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Masters Degrees (Chemical Industry)

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Chemical engineering and chemical engineers provide the leading-edge solutions to the society’s needs. Read more

Mission and goals

Chemical engineering and chemical engineers provide the leading-edge solutions to the society’s needs: we need efficient and clean technologies for energy transformation, technologically advanced materials, better medicines, efficient food production techniques, a clean environment, a better utilization of the natural resources. Chemical Engineering plays a pivotal role because all these challenges have a common denominator: they involve chemical processes. Chemical engineers are the "engineers of chemistry": by making use of chemistry, physics and mathematics they describe the chemical processes from the molecular level to the macroscale (chemical plant), and design, operate, and control all processes that produce and/or transform materials and energy.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/chemical-engineering/

Career opportunities

The Master of Science programme in Chemical Engineering completes the basic preparation of the bachelor chemical engineer and provide guided paths towards high-level professional profiles which are employed in various industrial sectors including the chemical, pharmaceutical, food, biological and automotive industry; energy production and management; transformation and process industries; engineering companies designing, developing and implementing processes and plant; research centres and industrial laboratories; technical structures in Public Administration; environmental and safety consultancy firms.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Chemical_Engineering_01.pdf
Chemical engineering provides the leading-edge solutions to the society’s needs: we require clean energy sources, efficient and clean technologies for energy transformation, technologically advanced materials, better medicines, efficient food production techniques, a clean environment, a better utilization of the natural resources. Chemical Engineering plays a pivotal role because all these challenges have a common denominator: they are based on chemical processes. Chemical engineers are the “engineers of chemistry”: by making use of chemistry, physics and mathematics they describe the chemical processes from the molecular level (chemical bond) to the macroscale (chemical plant), and design, operate, and control all processes that produce and/or transform materials and energy. The Master of Science programme in Chemical Engineering provides guided paths towards high-level professional profiles which find employment in various industrial sectors. The programme is taught in English.

Subjects

The Chemical Engineering programme includes mandatory courses on Chemical reaction engineering and applied chemical kinetics; Advanced calculus; Industrial organic chemistry; Unit operations of chemical plants; Mechanics of solids and structures; Applied mechanics. Other courses can be selected by the students on many subjects related to e.g. chemical plants and unit operations, safety, process design, catalysis, material science, numerical methods, environmental protection, food production, energy, biomaterials, etc.. A proper selection of the eligible courses will lead to specializations in Process engineering, Project engineering or Product engineering.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/chemical-engineering/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/chemical-engineering/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Chemical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Chemical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

Key Features of MSc in Chemical Engineering

The MSc Chemical Engineering course is built upon the wide range of research in chemical engineering at Swansea University. This includes engineering applications of nanotechnology, bioengineering, biomedical engineering, cell and tissue engineering, chemical engineering, colloid science and engineering, desalination, pharmaceutical engineering, polymer engineering, rheology, separation processes, transport processes, and water and wastewater engineering.

The MSc Chemical Engineering research project provides an opportunity to work with a member of academic staff in one of the above, or related, area of research. The project may also involve collaboration with industry.

The taught component of the MSc Chemical Engineering course covers specific areas of advanced chemical engineering as well as the complex regulations that are found in the engineering workplace. It also provides an opportunity for the development of personal and transferable skills such as project planning, communication skills, and entrepreneurship.

As a student on the Master's course in Chemical Engineering, you will advance your technical knowledge, which can lead to further research or a career in chemical engineering.

Modules

Modules on the MSc Chemical Engineering course typically include:

Complex Fluids and Rheology

Entrepreneurship for Engineers

Colloid and Interface Science

Communication Skills for Research Engineers

Water and Wastewater Engineering

Membrane Technology

Environmental Analysis and Legislation

Optimisation

Desalination

Polymers: Properties and Design

Principles of Nanomedicine

Nanoscale Structures and Devices

Pollutant Transport by Groundwater Flows

MSc Research Practice

MSc Dissertation - Chemical Engineering

Accreditation

The MSc Chemical Engineering at Swansea University is accredited by the Institution of Chemical Engineers (IChemE).

The MSc Chemical Engineering degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

One of the major strengths of Chemical Engineering at Swansea University is the close and extensive involvement with local, national and international engineering companies. The companies include:

Acordis

Astra Zeneca

Avecia

BP Chemicals

Bulmers

Dow Corning

GlaxoSmithKline

Nestle

Murco

Phillips 66

Unilever

Valero

Swansea staff have research links with local, national, and international companies. An industrial advisory board, consisting of eight industrialists from a range of chemical engineering backgrounds, ensure our courses maintain their industrial relevance.

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Careers

The demand for Chemical Engineering graduates remains excellent with the highest starting salaries out of all engineering disciplines.

Chemical engineers find employment in a variety of public and private sector industries, applying the principles of chemical engineering to health, energy, food, the environment, medicine, petrochemicals and pharmaceuticals.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.



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Chemical Engineering is key in addressing global challenges relating to sustainable supply of clean energy, food and water, through the production of chemicals, functionalised products and fuels. Read more

Chemical Engineering is key in addressing global challenges relating to sustainable supply of clean energy, food and water, through the production of chemicals, functionalised products and fuels. The MSc in Advanced Chemical Engineering provides technical and management training that employers increasingly demand from chemical engineers. The programme offers a general Chemical Engineering option, which covers core chemical engineering subjects and a range of specialised optional modules; and a Biorefining option (formerly the Biofuels Process Engineering MSc), which provides advanced understanding of the production of bioenergy and biofuels while strengthening the knowledge on chemical engineering discipline.

Who is it for?

The course is suitable for engineering and applied science graduates who wish to embark on successful careers as chemical engineering professionals.

Our general Chemical Engineering route equips you with diversified skills in advanced engineering, which includes theoretical and practical elements in operation, design, and control of a wide range of chemical processes. The Biorefining route (formerly the Biofuels Process Engineering MSc) equips you with fundamental understanding of chemical engineering and solid skills to address the challenges of the rapidly growing and dynamic bioenergy sector. This option covers the sustainable production of heat, power and fuels from biomass within the biorefining framework. Both routes include training in management applied to the energy sector which enables engineers to effectively fulfil a wider role in a business organisation.

