Develop your understanding of the main principles of chemical engineering and apply these principles to chemical engineering problems.

Build the skills required to analyse and compare chemical processes and learn how to develop and analyse flow diagrams.

Explore the key features of Matlab software and develop your problem solving skills through group work. You'll also acquire essential skills in physically manipulating apparatus, making measurements and analysing data.

Explain the behaviour and properties of fluids and solve basic problems related to fluid mechanics and heat and mass transfer.

Define and distinguish important principles related to thermodynamics and analyse one-component multi-phase systems.

Analyse diffusional separation processes for simple gas-liquid and liquid-liquid systems and consider their economic viability.

Familiarise yourself with the main principles of chemistry, and identify and apply a number of theories and concepts to solve reactivity.

Understand how to select the most appropriate mathematical techniques for problem solving and use these to solve complex mathematical equations.

Gain knowledge of the concepts that link atomic and molecular physical chemistry to macroscopic behaviour of gases, liquids and solids. 

Reinforce your mastery of chemical engineering to tackle more practical real-life engineering problems.

Advance your understanding of the equations governing mass and momentum transfer of incompressible fluids.

Design and execute selected experiments for a variety of engineering problems in order to choose optimal solutions and/or deliver set targets.

Engage with the fundamental theory for the design and analysis of (pseudo-) homogeneous chemical reactors.

Develop an understanding of the principles of a variety of industrially-significant processes concerned with energy conversion and use.

Explore the transient behaviour of processes through the application of a variety of mathematical models.

Build on your knowledge from Year 1 and analyse advanced distillation and extraction processes.

Review various mathematical concepts and methods used in chemical engineering, including vector calculus and partial differential equations.

Identify the chemical foundations and mechanisms that underpin chemical industrial processes and explore key concepts in biochemistry.

Further develop your mastery of chemical engineering towards an advanced level of proficiency in communication, problem solving and critical thinking.

Apply a general problem-solving approach to design heterogeneous and multi-phase reactors and appreciate the underlying physics of different reactor types.

Assess the key principles of particle technology and apply these concepts in process design situations involving solids.

Become familiar with structured approaches to the design of chemical processes and the associated business skills required to develop a business plan.

Analyse the hazards which are most often encountered in industrial process plants and learn how to identify them.

Examine the environmental impacts of human activities and explore issues related to sustainability, waste minimisation, clean technology and green chemistry.

Extend the practical competencies gained in earlier modules to areas of design and research to further develop your expertise and engineering judgement.

Apply advanced numerical methods for optimisation of both linear and nonlinear models to real chemical engineering problems.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department. You will be taught alongside students from other courses with options including business, management and many more.

Develop your ability to formulate and solve engineering problems involving the design of membranes and membrane modules.

Investigate the main chemical engineering processes associated with nuclear energy and work through problems related to mass and energy balance.

Understand how the environmental impacts of fossil fuels can be minimised and analyse CO2 capture from a range of processes.

Learn how to apply fundamental operation principles of different energy storage and conversion technologies and explore different options for clean energy generation.

Investigate the application and use of biological sensors.

Build your awareness of varied problems of process heat transfer and appreciate the advantages and disadvantages of the respective heat exchanger types.

Apply mathematical techniques to derive and solve the equations of motion of fluids and solve problems in Stokes and potential flows.

Employ innovative thinking to develop new process strategies, technology and analytical ability across a research project and group design task.

Understand the nature of various interparticle forces, and explain the significant forces between colloidal systems and how they can be calculated and measured.

Explore current experimental techniques for product characterisation and apply these methods to real-world products.

Evaluate a broad range of spectroscopic methods and apply your skills to various chemical systems and processes.

Review the techniques used in biotechnology, which in many cases differ markedly from chemical engineering.

Formulate, solve and interpret meaningful optimisation problems, and appreciate conditions for optimality as well as commonly available solution techniques.

