credit points
100 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Physics
ADSC04V3
Specific minimum requirements:
Credit points
100 level
200 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Software Technology
ADSC07V3
Specific minimum requirements:
Credit points
100 level
300 level
Additional
Balance of credit points required:
TOTAL CREDIT POINTS REQUIRED FOR THIS PROGRAM
Qualifying Majors for the Bachelor of Advanced Science
Additional Information
AQF Level | Level 7 Bachelor Degree |
CRICOS Code | 067843C |
Overview and Aims of the Program | Astronomy and Astrophysics In this major we develop a quantitative interpretation of the Universe and the underlying physical processes within it. The quantitative interpretation begins with observational astronomy – the process of measuring the Universe with particular emphasis on detecting electromagnetic radiation throughout its spectrum. In order to understand what this radiation means, the Advanced Science: Astronomy and Astrophysics major includes the study of radiative transfer: the way in which light propagates through and interacts with matter. From both an observational and theoretical perspective, we study the astrophysical processes that govern the formation and evolution of stars, planets and galaxies, including the structure of our own Galaxy. An essential part of developing this understanding is a solid background in physics and mathematics, including topics such as mechanics, electromagnetic radiation and differential equations. This knowledge development is complemented by hands-on laboratory experiments, collection of astronomical imaging and spectroscopic data, and computer-based analysis. Biology The Advance Biology Major is for exceptional students and provides face to face weekly tutorials with active research scientists to discuss key contemporary issues in biology. The Advanced Biology Major offers two units in addition to the requirements for the Biology Major. All students undertake at least one internship to gain hands-on research experience in biological science. The Biology Major offers a comprehensive education in a wide range of biological disciplines, spanning molecules to ecosystems and the biosphere, and terrestrial, marine and freshwater biomes. Throughout the major, structure and function are linked with processes that influence organismal evolution and ecology. Model systems range from microbes to fungi, plants and animals. The philosophy is of learning by doing, with a focus on the development of practical and problem-solving skills. Units take advantage of the university’s bushland setting by frequently offering opportunities for field experience. We have a particular focus on Australia’s unique biodiversity and the processes that have given rise to it. Key features of the major: • face to face discussions with active researchers • workplace experience in the form of an internship • emphasis on research ready graduates. Biomolecular Sciences The Biomolecular Sciences specialisation of the Advanced Science degree is suitable for students wishing to explore how molecules influence the structure and function of living biological systems. Biomolecular Sciences is based on biochemistry and molecular biology and extends into the fields of genetics, genomics and proteomics, biotechnology, structural, systems and synthetic biology, and bioinformatics. In this Advanced Science degree, students will develop problem-solving skills, independent and critical thinking, and be exposed to cutting edge research. Designed for gifted and talented students, this elite program has a strong research focus that provides the flexibility of a Bachelor of Science, plus advanced units that are not available to other students. Students will gain theoretical knowledge and practical experience in a range of relevant subject areas, including biochemistry, biotechnology, cellular biochemistry, genetic engineering, genomics, microbiology, molecular analysis, molecular biology, molecular structures, proteomics and synthetic biology. Students will have direct contact with researchers and academics and their skills will be nurtured with individual attention in a small select advanced science group. Students will also have the opportunity to undertake their own research project in third year, and gain practical experience in research laboratories and research groups using state-of-the-art instrumentation and approaches. An Advanced Science Degree with a specialisation in Biomolecular Sciences offers a path into many bioindustries including those engaged in medical research, pharmaceuticals, diagnostics and biotechnology and provides an excellent foundation for postgraduate studies including medicine. Students can also combine the Biomolecular Sciences specialisation with a range of related disciplines including chemistry, biological sciences and physics. Key features: • Significant research content delivered by teachers who are recognised nationally and internationally for their research. • Practical experience in undergraduate teaching laboratories that are among the best equipped in Australia. • Apply for summer vacation scholarships to work on research projects. • Excellent foundation for postgraduate studies, including higher degree research. Chemistry Chemistry is the science of analysing, transforming or manipulating substances and the molecular interpretation of the world around us. It is concerned with the study of the interactions of matter and energy. One of the main functions of the chemist is to produce new substances or to understand how substances are formed and removed in the environment. Chemistry has an important effect on our economy by playing a vital role in developing new technologies and influencing all human activity. The Advanced Science Degree with a Major in Chemistry develops work- and research-readiness for our graduates. The practice of Chemistry, synthesis and analysis, is taught through a combination of theory, practice and authentic experience, encompassing coursework, laboratory exercises, work and research-laboratory placements. The specialist units for the Advanced Science program provides the opportunity to engage with academic staff in investigations of cutting-edge chemistry and for authentic research experiences in research laboratories. Mathematics The study of Mathematics at Macquarie features a modern, balanced curriculum, designed to provide a sound foundation for a future career or further study in any of the major branches of Mathematics, drawn together in a way that ensures that each aspect of the curriculum takes full advantage of the insights and perspectives of traditional pure and applied approaches to the study of mathematics. In addition to this, the Advanced Science award features a specialist advanced unit in each year of study, extending the undergraduate curriculum to allow early access to areas which are at the forefront of current mathematical research, together with the opportunity to engage in their own mentored research experience working closely with faculty members who are internationally recognised as leaders in their field, through the Mathematics Department's Vacation Research Scholarship program. The Bachelor of Advanced Science - Mathematics award is fully accredited by the Australian Mathematical Society. Palaeobiology The main aim of the Palaeobiology Major is to provide students with a “deep time” perspective to the evolution and history of life on Earth. By studying the fossil record, students will learn more about the evolutionary relationships of animals and plants, the timing and correlation of important events in deep time, and explore fundamental questions related to fluctuating ecological and environmental parameters through time. Coverage includes a broad survey of important invertebrate and vertebrate fossil groups, study of evolutionary processes as revealed by the fossil record, investigation of reef evolution through time (includes a field excursion to the GBR), application of fossils to reconstruct past environments, climates and behaviours, and the various ways that fossils can be used as tools to solve geological and biological problems. The melding of palaeobiology with evolutionary biology, genetics and developmental biology allows students to explore the new discipline of ‘evo-devo’ which seeks to determine the ancestral relationship