Why this course?

Chemical engineering is a continuously evolving discipline linked to a variety of industries. Chemical engineers lead the design of large-scale facilities in the chemical, petrochemical, and industrial biotechnology sectors.

A distinguished feature of this course is that it is not directed exclusively at chemical engineering graduates. This MSc will provide you with the training and knowledge skill set that employers actively seek in a desirable engineering graduate. We recognise the importance of an interdisciplinary approach; as such the core and optional modules and course contents have been carefully developed to meet the engineering skill shortage currently faced within industry. In particular, no other university in the UK offers a MSc in Advanced Chemical Engineering with a dedicated option in Biorefining. You will develop the professional profile required by the growing biobased sector (more than 480,000 jobs and annual turnover of about €50 million only in the European Union), with a high level of skills' transferability across the chemical and energy sectors.

Cranfield is an exclusively postgraduate university with distinctive expertise in technology and management. There are also numerous benefits associated with undertaking a postgraduate programme of study in here. These include:

  • Teaching activities involving bespoke pilot plant facilities
  • Undertaking projects in consultation with industry, government and its agencies, local authorities and consultants
  • Lecturing from leading academics and industrial practitioners
  • Dedicated support for off-campus learners including extensive information resources managed by our library.
  • Very well located for part-time students which enables students from all over the world to complete their qualification whilst balancing work/life commitments.
  • A Career Development Service, which is an accredited member of the Association of Graduate Careers Advisory Services (AGCAS) and provides a personalised service to Cranfield students and alumni, working to enhance careers and increase opportunities. 

Course details

The taught programme is delivered from October to February and is comprised of eight modules. The modules are delivered over one week of intensive delivery with the later part of the module being free from structured teaching to allow time for more independent learning and reflection. Students on the part-time programme will complete all of the modules based on a flexible schedule that will be agreed with the Course Director.

Group project

The Group Project, undertaken between February and April, enables you to put the skills and knowledge developed during the course modules into practice in an applied context, while gaining transferable skills in project management, teamwork and independent research. Projects are often supported by industry and potential future employers value this experience. The group project is normally multidisciplinary and shared across the Energy MSc programme, giving the added benefit of working with students with other backgrounds.

Each group is given an industrially relevant problem to solve. During the project you will develop a range of skills including learning how to establish team member roles and responsibilities, project management, and delivering technical presentations. At the end of the project, all groups submit a written report and deliver a poster presentation to industry partners. This presentation provides the opportunity to develop presentation skills and effectively handle questions about complex issues in a professional manner.

Part-time students are encouraged to participate in a Group Project as it provides a wealth of learning opportunities. However, an option of an individual dissertation is available if agreed with the Course Director.

Individual project

The individual research project allows students to investigate deeper into an area of specific interest. It is very common for industrial partners to put forward real world problems or areas of development as potential research project topics. The individual research project component takes place between May and September.

If agreed with the Course Director, part-time students have the opportunity to undertake projects in collaboration with their place of work, which would be supported by academic supervision.

Individual research projects undertaken may involve feasibility assessments, reviews, practical evaluations, designs, simulations, and experimental investigations.

Assessment

Taught Modules 40%, Group Project 20%, Individual Research Project 40%

Your career

Industry driven research makes our graduates some of the most desirable in the world for recruitment by companies competing in a range of industries, including chemicals, petrochemicals, biochemicals, conventional energy and bioenergy, food, materials, consultancy and management.

Those wishing to continue their education via PhD or MBA studies in the chemical or energy sectors will be greatly facilitated by the interdisciplinary, project-oriented profile that they will have acquired through this course.



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Penn’s Master of Chemical Sciences is designed for your success. Chemistry professionals are at the forefront of the human quest to solve ever-evolving challenges in agriculture, healthcare and the environment. Read more
Penn’s Master of Chemical Sciences is designed for your success
Chemistry professionals are at the forefront of the human quest to solve ever-evolving challenges in agriculture, healthcare and the environment. As new discoveries are made, so are new industries — and new opportunities. Whether you’re currently a chemistry professional or seeking to enter the field, Penn’s rigorous Master of Chemical Sciences (MCS) builds on your level of expertise to prepare you to take advantage of the myriad career possibilities available in the chemical sciences. With a faculty of leading academic researchers and experienced industry consultants, we provide the academic and professional opportunities you need to achieve your unique goals.

The Penn Master of Chemical Sciences connects you with the resources of an Ivy League institution and provides you with theoretical and technical expertise in biological chemistry, inorganic chemistry, organic chemistry, physical chemistry, environmental chemistry and materials. In our various seminar series, you will also regularly hear from chemistry professionals who work in a variety of research and applied settings, allowing you to consider new paths and how best to take advantage of the program itself to prepare for your ideal career.

Preparation for professional success
If you’ve recently graduated from college and have a strong background in chemistry, the Master of Chemical Sciences offers you a exceptional preparation to enter a chemistry profession. In our program, you will gain the skills and confidence to become a competitive candidate for potential employers as you discover and pursue your individual interests within the field of chemistry. Our faculty members bring a wealth of research expertise and industry knowledge to help you define your career direction.

For working professionals in the chemical or pharmaceutical industries, the Master of Chemical Sciences accelerates your career by expanding and refreshing your expertise and enhancing your research experiences. We provide full- and part-time options so you can pursue your education without interrupting your career. You can complete the 10-course program in one and a half to four years, depending on course load.

The culminating element of our curriculum, the capstone project, both tests and defines your program mastery. During the capstone exercise, you will propose and defend a complex project of your choice, that allows you to stake out a new professional niche and demonstrate your abilities to current or prospective employers.

Graduates will pursue fulfilling careers in a variety of cutting-edge jobs across government, education and corporate sectors. As part of the Penn Alumni network, you’ll join a group of professionals that spans the globe and expands your professional horizons.

