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University of Adelaide

  • 28% international / 72% domestic

Master of Engineering (Chemical)

  • Masters (Coursework)

Chemical engineering is all about changing raw materials into useful products we use every day in a safe and cost-effective way. Chemical engineers create and develop the processes to produce, change or transport products and materials.

Key details

Degree Type
Masters (Coursework)
Duration
2 years full-time
Course Code
3CM058, 071200D
Intake Months
Jul, Feb
International Fees
$51,000 per year / $102,000 total

About this course

A competitive edge in chemical engineering

Chemical engineering is all about changing raw materials into useful products we use every day in a safe and cost-effective way. Chemical engineers create and develop the processes to produce, change or transport products and materials. They create, sustain and improve industries as diverse as clean energy, water and waste water treatment, food and beverage processing, petrochemicals, primary metals, biotechnology, pharmaceuticals, and specialty chemicals.

Our Master of Engineering (Chemical) is suited to high-achieving engineering graduates, as well as engineers with relevant work experience, who want to learn the about the latest advances in chemical engineering. It is fully accredited by

Engineers Australia
.

Study locations

North Terrace

North Terrace Campus

What you will learn

This intensive degree comprises a foundation year and an advanced studies year. You will:

  • explore advanced chemical engineering concepts: fluid and particle mechanics, chemical reactor design, separation process, process synthesis & design
  • pursue electives according to interests and career goals - from Bioprocess Engineering to Quantum Materials
  • build skills in project management and entrepreneurship
  • undertake a significant research project-including sustainable process design, artificial intelligence in process engineering, energy materials, environmental remediation and biopharmaceutical engineering.

Career pathways

You could develop pharmaceuticals, semiconductors, energy materials, cosmetics or foods. You might work in water treatment, waste management or even tissue engineering. You could conduct safety and risk assessments on process plants. Perhaps you'll design environmentally sustainable food production or energy storage for Space.


  • Ranked #50 in the world for computer science and engineering^
  • Undertake a major research project supervised by world-class academic staff
  • Graduates qualify for professional membership with Engineers Australia

^ARWU, 2022



Course structure

The Master of Engineering is a 48-unit program comprising:

  • 12 units of core courses;
  • 12 units of foundation courses;
  • 12 units of elective courses and;
  • a project to the value of 12 units, which introduces candidates to research.
Normally, students will complete the requirements for the Master of Engineering in two years of full-time study.

Graduates of a Bachelor of Engineering from the University of Adelaide or another institution whose program is equivalent to an AQF level 8 honours program and accredited under the Washington Accord will be eligible to be considered for credit-allowing them to complete the master's program in less than two years, with a minimum of one year of full-time study.

International students from non-English speaking backgrounds will be required to take an English language communications course as part of the program.

The availability of all courses is conditional on the availability of staff, facilities and sufficient enrolments.

Program Learning Outcomes

The learning outcomes for this program were informed by the University of Adelaide Graduate Attributes, Engineers Australia Stage 1 Competencies and the characteristics of the Adelaide Engineering graduate.

Graduates of a Master of Engineering (Chemical) will be able to:

  1. Employ highly developed oral and written communication skills to communicate complex information and present persuasive arguments.
  2. Exercise professional judgement, founded on a strong commitment to principles of continuing professional development, ethics, sustainability and social responsibility.
  3. Contribute pro-actively to the work of teams, both as a team member and a team leader, and maintain respectful, constructive and diverse team environments.
  4. Plan and manage resources using systematic methodologies to create solutions to complex engineering problems.
  5. Think critically and independently, apply logic and exercise judgement to create safe and sustainable outcomes.
  6. Apply in-depth knowledge of the principles and methods of research, and of the research directions in the nominated field of specialisation to devise innovative engineering solutions.
  7. Demonstrate comprehensive knowledge of the natural and physical sciences, and mathematical and computer sciences, which underpin the nominated field of specialisation.
  8. Apply an in-depth specialist body of knowledge and skills in the nominated field of specialisation.
  9. Create innovative solutions to complex socio-technical problems using the established engineering methods, tools and processes in the nominated field of specialisation.














Graduate outcomes

Graduate satisfaction and employment outcomes for Engineering courses at University of Adelaide.
80.2%
Overall satisfaction
88.3%
Skill scale
73.9%
Teaching scale