between organisms and understand how developmental processes evolved. Physics Physics is the quantitative study of Nature at all scales, from elementary particles to the large spacetime structure of the Universe. It encompasses both the search for the most fundamental laws of Nature down to the subatomic level, and emergent phenomena in complex systems, such as material or biological systems. Physics is one of the oldest academic disciplines, and it remains today both an exciting field at the frontier of knowledge and a fundamental underpinning of all science and technology. An undergraduate degree in advanced science: physics is generally recognised to be good training for a broad range of careers. It not only prepares students for graduate studies in physics and astrophysics, but when combined with appropriate courses in other disciplines it provides excellent preparation for a career, including biophysics, chemistry, engineering, geophysics, industrial research, finance, teaching and education, policy, medicine or law. Software Technology The Software Technology specialisation of the Advanced Science degree is suitable for students who wish to pursue a career designing and delivering complex software. The emphasis in all units is on concepts, insights and skills that enable graduates to use current technologies and also evaluate and adapt to new technologies as they emerge. Central to the learning of the conceptual material is extensive practical experience where complex problems are analysed, solutions designed, and software developed, both individually and in groups. Students will undertake a range of core units that introduce the technologies of modern software development and the practices that result in successful software projects. Elective units supplement the core by considering important application areas in software and/or systems or domain-specific technologies. Designed for gifted and talented students, this elite program has a strong research focus that provides the flexibility of a Bachelor of Science, plus advanced units that are not available to other students. Students will gain theoretical knowledge and practical experience in a range of relevant subject areas. |
Graduate Capabilities | The Graduate Capabilities Framework articulates the fundamentals that underpin all of Macquarie’s academic programs. It expresses these as follows: Interpersonal or social capabilities |
Program Learning Outcomes | By the end of the Bachelor of Advanced Science - Astronomy and Astrophysics it is anticipated you should be able to: 1. demonstrate knowledge of fundamental physics concepts and principles at an advanced level (K) 2. evaluate the role of theoretical models, numerical and empirical studies in development of physics knowledge (K, T, E) 3. demonstrate a creative approach to problem solving by independently identifying and applying core physical principles and relevant mathematical and computational techniques (k, T, P, I) 4. design an activity or experiment to test a physical hypothesis (I, C) 5. complete independent research projects in the area of astronomy or astrophysics and present outcomes before peers and lecturers (K, P, C, J) 6. use a range of measurement tools and methodologies to collect data (K, T) 7. use a range of data analysis tools to analyse measurements with due regard to uncertainties (K, T, P) 8. communicate physical ideas using appropriate language and conventions (K, C) 9. demonstrate capacity for effective, responsible and safe work practices as an individual or in a team (E, J, A) 10. demonstrate an understanding of the emission properties of gas with different physical conditions (ionized, neutral or molecular), whether permeated by magnetic fields or not, and of solid matter (dust) (K, T) 11. link emission properties of gaseous and dusty environments to our ability to observe them at different electromagnetic wavelengths and with different observational platforms and techniques (K, T) 12. identify the role of key physical conservation laws in the structure and life cycle of stars (K, T) 13. describe the structure and evolution of galaxies (K) 14. manipulate one and two dimensional data sets (including spectra and images) using astronomical packages (K, P) 15. manipulate equations describing physical principles, using mathematical techniques, to provide an analytical description of an astrophysical problem (K, T, P) 16. write custom computer programs to solve astrophysical problems (K, I) 17. exhibit intellectual integrity and practice ethical conduct (E). By the end of the Bachelor of Advanced Science - Biology it is anticipated you should be able to: KNOWLEDGE AND UNDERSTANDING 1. have a broad working knowledge of key contemporary topics in biology (K) 2. explain the theory of evolution and why it can be regarded as the central unifying concept in biology (K) 3. compare and contrast the form and function of key biological units at sub-cellular to ecosystem scales (K) 4. explain how processes operating at a hierarchy of temporal and spatial scales give rise to the phenotypes of individuals, populations, communities and ecosystems (K) 5. describe key features of the Australian biota and the processes that have given rise to these (K) 6. evaluate historical developments in biology, as well as current and contemporary research directions and challenges (K, T, J, L) SKILLS AND CAPABILITIES 7. make inferences by drawing on evidence from a range of disciplines and test novel hypotheses using interdisciplinary approaches (K, T, P, I) 8. develop hypotheses to explain biological patterns and processes and design appropriate experiments to test these (K, T, P, I, J) 9. display competence in using key laboratory and/or field methods in a range of disciplines (K, P) 10. acquire, synthesise, and statistically analyse data (K, T, P) 11. identify instances where biology can contribute to public debate, and critically evaluate biology as communicated in the public sphere (T, E, J) 12. clearly and accurately communicate biological problems and solutions to scientists and the public, using written, oral and digital media (C, E, A, J) 13. practice professional ethics in the conduct of biology (E, A) 14. identity and adopt safe work practices in laboratory and field environments (E, A) 15. display skills in leadership, group management, co-operation and teamwork (C, E, A, J). By the end of the Bachelor of Advanced Science - Biomolecular Sciences it is anticipated you should be able to: KNOWLEDGE AND UNDERSTANDING 1. demonstrate an understanding and a solid foundation in the Biomolecular Sciences, as well as a broad background in biological chemistry (K) 2. apply key Biomolecular Science concepts to make the connection between molecular properties, cellular activities and biological responses (K, A) 3. demonstrate well-developed knowledge in at least two disciplinary areas of biomolecular sciences (biochemistry, molecular biology, biotechnology, medicinal chemistry, microbiology, structural biology) (K) 4. identify, analyse and solve problems in the Biomolecular Sciences by gathering and critically evaluating information from a range of sources (A, P) 5. demonstrate knowledge and awareness of the ethical, regulatory and safety frameworks relevant to the Biomolecular Sciences (E, S) 6. demonstrate a broad knowledge necessary to understand and respond to the impact of Biomolecular solutions in a global and societal context (E, S, L). SKILLS AND CAPABILITIES 7. demonstrate the ability to engage in structured research by recording, analysing and critically interpreting experimental data. This includes successfully identifying the need for experiments, experimental design and conducting of experiments (A, P) 8. design and conduct a research project, under the guidance of a faculty member, including data collection, evaluation and presentation in a written paper format (A, P, I) 9. communicate ideas in contemporary biomolecular sciences through written and visual modes, and through discourse with peers and mentors (T, P, I, C) 10. integrate knowledge to define a problem, formulate a hypothesis, and design and plan an investigation (A, P, I) 11. select and apply appropriate contemporary practical tools and/or theoretical techniques to conduct an investigation (K, P) 12. translate an understanding and knowledge of ethical and regulatory frameworks in the experimental