Courses and Curriculum

The Master of Chemical Sciences degree is designed to give you a well-rounded, mechanistic foundation in a blend of chemistry topics. To that end, the curriculum is structured with a combination of core concentration courses and electives, which allow you to focus on topics best suited to your interests and goals.

As a new student in the Master of Chemical Sciences program, you will meet with your academic advisor to review your previous experiences and your future goals. Based on this discussion, you will create an individualized academic schedule.

The Master of Chemical Sciences requires the minimum completion of 10 course units (c.u.)* as follows:

Pro-Seminar (1 c.u.)
Core concentration courses (4-6 c.u., depending on concentration and advisor recommendations)
Elective courses in Chemistry, such as computational chemistry, environmental chemistry, medicinal chemistry, catalysis and energy (2-4 c.u., depending on concentration and advisor recommendations)
Optional Independent Studies (1 c.u.)
Capstone project (1 c.u.)
Pro-Seminar course (CHEM 599: 1 c.u.)
The Pro-Seminar will review fundamental concepts regarding research design, the scientific method and professional scientific communication. The course will also familiarize students with techniques for searching scientific databases and with the basis of ethical conduct in science.

Concentration courses
The concentration courses allow you to develop specific expertise and also signify your mastery of a field to potential employers.

The number of elective courses you take will depend upon the requirements for your area of concentration, and upon the curriculum that you plan with your academic advisor. These concentration courses allow you to acquire the skills and the critical perspective necessary to master a chemical sciences subdiscipline, and will help prepare you to pursue the final capstone project (below).

You may choose from the following six chemical sciences concentrations:

Biological Chemistry
Inorganic Chemistry
Organic Chemistry
Physical Chemistry
Environmental Chemistry
Materials
Independent Studies
The optional Independent Studies course will be offered each fall and spring semester, giving you an opportunity to participate in one of the research projects being conducted in one of our chemistry laboratories. During the study, you will also learn analytical skills relevant to your capstone research project and career goals. You can participate in the Independent Studies course during your first year in the program as a one-course unit elective course option. (CHEM 910: 1 c.u. maximum)

Capstone project (1 c.u.)

The capstone project is a distinguishing feature of the Master of Chemical Sciences program, blending academic and professional experiences and serving as the culmination of your work in the program. You will develop a project drawing from your learning in and outside of the classroom to demonstrate mastery of an area in the chemical sciences.

The subject of this project is related to your professional concentration and may be selected to complement or further develop a work-related interest. It's an opportunity to showcase your specialization and your unique perspective within the field.

Your capstone component may be a Penn laboratory research project, an off-campus laboratory research project or a literature-based review project. All components will require a completed scientific report. It is expected that the capstone project will take an average of six months to complete. Most students are expected to start at the end of the first academic year in the summer and conclude at the end of fall semester of the second year. Depending on the capstone option selected, students may begin to work on the capstone as early as the spring semester of their first year in the program.

All capstone project proposals must be pre-approved by your concentration advisor, Master of Chemical Sciences Program Director and if applicable, your off-campus project supervisor. If necessary, nondisclosure agreements will be signed by students securing projects with private companies. Additionally, students from private industry may be able to complete a defined capstone project at their current place of employment. All capstone projects culminate in a final written report, to be graded by the student's concentration advisor who is a member of the standing faculty or staff instructor in the Chemistry Department.

*Academic credit is defined by the University of Pennsylvania as a course unit (c.u.). Generally, a 1 c.u. course at Penn is equivalent to a three or four semester hour course elsewhere. In general, the average course offered at Penn is listed as being worth 1 c.u.; courses that include a lecture and a lab are often worth 1.5 c.u.

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The Humber is the largest trading estuary in the UK and the fourth largest in Europe, with a chemical and process sector worth £6bn a year. Read more

The Humber is the largest trading estuary in the UK and the fourth largest in Europe, with a chemical and process sector worth £6bn a year. The region is one of the fastest-growing chemical bases in the UK, with investment in new build, expansion and maintenance exceeding £1 billion.

This makes Hull the ideal location to study Chemical Engineering, you benefit from studying near over 350 engineering and process giants – including Phillips66, Total, Novartis, BP Chemicals, Croda, Cristal, Smith & Nephew and Reckitt Benckiser. A strong emphasis is placed on the practical application of knowledge. The University has strong, direct links with industry, providing you with opportunities to work on real-world engineering projects.

Our MSc Chemical Engineering programme is designed for applicants who wish to enter, or enhance, a technical career in the chemical and process industry. The MSc is especially designed for those with a Chemistry, or similar, background, and for those who wish to refresh or strengthen aspects of a prior BEng in Chemical Engineering. It takes both a theoretical and practical approach to ensure graduates gain the knowledge, understanding and skills required by providing a range of modules to suit the individual background of students.

Study information

This programme integrates current and employer-relevant themes and enables you to acquire knowledge and skills across a wide range of topics in the chemical and process industry with an emphasis upon chemical engineering applications.

The programme comprises a combination of lectures, practical/design exercises, tutorials, computer-based process simulation and optimisation, and resource-based, problem-based and enquiry-led learning.

Core modules

  • Principles of Chemical Engineering
  • Principles of Transport Processes and Engineering Thermodynamics
  • Research Skills and Project Planning
  • Principles of Separation Processes and Particle Technology
  • Individual Project

Optional modules

  • Energy Technologies
  • Advanced Thermo-Chemical Processing Technologies
  • Advanced Process Safety, Industrial Process Control and Instrumentation
  • Energy Generation from Conventional and Renewable Fuels

​You will develop competence and confidence in the application of engineering knowledge and techniques to a range of industrial and real-world problems in the chemical and process Industry.

A final project and dissertation will enable you to identify and apply theory and practice to the analysis and solution of complex engineering problems.

* All modules are subject to availability.

Future prospects

The energy engineering industry is expanding rapidly and employment opportunities are high. An increased focus on renewable energy projects is creating demand for sector specialist engineers.

