Course availability

First year courses

The course content in first year courses remains mostly unchanged. Course outlines are available here: [Course Outlines]

T1

T2

T3

CHEM1001

CHEM1011

CHEM1011

CHEM1011

CHEM1021

CHEM1021

CHEM1021

CHEM1041

CHEM1831

CHEM1031 

CHEM1061 

 

CHEM1051 

CHEM1821 

 

CHEM1811

CHEM1829

 
 

SCIF1004

 

Second year courses

The course content in second year courses remains mostly unchanged. CHEM2041 is now a prerequisite for CHEM2011, CHEM2021 and CHEM2031. 

For more information please see the Course Prerequisites page. Course outlines are available here: [Course Outlines]

T1

T2

T3

CHEM2041

CHEM2011

CHEM2031

CHEM2921

CHEM2021

CHEM2041

CHEM2999

CHEM2999

CHEM2999

 

 NANO2002

 

Third year courses

Our 3rd year chemistry courses have been completely redesigned in preparation for UNSW3+. Part of these exciting changes include a wider range of courses to choose from (see more detail below). For more information please see the Course Prerequisites page. Course outlines are available here: [Course Outlines]

The links below provide more detail on each of the courses:

T1

T2

T3

CHEM3021

CHEM3031

CHEM3011

CHEM3061

CHEM6041

CHEM3051

CHEM3998

CHEM3998

CHEM3071

 

 

CHEM3901

 

 

CHEM3998

 

CHEM3011 (Physical Chemistry: Quantum Nature of Molecules - from Earth to Space)

Course Coordinator: Dr. Ho

Gain a deeper understanding of physical chemistry and ability to utilise contemporary computational and experimental methods. Explore the phenomenological nature of matter at the quantum scale. The first part of the course focuses on establishing the theoretical foundations and introducing powerful new theories including statistical thermodynamics and symmetry. The second part of the course introduces students to the application of these methods in modern computational chemistry. The third part of the course illustrates modern experimental techniques such as laser spectroscopy to elucidate chemical reactions down to the femtosecond timescale. Throughout the course there will be an emphasis on applications of these techniques, for example, in atmospheric chemistry, astrochemistry chemistry and reaction kinetics.

CHEM3021 (Organic Chemistry: Modern Synthetic Strategies)

Course Coordinator: Prof. Kumar

The need for new functional molecules is greater than ever, with ever-growing demand for new therapeutics and materials for the future. The course will focus on developing key skills in making complicated organic molecules from simple building blocks, and transforming one organic molecule to another using the synthetic toolbox. Students will be trained in modern synthetic methodologies and their application in industry to solve real world problems. The concept of retrosynthetic analysis, a logic-based tool that uses pattern recognition and mechanistic understanding for the design of synthetic pathways, will be taught and illustrated with classic case studies, including the synthesis of natural products and bioactive molecules.

CHEM3031 (Inorganic Chemistry: Transition Metals and Complexes)

Course Coordinators: Dr Sulway

This course provides insight into the current state-of-art research where metals are used in technologies such as semiconductors, batteries, solar cells, superconductors, and where metals are used in life such as photochemical processes, nitrogen fixation. This course showcases the importance of understanding the role of the metal in these systems. The key components of structural characterization relevant to this understanding are covered and the function derived from the structure expanded. The way chemistry can be used to tune structure and hence properties is shown to underpin all of these technologies and processes in life.

CHEM3051 (Medicinal Organic Chemistry)

Course Coordinator: A/Prof. McAlpine

Synthesis of new organic molecules is a core skill that lies at the heart of medicinal chemistry. The development of a new drug, from the design stage to eventual introduction into the clinic, is enabled by comprehensive synthetic skills. This course will explore a range of important techniques necessary for the synthesis of complex organic architectures: synthetic strategy and the use of protecting groups, an introduction to asymmetric synthesis, and polymer-supported synthesis of bimolecular including peptides and nucleic acids.

CHEM6041 (Advanced Instrumental Analysis)

Course Coordinators: A/Prof Donald

This course builds on students' existing background in analytical chemistry to develop both theory and practice relating to the latest analytical techniques used in industry and research. The course covers in general, method validation and quality assurance in the analytical chemistry laboratory; and for selected major techniques, method development, theory, operation, instrumentation and applications. Analytical methods covered include separation techniques (chromatography), mass spectrometry, hyphenated chromatography-mass spectrometry techniques, surface analysis, X-ray diffraction, and elemental analysis, which are amongst the most widely used analytical instrumental techniques across a broad range of disciplines and in many different industries. The course was designed in close consultation with industry leaders (who will also give guest lectures) to provide valuable perspectives from outside academia and provide focus on the most relevant occupational skills. Students will obtain hands-on experience using state-of-the art, instruments in the Mark Wainwright Analytical Centre. Thus, the course strongly emphasises employability in both industry, government and academy.

CHEM3061 (Chemistry of Materials)

Course Coordinators: A/Prof. Kilian

Chemistry is fundamental not just to the design of small molecules, but increasingly to the preparation of materials ranging from hard colloidal nanomaterials to soft complex macromolecular architectures. These materials have been used by humans throughout the ages: from the Lycurgus Cup of ancient Rome to natural polymers such as wool and silk. This course will explore the synthesis and characterisation of such materials, as well as the physical chemistry that underpins their behaviour both in solution and in the solid state. A particular emphasis will be placed on chemistry at the interface, the modification of surfaces, and the self-assembly of block copolymers for the preparation of nanostructures materials.

CHEM3071 (The Chemistry of Catalysis, Systems and Biology)

Course Coordinator: A/Prof. Ball

Building on student’s existing background in both organic and inorganic chemistry, this course provides an understanding of the parallels between the function of synthetic and biological molecules, including enzymes. The parallels in the areas of catalysis and the formation of complex and self-assembled structures through intermolecular (supramolecular) interactions will be detailed. In this course you will learn about fundamental concepts and techniques in organic and organometallic catalysis, self-assembly & supramolecular chemistry and the chemistry of biological assemblies and enzymatic catalysis.