design and decision making process (E, J) 13. effectively communicate key biomolecular science concepts and scientific results in both written and oral form to a variety of audiences. Be able to effectively present data, and clearly and concisely answer questions (C, J) 14. demonstrate an ability to work effectively, responsibly and safely; both independently and as member of a research team (J, P, E, C). By the end of the Bachelor of Advanced Science - Chemistry it is anticipated you should be able to: 1. exhibit broad knowledge of the principles and concepts of chemistry (K, P) 2. apply your knowledge of chemistry to theoretical and practical problems and tasks (K, P) 3. investigate and solve qualitative and quantitative problems in the chemical sciences, both individually and in teams (K, T, P) 4. undertake authentic research, to an introductory level, within the context of a research laboratory (K, T, P, I, E) 5. communicate ideas in contemporary chemistry through written and visual media modes, and through discourse with peers and mentors (T, P, I, C) 6. formulate hypotheses, proposals and predictions (K, T, P, I) 7. design and undertake experiments in a safe and responsible manner (K, T, P, I, E) 8. apply recognised methods and appropriate practical techniques and tools, and be able to adapt these techniques when necessary (K, T, P, I, J) 9. collect, record and interpret data and incorporate qualitative and quantitative evidence into scientifically defensible arguments (K, T, P, I, C) 10. synthesise and evaluate information from a range of sources, including traditional and emerging information technologies and methods (T, P, I, C) 11. communicate chemical knowledge through appropriate documentation of the essential details of procedures undertaken, key observations, results and conclusions, and present information with articulate arguments and conclusions, in a variety of modes, to diverse audiences, and for a range of purposes (K, T, P, I, C, J) 12. demonstrate the testable and contestable nature of the principles of chemistry (K, T, I, C) 13. express your understanding of the place and importance of chemistry in the local and global community (C, E, A, J) 14. prove professional and social responsibility by conducting yourself in the relevant and required ethical manner which chemistry is practised, and demonstrate a capacity for self-directed learning (C, E, A, J). By the end of the Bachelor of Advanced Science - Mathematics it is anticipated you should be able to: 1. demonstrate a well-developed knowledge and sophisticated understanding of the principles, concepts and techniques of a broad range of areas in algebra, analysis and applied mathematics, with significant depth in several areas of current mathematics research (K, C, T) 2. demonstrate a well-developed understanding of the breadth of mathematics, the multidisciplinary role of mathematics and the way it contributes to the development in other fields of study (K, L, J) 3. construct sustained logical, clearly presented and justified mathematical arguments incorporating deductive reasoning (K, T, P, I) 4. formulate and model practical and abstract problems in mathematical terms using a variety of methods drawn from algebra, analysis and applied mathematics (K, P, T) 5. apply mathematical principles, concepts, techniques and technology efficiently to develop novel techniques to solve practical and abstract problems across a range of areas in algebra, analysis and applied mathematics (K, T, P, I) 6. appropriately interpret mathematical information communicated in a wide range of forms (K, T, C, J) 7. present mathematical ideas, information, reasoning and conclusions in forms tailored to the needs of diverse audiences (K, T, I, J, C) 8. identify and appropriately address ethical issues arising in professional mathematical work; demonstrating a high level of awareness of ethical responsibility and professionalism in all aspects of mathematical practice (K, C, E, A, J) 9. work effectively, responsibly and safely in individual and team contexts (C, E, J). By the end of the Bachelor of Advanced Science - Palaeobiology it is anticipated you should be able to: KNOWLEDGE AND UNDERSTANDING 1. have a deep understanding of the principles of palaeobiology and how fossils are used to determine the history of life on earth 2. be able to identify the major morphological features of the most important invertebrate and vertebrate phyla in the fossil record 3. be able to describe the various applications fossils have for solving important biological, ecological, environmental and geological problems 4. have a solid grasp of the principles of biostratigraphy, functional morphology, palaeoenvironmental reconstruction, taxonomy and palaeoclimatic interpretation 5. understand the principles and techniques of scientific methodology and communication through group discussion, debate and written assignments. investigate the origins, radiation, biodiversity trends and evolutionary relationships of the dominant invertebrate and vertebrate groups in the fossil record 6. utilise quantitative and qualitative scientific methods and techniques to evaluate a diverse range of multidisciplinary topics including: reef formation and structure, reef zonation, carbonate sedimentology, biodiversity, ecology, taxonomy, taphonomy, symbiosis, recruitment, bioturbation and bioerosion, human impacts on reef systems and global warming 7. outline the evolution and importance of reef formation in the geological record. Especially important here is that students will be able to describe the changes associated with the evolution of reefs through geological time 8. learn how to conduct and interpret cladistic and cluster analyses and interpret phylogenetic data SKILLS AND CAPABILITIES 9. analyse trends and patterns of fossil data utilizing new software techniques in order to explore applied theory 10. become familiar with the morphological features of key invertebrates and use this knowledge to interpret function, life habits and behaviour 11. utilise data from the Paleobiology Database to analyse and interpret origination, radiation and extinction patterns throughout the Phanerozoic (0-542 Ma) 12. demonstrate ability to utilize empirical data based on fossil material using specific and general software to investigate evolutionary trends and fluctuations 13. understand principles and gain skills in using bioinformatics and databases in evolutionary and phylogenetic research 14. skills and capabilities to interpret and utilse palaeobiological data to investigate a broad range of topics including applied palaeontology, functional morphology, macroevolution, invertebrate palaeontology and evolution, palaeobiogeography, conservation palaeontology, palaeoecology, phylogeny, reef evolution and dynamics, stratigraphic and biostratigraphic principles, taphonomic analyses, taxononomy and cladistics 15. demonstrate ability to find and utilise relevant information contained in the primary scientific literature 16. be able to formulate your own ideas, opinions and conclusions based on data presented in the primary scientific literature. By the end of the Bachelor of Advanced Science - Physics it is anticipated you should be able to: 1. demonstrate knowledge of fundamental physics concepts and principles at an advanced level (K) 2. demonstrate knowledge of mathematical concepts and methods at an advanced level (K) 3. evaluate the role of theoretical models, numerical and empirical studies in development of physics knowledge (K, T, J) 4. demonstrate knowledge of statistical principles behind physics (K) 5. demonstrate a creative approach to problem solving by independently identifying and applying core physical principles and relevant mathematical and computational techniques (K, T, P, I) 6. design an activity or experiment to test a physical hypothesis (K, T, P, I) 7. complete independent research projects and present outcomes before peers and lecturers (P, T, I, C) 8. use a range of measurement tools and methodologies to collect data (K, T, P) 9. use a range of data analysis tools to analyse measurements with due regard to uncertainties (K, T, P) 10. critique science-based arguments and communicate physical ideas using appropriate language and conventions (T, P, C) 11. demonstrate capacity for effective, responsible and safe work practices as an individual or in a team (K, E, A, J) 12. exhibit intellectual integrity and practice ethical conduct (E). By the end of the Bachelor of Advanced Science - Software Technology it is anticipated you should be able to: 1. use modern software technologies to analyse, design, create and evaluate complex software (K, T, P, I, C) 2. understand and apply concepts and techniques of software development such as algorithm and data structure design, object-oriented practices, low-level systems programming, and database-centred design (K, T, P, I, C) 3. understand and apply the mathematical concepts and techniques that underpin the development of software (K, T, P, C) 4. have a significant breadth of experience in the application of software to solve problems in a variety of domains (K, T, P, I, C) 5. conduct a software-based project applying industry-standard software development methodologies and practices, including as part of a team (K, T, P, I, C , J) 6. understand the ethical issues that arise in software development and apply standard approaches for reasoning about ethical issues that arise in the software development profession (K, T, P, E, J) 7. develop individual experience in scoping a significant research project (K, T, P, I, C, J) 8. develop research management skills which will be dependent upon the particular research area chosen, but students will manage a small research project and see it through to completion (K, T, P, I, C, J). |
Learning and Teaching Methods | Astronomy and Astrophysics In this program you will build your fundamental technical skills in experimental and theoretical physics and astronomy and develop understanding of their methodology, relationship with other disciplines and technological applications. Most of the units are comprised of three structured learning activities: lectures, tutorials and guided laboratory exercises. Lectures are where theoretical ideas and experimental and mathematical techniques are introduced and illustrated by a range of illustrative examples. They provide opportunities for discussion and active engagement, and as your studies progress will draw not only on textbooks and online learning materials, but involve exposure and interaction with the current research. Tutorials both demonstrate concrete applications of techniques introduced in lectures, and provide training ground for students for their application. Tutorials typically involve a mixture of individual and group work with guidance and assistance from the tutors. Laboratory work is an indispensable part of physics and astronomy education. You will acquire familiarity with experimental methods and practices that both illustrate the theoretical concepts that are presented in lectures and facilitate development of practical research skills. Laboratory work is the first setting where students will learn to work collaboratively, and preparation of reports from practical exercises provides you with valuable training in communicating scientific results. Mastering effective communication is a major component of all learning activities. Apart from the laboratory reports and problem-solving assignments you will prepare oral and written presentations and/or essays of their research and study projects. From the first year you will be engaged in collaborative work, both in tutorials and laboratories. With your study progression you become exposed to less structured activities, such as individual or group-based research projects, and formal and informal presentations. There are many instances of blended learning activities, including combinations of online and face-to-face modes, or group and/or one-to-one activities. The program prescribes People, Planet units and allows for Professional engagement, such as a PACE unit. During your study you will take one of the designated People units (in the areas of social sciences, business or arts) and one Planet unit (experiencing a different area of science). Toward the end of the program the Capstone unit of study allows you to integrate your skills and knowledge, applied to real-life problems through a research project conducted at an external partner institution. An annual careers evening is held where graduates of the program return to share their experiences with current students preparing to go out into industry, academic or government employment. Biology Advanced Science (Biology) requires students to undertake a standard Biology degree and two additional units (Biol 188 and 388). The learning and teaching methods of these two units are specifically designed to encourage critical thinking while addressing a broad range of hot topics in biology. The small group size and direct contact with active researchers from a broad range of disciplines during weekly tutorials ensures the students are constantly confronted with cutting edge research and novel ideas. Because of the broad experiences, students are effectively trained to think across disciplines. There is an additional emphasis on creating research-ready students since all students must undertake at least one internship in an active scientific laboratory. The choice of internship location is entirely driven by the individual interests of students and there are examples of students working in labs and in the field all over the world. Biol 388 is a listed PACE unit so students enrolled in this subject also gain active support from the PACE office when organising their internships. To qualify the students must be able to demonstrate that the internship will provide them with scientific training but also provide a benefit to the host institution. There is an emphasis on science communication which is exemplified through the weekly discussions, through lab placements and ultimately when they present both written and oral reports. The units are only available internally because of the emphasis on face to face contact with researchers during tutorials. These methods are in addition to those in the general biology degree (below). The Biology Major is taught using approaches that integrate the teaching and research environments. Our units: (1) provide students with an authentic research experience; (2) utilise problem-based learning activities; and (3) embed cutting-edge research in the curriculum. Most units combine theoretical and practical aspects, building competency in both discipline specific skills and knowledge, and in graduate capabilities, such as problem-solving and communication skills. At first year level, students are introduced to the scientific method. At second year level, students design and test their own simple scientific research questions under staff guidance. At third year level, students are given opportunities to develop and test more complex research questions. Theoretical elements may be taught using a combination of lectures, tutorials, workshops and online activities. Practical components may involve laboratory-based sessions, field trips to locations at and around campus, the Sydney Basin, and further afield, as well as role-play scenarios and problem-solving in tutorial sessions. In recognition that students learn via different means (i.e. visual, auditory, tactile), many of our units take advantage of a diversity of media for their delivery (e.g. videos, lectures, readings, activities). Our philosophy is that students learn by doing and we endeavour to make our units as hands-on as possible. The Biology Major is offered in external as well as internal mode. This means that for many units, instead of attending weekly practicals, students can opt to cover these in block over several weekends. Furthermore, many of the theoretical aspects can be completed on-line in lieu of lecture attendance. NOTE: the external offering is designed to maximize flexibility, but does not eliminate the face-to-face component. Biomolecular Sciences In this program you will be given the opportunity to gain theoretical knowledge and practical experience in the Biomolecular Sciences through a variety of independent and collaborative activities. For the majority of units within this program, lectures will be used to introduce the concepts of Biomolecular sciences. Laboratory sessions are used to both complement the lecture material and provide practice in standard Biomolecular techniques used in research. Tutorials (and dry-lab workshops) are additionally designed to reinforce the concepts presented in lectures and