This programme provides you with the skills, competencies and knowledge to be successful in the workplace or will prepare you to advance to specialist PhD study.

This MSc has a host of industry advisors from companies and organisations likely to offer employment opportunities to students completing the programme.



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This course is mainly for engineering students from the UK and overseas who want to develop careers in the oil, gas, process and chemical industries. Read more

Why this course?

This course is mainly for engineering students from the UK and overseas who want to develop careers in the oil, gas, process and chemical industries. The course has a strong project-based approach and is relevant to the recruitment needs of a wide range of employers.

It meets accreditation requirements for the Institute of Chemical Engineers allowing graduates to apply for chartered engineer status.

Our course is one of the few MSc programmes to offer the module Safety Management Practices. It offers exposure to best industry practice and much required industrial training.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/advancedchemicalprocessengineering/

You’ll study

This is a modular course. To gain the Postgraduate Certificate you need to pass six modules.

The Diploma requires eight taught modules and a group project.

The MSc requires eight taught modules, a group design project and an individual research project. You'll work with our talented team of researchers on chemical engineering issues of the future.

The key areas of the programme are:
Chemical & Process Engineering:
- process design principles
- safety management practices
- energy systems
- colloid engineering
- multi-phase processing
- petroleum engineering
- environmental control technologies
- process safety design
- emerging technologies
- programming & optimisation

Multidisciplinary Skills:
- project management
- risk management
- information management
- understanding financial information

If you want to study the same scope of subjects but be part a sustainable engineering programme, you should apply for the MSc Sustainable Engineering: Chemical Processing pathway.

You’ll work on an individual research project with our highly talented team of leading researchers on chemical engineering issues of the future.

Facilities

We're one of the largest chemical engineering departments in the country.
We have new state-of-the-art research laboratories. These include experimental facilities for light scattering, spectroscopy, adsorption measurements and high pressure viscometry.
You'll have access to the department's own dedicated computer suite which is installed with industry standard software.

Accreditation

The course meets accreditation requirements for the Institute of Chemical Engineers allowing graduates to apply for chartered engineer status.

Guest lecturers

In the Emerging Technologies modules you’ll benefit from external speakers who are leading practitioners in their field.

Learning & teaching

All classes are delivered over a twelve week period.
The Emerging Technologies module makes extensive use of external speakers who are leading practitioners in their field.
The Safety Management Practices module offers exposure to best industry practice and is one of a few MSc programmes to offer much required industrial training.

Assessment

Assessment is through a balanced work load of class based assessment, individual and group based projects and exams.

Careers

There is growing demand for high-calibre graduates who can develop and apply advanced process technologies in chemical and process industries.

Some students may be eligible to apply for PhD places in the department and across the Engineering faculty.

How much will I earn?

- The average graduate starting salary for a chemical engineer is £28,000*.
- The average salary for chemical engineers with experience is £53,000*.
- Chartered chemical engineers can earn £70,000* plus.

*Information is intended only as a guide.

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The MSc in Sustainable Chemical Engineering is designed for ambitious graduates who aspire to play leading roles in managing, innovating and delivering resource efficient products, processes and systems in a sustainable way. Read more
The MSc in Sustainable Chemical Engineering is designed for ambitious graduates who aspire to play leading roles in managing, innovating and delivering resource efficient products, processes and systems in a sustainable way. The process industry has a high dependence on material and energy resources. Because of this, there is a strong interest in improving resource efficiency to increase competitiveness and decrease environmental impact.

Resource efficiency is about 'doing more and/or better with less' and delivering this sustainably presents a major opportunity and challenge for engineers and scientists. Industry needs skilled graduates with the expertise to take up this challenge now.

This course benefits from the support of our multidisciplinary EPSRC Centres for Doctoral Training:

- Sustainable Chemical Technologies (University of Bath)
- Water Informatics: Science and Engineering (Universities of Bath, Exeter, Bristol, Cardiff)
- Catalysis (Universities of Bath, Cardiff, Bristol).

The three Centres for Doctoral Training offer excellent opportunities for cross-disciplinary projects in engineering and science as well as access to a lively programme of talks and other events throughout the year. At the start of the MSc programme you will be assigned a doctoral student who will act as your mentor in addition to an academic tutor and supervisor.

Make an Impact: Sustainability for Professionals

If you are interested in sustainability, you can sign up for our free MOOC (massive open online course) Make an Impact: Sustainability for Professionals (https://www.futurelearn.com/courses/sustainability-for-professionals). The course starts in April.

Visit the website http://www.bath.ac.uk/engineering/graduate-school/taught-programmes/sustainable-chemical-engineering/index.html

Learning Outcomes

This course teaches and builds on advanced concepts and technologies core to sustainable chemical engineering. It will train you how to integrate systems thinking and economic, environmental and social objectives in problem solving and decision making. You will graduate with the practical and interpersonal skills required by professionals to work in the emerging and expanding employment market in the green sector.

You will:

- gain a holistic understanding of the environmental, social, ethical, regulatory and economic dimensions of sustainable chemical engineering and how they interact

- apply methodologies and tools to design and evaluate alternative products, processes and systems based on sustainability criteria

- apply your knowledge of resource conservation to deal with complex scenarios, real-life problems and decision making in the face of incomplete or uncertain information

- develop 'big picture' thinking to evaluate alternative products, processes and systems using whole systems approaches, which consider the multiple criteria and stakeholders along the process industry value chain

- develop the skills to formulate and implement research and design projects independently and in professional multidisciplinary teams.

Structure

The programme creates many opportunities for interdisciplinary and active learning through authentic, industrially relevant case studies, games and project work. There are guest speakers from industry and other organisations, as well as opportunities for industrial visits. Transferable skills development, such as problem solving, teamwork, effective communication, networking and time and resource management, is embedded throughout the programme.

- Semester 1 (September to January):
The first semester consists of five taught compulsory units that provide you with a foundation in sustainability and systems analysis to apply throughout the programme.