practiced in the laboratory but in a smaller peer learning environment. Formal peer-assisted learning (PAL) is also offered in some units. In general, in the first year of the program you will build on your foundation of knowledge in the biological and chemical sciences. In the second year, you will further develop your Biomolecular knowledge through the core disciplines of biochemistry, molecular biology and microbiology and receive further practical skills training in these areas. Towards the conclusion of your program, you will explore your chosen disciplinary areas within Biomolecular sciences by choosing from three specialisations (minimum) within the program. A central and dominant theme throughout your Biomolecular major program is the inclusion of research experience in the majority of units. Your program will culminate in the Biomolecular Sciences capstone unit where you will integrate your Biomolecular knowledge to define a problem, formulate a hypothesis, and design and plan your own scientific investigation. You will have the opportunity to present this research to an international audience through the participation in an international undergraduate research competition (such as the iGEM international Genetically Engineered Machine). In addition to developing skills to evaluate and critique the present scientific literature, the laboratory research experience forms an essential element of your scientific training throughout this program. Many of your laboratory sessions are also designed to provide you with hands on experience with a wide range of contemporary research equipment encountered in today’s modern Biomolecular science research facilities. Two special advanced units with a strong research focus form part of this advanced degree program (CBMS188 and CBMS389). You will also gain further practical experience working in research laboratories with a vacation research internship available between your second and third year of study. In addition, you will attend regular research-focused seminars and discussions with academic and research staff, exposing you to cutting-edge research. In this program, you will learn to effectively communicate Biomolecular science concepts and scientific results in various forms (written, oral, poster presentation) to a wide range of people, including your peers and the wider scientific community. Most activities will require you to present on your own or as a group and you will receive feedback on it. Chemistry In this program you will be given the opportunity to acquire and develop relevant subject skills, methods, knowledge and understanding of chemistry through a variety of independent and collaborative learning activities. You will engage in structured learning activities such as lectures, tutorials and guided laboratory exercises and you will also have the opportunity to engage in less structured activities such as open laboratory exercise (research projects in teaching and research laboratories), work placements, and formal and informal presentations. Learning activities include lectures, tutorials, one-to-one meetings, laboratory classes and personal study and investigations. There are many instances of blended learning activities, in which online and face-to-face modes are combined. Individual and group work undertakings are incorporated into the Major. You will complete assignments that will engage you in acquiring and presenting information from a variety of sources that include textbooks, reports, databases and articles from the research journals. In many cases, especially in practicals and tutorials you will work collaboratively with other students from this and other programs. You will learn to communicate effectively using a variety of media and techniques to a wide range of people. Most units of study will involve preparation of reports from practical exercises and the submission of assignments that may range from numerical calculations, essays, or the construction of physical objects. Within the major there is the opportunity to participate in the Professional and Community Engagement program through placements in the chemistry industry. Your assessment items will be assessed in a variety of methods, appropriate for the type of work, and feedback will be provided on the level of achievement and areas of improvement. In some units of study formal peer-assisted learning (PAL) is offered. In most units of study recent graduates of the program are employed as laboratory demonstrators and tutors. Toward the end of the program the Capstone unit of study allows you to integrate and exhibit your skills and knowledge in an integrative way. Mathematics Most mathematics units use lectures and tutorials (or practicals) as the main formal learning and teaching activities. Students are expected to read text books and other material to enhance their understanding, and to develop their understanding and skills through applying their newly acquired techniques and understanding to a wide range of exercises outside of the formal teaching times. • Lectures are where ideas, techniques and theory are introduced, and illustrated by a range of well chosen, illustrative examples. • Tutorials provide a context in which students are actively involved in applying the ideas and techniques introduced in lectures. Tutorials typically involve a mixture of individual and group work, with guidance and assistance from the tutor. Students also have opportunities to develop and practice their skills at explaining and presenting mathematical arguments and ideas. • Practicals are often a feature of early mathematics units; providing opportunities to explore a greater range of examples and to engage with the process of understanding how to approach the task of developing strategies to approach mathematical problems and developing the required insight to select appropriate mathematical techniques. Practicals typically involve an interactive discussion between a faculty member and students to develop solutions to questions related to material recently introduced in lectures. The three special units in this program, MATH188, MATH288 and MATH388 involve close collaboration between students and faculty members, with a mixture of formal lectures, individual research and reading and extended projects. Students in this program also have the opportunity to work on summer research programs with faculty members through the department's vacation scholarship program. Palaeobiology The fundamental tenets that underpin the teaching philosophy behind the Palaeobiology Major are to equip each student with the knowledge, technical skills, professionalism and confidence to gain employment and research capacity to succeed in their chosen field of endeavour. To achieve this, the specific aims of the major are to: • to introduce each student to the broad sweep of the history of life on Earth by focusing on the functional morphology, evolution and extinction, palaeoecology, biostratigraphy, and palaeobiogeography of the most important and informative invertebrate and vertebrate fossil groups, • provide an introduction to some of the applied aspects of life, earth and marine sciences, using relevant examples from current or recent research investigations, • provide first-hand experience of fossil material in the lab and field using cutting edge quantitative and qualitative scientific methods and techniques, • enthuse and encourage students to undertake independent critical scientific thought by using a combination of generic and specialists skills required by all scientists and how to think and express themselves “scientifically”. The Palaeobiology Major is taught by academics with expertise in the research and teaching of palaeobiology (the history of life), palaeoecology, marine science and quantitative palaeobiology. All students undertaking the major gain broad experience and knowledge in each subject, and are exposed to innovative problem-based learning techniques, group-based work, a mixture of seminars and poster presentations, online workshops and written assignment work based on synthesis and critical evaluation directly from the primary scientific literature. The Major has been designed so that all students gain broad experience and knowledge in each unit and are exposed to a wide variety of teaching techniques. All units are available online and are offered on campus or by Distance Education (external study) on an annual basis. Most units have a fieldwork component ranging from weekend excursions to eight-day intensive programs. All units incorporate significant proportions of research material in the form of case studies, workshops, and field programs. The units in the Palaeobiology Major provide a carefully planned pathway designed to include a mix of field-based learning, supplemented by relevant lectures and lab sessions with high quality specimens/materials that challenge each student to solve specific problems. Field based units at 300 level allows students to complete Independent Group Projects (IGPs) which are designed to challenge small groups of students to design, formulate, collect/observe/measure data in the field and/or lab and produce a logically organised written scientific report. This is perfect initial training for advanced undergraduates who might consider completing an MRes degree in the future. The structure of the major combines theoretical and practical aspects, building competency in both discipline specific skills and knowledge, and in graduate capabilities, such as problem-solving and communication skills. At first year level, students are introduced to the scientific method, at second year level students build their knowledge base in evolutionary and ecological principles, taxonomy of the major groups and palaeobiological techniques and applications that provide opportunities to delve into the cutting edge research streams in the discipline. At third year level, students design and test their own simple scientific research questions under staff guidance and develop and test more complex (often interdisciplinary) research questions. All units are offered using flexible delivery utilizing a diversity of media (e.g. videos, lectures, readings, activities). Our teaching methods also aim to help students to develop “soft skills”, by enhancing communication, tolerance and interpersonal relationships as well as encouraging discussion, debate and synthesis of available data. The students thus work in an environment (lab or field) that replicates how a team of scientists might interact in the workplace, whether private industry, government agencies or academia. The BAdvSci degree has one of the highest ATARs for a science program in Australia. On top if the specialized PalaeoMajor, students will complete special advanced units only available to other students inthis degree. Student numbers are restricted, allowing personal attention including an academic mentor throughout the degree and direct contact with researchers. Students have the opportunity to take part in research and gain practical experience in research laboratories and research groups. Physics Refer to the Astronomy and Astrophysics major above. In addition to the learning and teaching methods used in the Bachelor of Physics degree, the Bachelor of Advanced Science Physics degree involves three additional courses, one per year, that provide in depth coverage of fundamental concepts in physics. These concepts include but are not limited to: Classical Mechanics using Lagrangian and Hamiltonian dynamics, the role of symmetry and conservation laws in nature, classical field theory, probability theory, and stochastic processes. Software Technology The Major in Software Technology is designed to prepare graduates as IT professionals for work in industry, research organisations and academia. The program is intended to meet the Australian Computer Society professional standards for ICT courses which includes the underlying core body of knowledge in IT and the professional and ethical responsibilities relevant to working in the IT industry. In addition, this program in the Bachelor of Advanced Science offers students two special units in first and third year that involve them directly in the research activities of the Department. These offer a chance to interact with Computing academics and carry out a small research project. The learning activities in the degree are designed to provide opportunities for students to meet all of these standards. The academics involved with this program are active researchers, which enables them to integrate cutting-edge research into the units that they teach. The majority of the units in this program have practical components supported by small-group teaching sessions in our computing laboratories. Some units utilise small groups where students work in a team to achieve a goal. Communication skills are developed through oral presentations. The theoretical components of units are presented in lectures and develop the underlying theory, in addition to developing analytical and problem solving skills. All units have weekly face-to-face activities. Assignments are used for formative and summative purposes. As knowledge in IT is continually evolving, learning and teaching methods support the capacity for students to become independent learners. The major culminates with a Capstone unit that involves students being part of a small team assigned to an industry partner to carry out an industry relevant project. Students work autonomously under the guidance of academic staff and using industry staff as 'clients'. The project allows students to apply in an integrated manner the knowledge and skills they have developed in their studies on a substantial design, analysis or development problem. |
Assessment | Astronomy and Astrophysics Assessment tasks are intended both to measure individual progress and give feedback. They are based on the topics of the units of study and are provided in two forms: whilst you are working on a task and once you have completed a task. Both forms of feedback are important as they provide you with information and guidance on your development and progress. At least three different assessment methods are used in each unit. They include problem solving, laboratory work and reports, oral presentations, essays, active participation in lectures and/or tutorials, online and in-class quizzes, individual and group projects. Formal examinations are part of the assessment of the majority of units and involve solving of problems appropriate for the scope and level of the unit. The assessment in most physics and astronomy units includes regular assessment tasks, such as the submission of weekly/biweekly home assignments and/or in-class tests, designed to assist you in your learning development. Standards and criteria for coursework, what is assessed and how it is assessed, are contained in each unit guide or may be made available during classes. Assessment is undertaken by academic staff, demonstrators and tutors. In some cases peer assessment will contribute to the grade, and it may be done by people from outside the university, such as work placement supervisors or guest lecturers. Where group work is involved, a self-reflection and peer assessment/feedback in the form of contribution to the assessment task is incorporated into the requirements of the assessment so that your individual contribution can be identified. Biology There are multiple assessment tasks which emphasises the many skills the students are expected to gain during the degree. The first is engagement with the discussions during the weekly tutorials. The pre-reading provided means that students must be able to synthesis what they have read and then actively engage in discussion with an expert in the field and their peers. Secondly the students’ oral presentations are assessed by their peers and the Director during the annual Advanced Biology conference. They must also provide a written report, often in the form of a scientific paper, of their internship experience or write a review of a hot topic in biology. Their internships are assessed by the host whom provides feedback on all aspects of the internship (ranging from practical lab skills to social skills). Collectively assessment is very rounded and compliments the assessment tasks they receive during the rest of their biology degrees. These assessments are in addition to those in the general biology degree (below). Assessments in Biology are designed not only to test students’ discipline-specific knowledge and skills but also their ability to integrate and analyse information to solve real-world problems. Assessments are spread throughout semester to enable students to build confidence and gain feedback