The units advance your understanding of the concepts, technologies and issues in resource recovery, including the valorisation and the re-use of waste streams (waste2resource). You will examine in detail how resources can be conserved by transforming wastes and other feedstocks into high value products in the bioeconomy.

Each unit consists of lectures, tutorials and case studies, and is supplemented by private study and preparation for in-class activities.

Assessment is by a combination of coursework and examination.

- Semester 2 (February to May):
In the second semester you will take two further technical specialist units on resource conservation. These cover a range of advanced technologies and concepts, including process intensification and waste, water and energy integration.

You will also develop your understanding of Sustainable Chemical Engineering in a design, research and management context through three project-based units, focused on resource efficiency and conservation.

In the group activity, you will apply engineering and project management techniques to solve a design problem, just as an industry-based design team would.

Project unit 1 introduces you to research methods and project planning. You will then apply this to detailed background research in your discipline area to prepare for your individual summer dissertation project in Project unit 2.

Assessment is by a combination of coursework and examination.

- Semester 3 (June to September):
The final semester consists of an individual project leading to an MSc dissertation. Depending on your chosen area of interest, the project may involve theoretical, computational and/or experimental activities. You will conduct your individual project at Bath under the supervision of a member of academic staff, with opportunities for industrial co-supervision. You will have access to the state-of the-art facilities in the Department of Chemical Engineering.

Assessment is through a written dissertation and an oral presentation.


Facilities and equipment
The Department has a full range of research facilities with pilot plants for all major areas of research. Our analytical facilities include gas chromatography, mass spectrometry, high performance liquid chromatography (HPLC), UV-VIS, FTIR and Raman, photon correlation spectroscopy (PCS), microcalorimetry, adsorption measurement systems, surface and pore structure analysis systems and particle sizing equipment. Within the University, there is access to atomic force, scanning and transmission electron microscopes.

Research Excellence Framework 2014
We are proud of our research record: 89% of our research was graded as either world-leading or internationally excellent in the Research Excellence Framework 2014, placing us 10th in the UK for our submission to the Aeronautical, Mechanical, Chemical and Manufacturing Engineering.

Careers information
We are committed to ensuring that postgraduate students acquire a range of subject-specific and generic skills during their research training including personal effectiveness, communication skills, networking and career management. Most of our graduates take up research, consultancy or process and product development and managerial appointments in the commercial sector, or in universities or research institutes.

Find out how to apply here - https://secure.bath.ac.uk/prospectus/cgi-bin/applications.pl?department=chem-eng

We have Elite MSc Scholarships for £2,000 towards your tuition fees available for this course - http://www.bath.ac.uk/engineering/graduate-school/taught-programmes/funding/

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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Chemical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Chemical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

From authoring definitive text books on chemical engineering to finding solutions to the world's water shortages, Swansea University has a proud tradition of delivering pioneering innovative process engineering solutions. As we have a wide range of research in chemical engineering, Swansea University provides an excellent base for your research as an MSc by Research student in Chemical Engineering.

Key Features of MSc by Research in Chemical Engineering

There is a wide range of research in chemical engineering at Swansea University. This includes:

Membrane separation

Biochemical engineering

Biomanufacturing

Engineering applications of nanotechnology

Bioengineering, biomedical engineering

Cell and tissue engineering

Colloid science and engineering

Desalination

Pharmaceutical engineering

Polymer engineering

Rheology

Separation processes

Transport processes

Water and wastewater engineering

The MSc by Research in Chemical Engineering at Swansea University provides an opportunity to work with a member of academic staff in one of the above, or related, area of research.

The MSc by Research in Chemical Engineering typically lasts one year full-time, two to three years part-time. This is an individual research project written up in a thesis of 30,000 words.

Links with industry

One of the major strengths of Chemical Engineering at Swansea University is the close and extensive involvement with local, national and international engineering companies. The companies include:

Acordis

Astra Zeneca

Avecia

BP Chemicals

Bulmers

Dow Corning

GlaxoSmithKline

Nestle

Murco

Phillips 66

Unilever

Valero

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Swansea University has resources specific to Chemical Engineering.

Research

Research in Chemical Engineering at Swansea is located within the Systems and Process Engineering Research Centre which has a number of focused research groups including the Centre for Water Advanced Technologies and Environmental Research (CWATER), the Centre for Complex Fluids Processing and the Multidisciplinary Nanotechnology Centre.

The Centre for Water Advanced Technologies and Environmental Research (CWATER) is an internationally leading centre of excellence for the development of advanced technologies in water treatment. The Centre benefits from world-leading expertise in the areas of desalination and membrane technologies for water treatment.

The Centre for Complex Fluids Processing is internationally recognised for its leading and innovative research on the processing of complex fluids which is a major feature of modern industry. Such fluids are extremely diverse in origin and composition - ranging, for example, from fermentation broths and food products to inks and mineral slurries. However, underlying this diversity are certain properties that must be understood if the processing is to be effective and efficient. These include flow behaviour in process equipment, how the components of the fluid determine its overall properties and how individual components may be selectively separated.

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.



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Our Chemical Engineering MSc will equip you with a multidisciplinary knowledge of chemical engineering in areas such as fuel cells, control, intensification and sustainability. Read more

Our Chemical Engineering MSc will equip you with a multidisciplinary knowledge of chemical engineering in areas such as fuel cells, control, intensification and sustainability. It is intended for honours graduates with a chemical engineering degree who wish to advance their knowledge in the chemical and process engineering design.

The course meets the industry’s growing need for chemical engineers and provides an understanding of theory and its application in an economic and environmentally suitable way. It gives scientists and engineers the opportunity to work with researchers in the fields of new energy technologies and new advanced materials.

You will gain specialist knowledge and understanding via lectures, seminars and personal supervision. You will develop an understanding of:

  • chemical processes
  • model based approaches to process control and measurement
  • process intensification and modelling 
  • latest research developments in chemical engineering

The course is delivered by the School of Chemical Engineering and Advanced Materials. Hear first-hand from our students about studying with us in our postgraduate video.