as they learn. In recognition that students learn and communicate in different ways, assessment methods are diverse, with at least three different types of assessment in every unit. Assessment methods include, but are not limited to, exams and quizzes, written assessments (such as scientific reports, grant proposals, critical essays and journals of learning), oral assessments (such as presentations, debates and discussions), and multi-media presentations (posters, videos, blogs). In addition to formal assessments, students are provided with regular informal feedback on their progress. This is done through activities that involve self- and peer-evaluation, as well as through our strong student support system of tutors and academic advisors. Biomolecular Sciences Assessment is made on the submission of individual and group coursework. In some units, a small component of the assessment is made from observations of student participation in laboratory or tutorial environments. Assessment types are diverse across units and may include written assessments (such as scientific reports, essays, project proposals, case studies, critique of the scientific literature) or oral assessments (such as seminars, debates, discussions) or multimedia presentations (such as scientific poster presentations, digital media presentations, blogs, wikis). Most units have a final examination which forms a significant part of the assessment of student achievement, and which is where a student’s ability to apply knowledge is assessed. All units have at least three different types of assessment. Clear standards and criteria for coursework, what is assessed and how it is assessed, are contained in each unit guide. The program incorporates formative and summative feedback. Formative feedback is that which is received whilst you are working on a task. Summative feedback is that received once you have completed a task. Both forms of feedback are extremely important and provide you with information and guidance on your development and progress. Feedback is mostly provided in written form and occasionally in discussion with peers, tutors and academic advisors. Chemistry Assessment is made on a variety of submitted materials and in some cases through observations of students by demonstrators and tutors. These assessments include submitted assignments (including online), in-semester tests, quizzes, practical reports, presentations and physical objects (e.g. samples, models). In the majority of units of study a final examination is included. The assessments are based on the topics of the units of study, and include the lecture and practical learning activities, and the readings or further study topics set by the lecturers. Assessment is undertaken by academic staff, demonstrators and tutors. In some cases, assessment may be made by other students (peer assessment) or people from outside Macquarie University, such as work placement supervisors or guest lecturers. Standards and criteria for coursework, what is assessed and how it is assessed, are contained in each unit guide or may be made available during classes. The program incorporates both formative and summative feedback. Formative feedback is that which is received whilst you are working on a task. Summative feedback is that received once you have completed a task. Both forms of feedback are important as they provide you with information and guidance on your development and progress. Feedback may be provided in written form or through discussion with peers and teachers. Mathematics Various assessment methods are used in the units that constitute the mathematics major. These includes problem solving, producing reports, oral presentations, active participation in lectures and/or tutorials, online quizzes, individual and group projects and formal examinations. Where group work is involved, a self reflection and peer assessment/feedback form on contribution of each student to the assessment task is incorporated into the requirements of the assessment so that individual contribution of each student can be identified. The assessment in most mathematics units includes a number of regular low-stakes formative assessment tasks, such as the submission of weekly tutorial exercises, designed to assist students in their learning development; in addition to a range of summative assessment tasks. Palaeobiology All assessment tasks in each of the core palaeobiology units are designed to test capacity and competency in discipline-specific knowledge and skills. Assessments are normally spread throughout semester to enable students to build confidence and gain feedback as they learn. Because the structure of the units is diverse, ranging from traditional weekly Lecture/Lab sessions to intensive blocks of learning at on-campus sessions or in the field (sometimes in remote locations), assessment strategies are spread across a wide spectrum. All units have at least 3 different types of assessment and these might include, but are not limited to: exams and online quizzes, written assessments (such as scientific evaluations, critical essays and comment and reply tasks), oral assessments (such as presentations, debates and discussion topics), peer review tasks, and multi-media presentations (posters, videos, blogs). Advanced Science students also attend weekly reserach focussed seminars and discussions with Academic and Research Staff, conduct a literature-based research project and produce a scientific based on Lab or vacation research projects. Physics Refer to the Astronomy and Astrophysics major above. In addition to the assessment methods used for the degree Bachelor of Physics, the Bachelor of Advanced Science Physics degree includes additional coursework that includes assessments based on homework assignments, individual projects, and final exams. For the three additional advanced physics courses (Phys188, Phys246, and Phys388) the students are asked to complete an individual research project (typically one per semester). This project involves preparing a 10-15 page report on a specific topic within the theme of the course. The report includes: motivation and background, derivation of important results, figures and data if relevant, discussion, conclusions, and references. The students also give a 20-30 minute oral presentation of their results at the end of the semester and are expected to comment on their peer's presentations. Software Technology Units in the Major in Software Technology all have at least three different types of assessment. These assessments are designed not just to test discipline-specific knowledge, but all aspects of professional competency include professional practice, project work, design and communication skills. In addition to formal assessments, students are provided with informal feedback from staff and their peers throughout the semester. Assessment types are very diverse and include: • assignments - test the understanding of a learning outcome by means of small size problems • programming assignments - allow students to demonstrate their competency in developing software of varying complexity • reports and documents - beside essay style questions to analyse and critique different topics they also assess relevant skills involving documentation such as requirements documentation and project plans • oral presentations - these test students ability to communicate the results of their work • group reports - are used when group projects or group laboratory work is conducted • final exams - the majority of the units will have a final examination where the ability to synthesize and apply knowledge is assessed • quizzes and in-class tests assess student learning part-way through the unit and provide feedback to students on learning progress • tutorial assessment - assess students work in formal tutorial sessions where students receive the support of tutors and other staff. |
Recognition of Prior Learning | Macquarie University may recognise prior formal, informal and non-formal learning for the purpose of granting credit towards, or admission into, a program. The recognition of these forms of learning is enabled by the University’s Recognition of Prior Learning (RPL) Policy (see www.mq.edu.au/policy) and its associated Procedures and Guidelines. The RPL pages contain information on how to apply, links to registers, and the approval processes for recognising prior learning for entry or credit. |