Accreditation:

We are seeking Institution of Chemical Engineers (IChemE) accreditation, so you can be assured that you will graduate with a degree that meets the standards set out by the chemical engineering industry.

Facilities:

The School of Chemical Engineering and Advanced Materials has a wide range of attractive facilities.

The School occupies five floors in Merz Court, and we provide a Student Common Room and a separate Student Study Space.



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The PgCert/PgDip/MSc in Medical Toxicology is a distance learning course for medical personnel. Read more
The PgCert/PgDip/MSc in Medical Toxicology is a distance learning course for medical personnel.

It is particularly designed for clinical pharmacologists in training, specialist trainees in accident and emergency medicine or acute medicine and other disciplines, and those intending to enter or already working in the pharmaceutical industry.

It is also designed for those working in poisons centres, for health professionals, including hospital and community pharmacists and for those with a degree in Life Sciences or other individuals seeking a career in the government regulatory bodies or the pharmaceutical or chemical industry.

Structure

• PgCert:

This Postgraduate Certificate in Medical Toxicology is a part-time distance learning course that takes 2 years to complete.

The Postgraduate Certificate consists of one stage: stage T.

This stage lasts for one academic year and consists of three 20-credit modules totalling 60 credits, at Level 7

Core modules:

Diagnosis and Management in Poisoning
Poisoning by commonly used pharmaceuticals
Poisoning by non-pharmaceuticals

At the end of stage T, students who have obtained a minimum of 60 credits at Level 7, including the award of credit for all required modules may exit with the award of Postgraduate Certificate or may apply to progress to the Postgraduate Diploma. 

• PgDip:

This Postgraduate Diploma in Medical Toxicology consists of six 20-credit modules which can be completed in 1 year with full-time distance learning or in 2 years by part-time distance learning.

Core modules:

PgCert core modules PLUS

Mechanisms of Toxicity
Preventive and Regulatory Toxicology
Environmental and Industrial Toxicology

If students successfully complete the Postgraduate Diploma in Medical Toxicology to an acceptable standard they may be eligible for entry to the MSc in Medical Toxicology (dissertation stage). However, places are limited and may be allocated on a competitive basis taking past performance into account.

• MSc:

The MSc in Medical Toxicology consists of one stage (post-diploma) – “stage R” (research dissertation stage), which lasts for one year and will include a dissertation of 60 credits at Level 7, to achieve a combined total of 180 credits (including 120 credits from the Cardiff University Postgraduate Diploma in Medical Toxicology) to achieve the MSc.

Your dissertation, which will normally be of not more than 20,000 words and supported by such other material as may be considered appropriate to the subject, will embody the results of your period of project work. The subject of each student’s dissertation will be approved by the Chair of the Board of Studies concerned or his/her nominee.

The dissertation is worth 60 credits and, in combination with the Postgraduate Diploma taught stage(s), is weighted 50% for the purpose of calculating the final mark:

Taught modules (from Cardiff University Postgraduate Diploma in Medical Toxicology) 50%.
Dissertation (stage R) 50%.

Career prospects

The course is suitable for clinical pharmacologists in training, specialist registrars in other disciplines, those working in the pharmaceutical industry, those working in the National Poisons Information Services, pharmacists, nurses and other life science graduates. The course may be of interest to individuals seeking a career in the government regulatory bodies or the pharmaceutical or chemical industry.

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This one-year programme at the University of Edinburgh will immerse you in the most current developments in chemical engineering, through a combination of taught modules, workshops, a research dissertation, and a number of supporting activities delivered by the key experts in the field. Read more

This one-year programme at the University of Edinburgh will immerse you in the most current developments in chemical engineering, through a combination of taught modules, workshops, a research dissertation, and a number of supporting activities delivered by the key experts in the field.

The programme will develop from fundamental topics, including modern approaches to understanding properties of the systems on a molecular scale and advanced numerical methods, to the actual processes, with a particular emphasis on energy efficiency, to the summer dissertation projects where the acquired skills in various areas are put into practice, in application to actual chemical engineering problems.

Programme structure

The programme develops from compulsory courses, emphasizing modern computational techniques and research methods, to a range of options. It is complemented by a strong management and economics component, culminating in a research project leading to a masters thesis.

Compulsory Courses

  • Numerical Methods for Chemical Engineers
  • Molecular Thermodynamics
  • Introduction to Research Methods

Optional Courses

Students must select one of the following courses during semester one:

  • Chemical Reaction Engineering
  • Fire Science and Fire Dynamics
  • Process Safety
  • Computational Fluid Dynamics
  • Group Design Project (Power Station with Carbon Capture and Storage)

Plus, five or six courses (depending on the weighting of the course) from the options listed below in semester two:

  • Adsorption
  • Separation Processes
  • Membrane Separation Processes
  • Batchwise and Semibatch Processing
  • Oil and Gas Systems Engineering
  • Polymer Science and Engineering
  • Supply Chain Management
  • Modern Economic Issues in Industry
  • Technology and Innovation Management
  • Nanotechnology
  • Engineering in Medicine
  • Nanomaterials in Chemical and Biomedical Engineering

Learning outcomes

  • A working knowledge of modern modelling and simulation approaches to understanding properties of chemical systems at a molecular level.
  • A working knowledge of advanced experimental techniques, such as for example particle image velocimetry, spectroscopy and infra-red thermography, as applied in engineering research and development.
  • Ability to transform a chemical engineering problem into a mathematical representation; broad understanding of the available numerical tools and methods to solve the problem; appreciation of their scope and limitations.
  • An understanding of the basic design approaches to advanced energy efficient separation processes.
  • Ability to transfer and operate engineering principles in application to other fields, such as biology.
  • Proficiency in using modern chemical engineering software, from molecular visualisation to computational fluid dynamics to process engineering.

On completion of the research dissertation, the students will be able to:

  • Plan and execute a significant research project
  • Apply a range of standard and specialised research instruments and techniques of enquiry
  • Identify, conceptualise and define new and abstract problems and issues
  • Develop original and creative responses to problems and issues
  • Critically review, consolidate and extend knowledge, skills practices and thinking in chemical engineering
  • Communicate their research findings, using appropriate methods, to a range of audiences with different levels of knowledge and expertise
  • Place their research in the context of the current societal needs and industrial practice
  • Adhere to rigorous research ethics rules
  • Exercise substantial autonomy and initiative in research activities
  • Take responsibility for independent work
  • Communicate with the public, peers, more senior colleagues and specialists
  • Use a wide range of software to support and present research plans and findings

Career opportunities

Our graduates enjoy diverse career opportunities in oil and gas, pharmaceutical, food and drink, consumer products, banking and consulting industries. Examples of the recent employers of our graduates include BP, P&G, Mondelēz International, Doosan Babcock, Atkins, Safetec, Xodus Group, Diageo, Wood Group, GSK, Gilead Sciences, ExxonMobil, Jacobs, Halliburton, Cavendish Nuclear to name a few. This wide range of potential employers means that our graduates are exceptionally well placed to find rewarding and lucrative careers. According to the Complete University Guide, the chemical engineering programme at the University of Edinburgh is ranked one of the top in the UK in terms of graduates prospects.

Find out more about career opportunities:

The MSc in Advanced Chemical Engineering may also lead to further studies in a PhD programme. With the 94% of our research activity rated as world leading or internationally excellent (according to the most recent Research Excellence Framework 2014), Edinburgh is the UK powerhouse in Engineering. As an MSc student at Edinburgh you will be immersed in a research intensive, multidisciplinary environment and you will have plenty of opportunities to interact with PhD, MSc students and staff from other programmes, institutes and schools.

Find out more about our research:



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MSc Chemical Engineering and Process Management explores topics required for a successful career as a chemical engineer. Read more
MSc Chemical Engineering and Process Management explores topics required for a successful career as a chemical engineer. You'll study process management and how this relates to chemical engineering, which is increasingly required in chemicals and petrochemical plants along with solid knowledge in reactor design, process simulation, and the numerous unit operations that take place.

The course has been developed in response to these industry needs and it reflects our strength in research and teaching in this area.

If you already have a first degree in chemical engineering you can gain more in-depth knowledge in this discipline as well as explore broader issues through specialist modules relating to project management, the chemical industry, and sustainability. Academic staff in the Division of Chemical and Petroleum Engineering are very research active in areas such as greener energy, multiphase flow, materials and catalytic reactions.

If you do not have a chemical engineering degree but graduated from a closely related engineering discipline, this course offers you a platform to study chemical engineering and opens a career path for you in the chemical industry.

Modules

Engineering management for chemical engineers
Advanced reaction engineering
Energy management and sustainability
Materials engineering
Multiphase fluid flow
Dissertation

Plus one option from:

Applied engineering practice
Chemical process management

All modules except the dissertation are assessed by a combination of examinations and written coursework assignments.

Accreditation

This course is seeking accreditation from the Institution of Chemical Engineers (IChemE).

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Why choose this course?. This course aims to. extend your comprehension of key chemical concepts and so provide you with an in-depth understanding of specialised areas of chemistry. Read more

Why choose this course?

This course aims to:

  • extend your comprehension of key chemical concepts and so provide you with an in-depth understanding of specialised areas of chemistry.
  • provide you with the ability to plan and carry out experiments independently and assess the significance of outcomes.
  • develop your ability to adapt and apply methodology to the solution of unfamiliar types of problems.
  • instil a critical awareness of advances at the forefront of the chemical sciences.
  • prepare you effectively for professional employment or research degrees in the chemical sciences.

What happens on the course?

You will build upon your previous undergraduate studies to develop an in depth knowledge of selected aspects of advanced cutting edge topics in chemistry.

MSc Chemistry Level 7 Programme (all modules are 20 credits unless otherwise specified)

*Advanced Topics in Organic Chemistry

*Advanced Topics in Inorganic Chemistry

*Advanced Topics in Physical Chemistry

*Advanced Topics in Chemical Analysis

MSc Research Project (120 credits)

*Select three from these four core option modules.

Why Wolverhampton?

  • Chemistry, and related science students, have excellent job prospects or go on to further study and/or research.
  • Our existing chemistry-related programmes, BSc Biochemistry and BSc Pharmaceutical Science have excellent student satisfaction rates (95% respectively) and we anticipate that our new Chemistry developments will achieve similar results.
  • Our compliment of existing, experienced staff (including several research professors), will expand as the course develops. We recently moved into our new £25m “state of the art” science facility. The new laboratory facilities were accompanied by generous investment in a range of new teaching, research and consultancy equipment.
  • Our chemistry-based subjects have maintained links with several local/regional chemical companies and we’ve had many successful collaborative research and development knowledge transfer programmes (KTP’s), our most recent was independently rated as “outstanding”, the highest grading possible. We shall continue to build upon our existing and expanding capacity to develop links with local employers.

Career Path

The UK’s chemical industry is one of the leading industrial contributors to the national economy and there are many opportunities to apply chemical knowledge, principles and skills to a successful career in the chemistry, pharmaceutical science, chemical engineering or other chemistry-related disciplines. “Chemistry will underpin economic growth, say industry leaders”, it was reported in the Royal Society of Chemistry (RSC) publication, Chemistry World, on the “Strategy for delivering chemistry-fuelled growth of the UK economy”. Currently the Chemistry-using industries contribute ~£195bn to the UK economy with approximately £10bn coming from chemical manufacturing and £9bn from pharmaceutical manufacturing. The areas of chemical manufacture, process technology, product development and application, and formulation skills are key areas of these chemical sciences. In chemicals (including pharmaceuticals) 95.6% of UK companies are SME’s employing 42% of the total workforce and account for 29% of turnover.

If you choose not to go into the chemical industry there are still extensive career opportunities in teaching and academic research

What skills will you gain?

You will have evidenced good practical skills, be literate, numerate, have high level of IT skills and be capable of logical, scientific, critical thinking and problem solving. You will have developed a great deal of autonomous decision making and research capability and you will be able to evidence a range of professional, personal transferable skills and be well versed with the concept of continuous professional development. These skills will make you well equipped for the workplace, be it in a chemistry environment or the wider world of work in general, or for further research if you so choose.