Support for Learning | Macquarie University aspires to be an inclusive and supportive community of learners where all students are given the opportunity to meet their academic and personal goals. The University offers a comprehensive range of free and accessible student support services which include academic advice, counselling and psychological services, advocacy services and welfare advice, careers and employment, disability services and academic skills workshops amongst others. There is also a bulk billing medical service located on campus. |
Program Standards and Quality | The program is subject to an ongoing comprehensive process of quality review in accordance with a pre-determined schedule that complies with the Higher Education Standards Framework. The review is overseen by Macquarie University's peak academic governance body, the Academic Senate and takes into account feedback received from students, staff and external stakeholders. |
Graduate Destinations and Employability | Physics and Astronomy and Astrophysics Successful completion of a degree in Physics and Astronomy is a demonstration of capacity to observe, analyse and interpret complex situations, and to solve a wide range of problems. The graduates may pursue a career in physical sciences in academia (after post-graduate studies) or industry (often after post-graduate studies). Varieties of specialized fields of physics find their application in electro-optics, telecom, mining, semiconductor, aerospace, biomedical industries and national defence. Outside the immediate field of studies the graduates [in combination with other professional studies/training] are employed in secondary school teaching, law (particularly patent law), finance, data analysis and applications, public policy development, medical physics and imaging. Biology The focus of our major on the development problem-solving and critical-thinking skills enables graduates of the biology major to enter a diversity of fields. these include: • animal keeper • aquarist • biotechnologist • captive breeder • education officer • ecological consultant • environmental officer • food industry quality control • genetic counsellor • greenhouse/garden curator • land manager • natural resource manager • ranger • research technician • scientific researcher • science teacher • statistical analyst • quarantine inspector • wildlife manager. Major employers include: • environmental consulting firms • local, state and federal government agencies • universities and research institutes • pharmaceutical and biotechnology companies. In the third year of study, we prepare students for the job market by helping them to formulate their skills and experiences into a CV, and with mock job interviews. Biomolecular Sciences The Biomolecular Sciences specialisation of the Advanced Science Degree offers a path into a wide range of job options in many bioindustries including those engaged in medical research, pharmaceuticals, diagnostics and biotechnology. It allows you to pursue a career in the biotechnology and pharmaceutical industry, research and educational institutions including Universities, hospital research bodies/area health services, and government agencies and laboratories. It provides an excellent foundation for postgraduate studies including medicine. A specialisation in Biomolecular Sciences can also be combined with a range of related disciplines including chemistry, biological sciences, medical sciences, geosciences, physics, business and law. These combinations also allow you to pursue a range of careers in business, industry, research and academia, both in Australia and internationally. Career options include the following: • agrobiotechnology • biomarker discovery • biomedical science research • bioproduct manufacturing • biotechnology industry • drug discovery • forensic scientist • hospital scientist • medical science research • patent officer • pharmaceuticals • science communication • science education • teaching • university postgraduate study and research. Chemistry A major in Chemistry offers a very wide range of job options. Major employers of chemists include academic institutions, industry (chemical manufacturing, pharmaceutical industry, analytical services) and government laboratories and public service advisors. Chemists are employed in positions that are important to community and/or economy such that a shortage of chemists would incur a high risk/high disruption, resulting in significant social and economic costs. A Chemistry major offers entry into a range of associated careers, such as teaching, public policy advising, business and many more that value the critical thinking skills developed within the course of study. Chemistry is also seen as an excellent foundation for entry into postgraduate medicine. The specific knowledge and skills, and the generic graduate capabilities, obtained in BAdvSc - Chemistry program provide an excellent basis for immediate employment or for progression to research endeavours. Mathematics Graduates from the Bachelor of Advanced Science - Mathematics are highly sought after in many sectors including aerospace and defence, engineering, finance and economics, IT and computing, insurance, environment, exploration geophysics and mining, meteorology, telecoms and utilities, education and academic research. These areas of employment depend, at some point on handling and interpreting data, on modelling and predicting outcomes, and rely on the sort of complex quantitative problem-solving skills and more fundamental logical and analytical skills offered by graduates in mathematics. The unique opportunities to study advanced topics and engage with current research provided throughout this program provide an unusually strong foundation for further study and research in mathematics, with many of our graduates proceeding to Doctoral studies, either at Macquarie or at one of a wide range of leading international institutions. Palaeobiology The focus of palaeobiology major is to provide career-specific skills and information, research training the development problem-solving and critical-thinking skills to enables graduate to enter a diversity of fields. Major employers include: • state and regional museums • universities and research institutes • state/federal government geological surveys • local, state and federal government agencies • specialist geoscience consultancies universities • geological surveys • government utilities • mining and resource exploration companies • geothermal exploration industry • specialist contractors • national parks and wildlife • environmental agencies • research organisations • secondary schools • environmental consulting firms. Software Technology The Bachelor of Advanced Science - Software Technology prepares students for careers in a variety of Information Technology areas that involve analysis, development, deployment and maintenance of software systems. Some relevant careers include: software developer, business consultant and analyst, project leader, researcher, and systems administrator. Graduates in these and other areas of Information Technology are in high demand in the Australian workforce and Macquarie IT graduates are no exception (source: Good Universities Guide). The capstone project unit provides experience in a team environment to approximate professional conditions. |
Assessment Regulations | This program is subject to Macquarie University regulations, including but not limited to those specified in the Assessment Policy, Academic Honesty Policy, the Final Examination Policy and relevant University Rules. For all approved University policies, procedures, guidelines and schedules visit www.mq.edu.au/policy. |
Accreditation | This is an Australian Qualifications Framework (AQF) accredited qualification. The Bachelor of Advanced Science - Astronomy and Astrophysics has an Australian Institute of Physics accreditation - every 5 years (most recently October 2013). The Bachelor of Advanced Science - Chemistry is an RACI-accredited program. Accreditation by the Royal Australian Chemical Institute is be regarded by students and employers as the gold standard for chemistry degree courses. The Bachelor of Advanced Science - Mathematics is accredited by the Australian Mathematical Society. Review for renewal of accreditation is scheduled for 2014. |