Join us on Social Media

Faculty of Science and Engineering on Facebook

https://www.facebook.com/wlvsae/

Faculty of Science and Engineering on Twitter

https://twitter.com/WLVsci_eng



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Why choose this course?. This course aims to. extend your comprehension of key chemical concepts particularly in the field of instrumental chemical analysis and so provide you with an in-depth understanding of specialised areas of chemistry. Read more

Why choose this course?

This course aims to:

  • extend your comprehension of key chemical concepts particularly in the field of instrumental chemical analysis and so provide you with an in-depth understanding of specialised areas of chemistry
  • provide you with the ability to plan and carry out experiments independently and assess the significance of outcomes
  • develop your ability to adapt and apply methodology to the solution of unfamiliar types of problems
  • instil a critical awareness of advances at the forefront of the chemical sciences with special emphasis on instrumental chemical analysis
  • prepare you effectively for professional employment or research degrees in the chemical sciences.

What happens on this course?

You will build upon your previous undergraduate studies to develop an in depth knowledge of selected aspects of advanced cutting edge topics in chemistry.

MSc Chemistry Level 7 Programme (all modules are 20 credits unless otherwise specified)

*Advanced Topics in Organic Chemistry

*Advanced Topics in Inorganic Chemistry

*Advanced Topics in Physical Chemistry

#Advanced Topics in Chemical Analysis

#Laboratory Quality Assurance and Management

#Pharmaceutical Analysis

#MSc Research Project (120 credits)

If you are a direct entrant to the University of Wolverhampton you are expected to do the core modules (#) but if you have previously done the BSc Hons) Chemistry degree at Wolverhampton then you can replace Laboratory Quality assurance and Management with one of the three options*

Why Wolverhampton?

  • Chemistry, and related science students, have excellent job prospects or go on to further study and/or research.
  • Our existing chemistry-related programmes, BSc Biochemistry and BSc Pharmaceutical Science have excellent student satisfaction rates (95% respectively) and we anticipate that our new Chemistry developments will achieve similar results.
  • Our compliment of existing, experienced staff (including several research professors), will expand as the course develops. We recently moved into our new £25m “state of the art” science facility. The new laboratory facilities were accompanied by generous investment in a range of new teaching, research and consultancy equipment.
  • Our chemistry-based subjects have maintained links with several local/regional chemical companies and we’ve had many successful collaborative research and development knowledge transfer programmes (KTP’s), our most recent was independently rated as “outstanding”, the highest grading possible. We shall continue to build upon our existing and expanding capacity to develop links with local employers.

Career Path

The UK’s chemical industry is one of the leading industrial contributors to the national economy and there are many opportunities to apply chemical knowledge, principles and skills to a successful career in the chemistry, pharmaceutical science, chemical engineering or other chemistry-related disciplines. “Chemistry will underpin economic growth, say industry leaders”, it was reported in the Royal Society of Chemistry (RSC) publication, Chemistry World, on the “Strategy for delivering chemistry-fuelled growth of the UK economy”. Currently the Chemistry-using industries contribute ~£195bn to the UK economy with approximately £10bn coming from chemical manufacturing and £9bn from pharmaceutical manufacturing. The areas of chemical manufacture, process technology, product development and application, and formulation skills are key areas of these chemical sciences. In chemicals (including pharmaceuticals) 95.6% of UK companies are SME’s employing 42% of the total workforce and account for 29% of turnover.

If you choose not to go into the chemical industry there are still extensive career opportunities in teaching and academic research

What skills will you gain?

You will have evidenced good practical skills, be literate, numerate, have high level of IT skills and be capable of logical, scientific, critical thinking and problem solving. You will have developed a great deal of autonomous decision making and research capability and you will be able to evidence a range of professional, personal transferable skills and be well versed with the concept of continuous professional development. These skills will make you well equipped for the workplace, be it in a chemistry environment or the wider world of work in general, or for further research if you so choose.

Join us on Social Media

Faculty of Science and Engineering on Facebook

https://www.facebook.com/wlvsae/

Faculty of Science and Engineering on Twitter

https://twitter.com/WLVsci_eng



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Chemical engineers invent, design and implement industrial-scale processes through which raw materials are converted into products that we rely on every day, such as fuel, plastics, food additives, fertilisers, paper and pharmaceuticals. Read more

Chemical engineers invent, design and implement industrial-scale processes through which raw materials are converted into products that we rely on every day, such as fuel, plastics, food additives, fertilisers, paper and pharmaceuticals.

You will develop practical, laboratory-based skills, combined with expertise in computing and simulation. You will be guided by internationally renowned experts in areas such as nanotechnology, carbon capture and storage, minerals and materials, natural gas processing, and solvent extraction. You will have the opportunity to complete an industry project in conjunction with a relevant industry partner.

The Master of Engineering (Chemical) will lead to a formal qualification in chemical engineering.

CAREER OUTCOMES

Chemical Engineering Career Pathways [PDF]

Career opportunities in chemical engineering are extensive and exist in petrochemical, minerals processing, mining, chemical manufacturing, natural gas, explosives and fertiliser production and environmental consulting.

Our graduates are employed in a diverse range of industries, for companies including: ExxonMobil, BP, PETRONAS, Schlumberger, Nyrstar, BHP Billiton, Rio Tinto, Worley Parsons, ThyssenKrupp, WSP Parsons Brinckerhoff, Wood Group PSN, GHD, AECOM, Mars and Unilever.

PROFESSIONAL ACCREDITATION

The Master of Engineering is professionally recognised under two major accreditation frameworks — EUR-ACE® and the Washington Accord (through Engineers Australia). Graduates can work as chartered professional engineers throughout Europe, and as professional engineers in the 17 countries of the Washington Accord.

Master of Engineering (Chemical) is also accredited by IChemE (Institution of Chemical Engineers). This accreditation has worldwide recognition.



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