Review state-of-the-art optimisation based techniques for process synthesis, process design and molecular design, and learn how to use leading modelling software.

Develop mathematically well-behaved models of the transient behaviour of process equipment.

Appreciate how nonlinear dynamical systems are key to our understanding of complex phenomena both in nature and in a variety of technological processes.

Assess the opportunities and constraints of the drug development process and the value the chemical engineer adds to it.

Interlink the biological principles of cellular physiology with the mathematical tools required for their analysis and modelling.

Review the relevant fundamentals of biochemistry, microbiology, and molecular biology, and understand the principles behind fermentation processes.

Develop your appreciation of the basic principles of heat, mass and momentum transport and solve problems involving fluid flow, heat and mass transfer.

Build the background and skills needed to understand the application of molecular theory and simulation in modelling fluids and fluid mixtures.

Understand the application of machine learning techniques within a chemical engineering context.

Develop your understanding of the main principles of chemical engineering and apply these principles to chemical engineering problems.

Build the skills required to analyse and compare chemical processes and learn how to develop and analyse flow diagrams.

Explore the key features of Matlab software and develop your problem solving skills through group work. You'll also acquire essential skills in physically manipulating apparatus, making measurements and analysing data.

Explain the behaviour and properties of fluids and solve basic problems related to fluid mechanics and heat and mass transfer.

Define and distinguish important principles related to thermodynamics and analyse one-component multi-phase systems.

Analyse diffusional separation processes for simple gas-liquid and liquid-liquid systems and consider their economic viability.

Familiarise yourself with the main principles of chemistry, and identify and apply a number of theories and concepts to solve reactivity.

Understand how to select the most appropriate mathematical techniques for problem solving and use these to solve complex mathematical equations.

Gain knowledge of the concepts that link atomic and molecular physical chemistry to macroscopic behaviour of gases, liquids and solids. 

Reinforce your mastery of chemical engineering to tackle more practical real-life engineering problems.

Advance your understanding of the equations governing mass and momentum transfer of incompressible fluids.

Design and execute selected experiments for a variety of engineering problems in order to choose optimal solutions and/or deliver set targets.

Engage with the fundamental theory for the design and analysis of (pseudo-) homogeneous chemical reactors.

Develop an understanding of the principles of a variety of industrially-significant processes concerned with energy conversion and use.

Explore the transient behaviour of processes through the application of a variety of mathematical models.

Build on your knowledge from Year 1 and analyse advanced distillation and extraction processes.

Review various mathematical concepts and methods used in chemical engineering, including vector calculus and partial differential equations.

Identify the chemical foundations and mechanisms that underpin chemical industrial processes and explore key concepts in biochemistry.

Employ innovative thinking to develop new process strategies, technology and analytical ability across a research project and group design task.

Understand the nature of various interparticle forces, and explain the significant forces between colloidal systems and how they can be calculated and measured.

Explore current experimental techniques for product characterisation and apply these methods to real-world products.

Evaluate a broad range of spectroscopic methods and apply your skills to various chemical systems and processes.

Review the techniques used in biotechnology, which in many cases differ markedly from chemical engineering.

Formulate, solve and interpret meaningful optimisation problems, and appreciate conditions for optimality as well as commonly available solution techniques.

Review state-of-the-art optimisation based techniques for process synthesis, process design and molecular design, and learn how to use leading modelling software.

Develop mathematically well-behaved models of the transient behaviour of process equipment.

Appreciate how nonlinear dynamical systems are key to our understanding of complex phenomena both in nature and in a variety of technological processes.

Assess the opportunities and constraints of the drug development process and the value the chemical engineer adds to it.

Interlink the biological principles of cellular physiology with the mathematical tools required for their analysis and modelling.

Review the relevant fundamentals of biochemistry, microbiology, and molecular biology, and understand the principles behind fermentation processes.

Develop your appreciation of the basic principles of heat, mass and momentum transport and solve problems involving fluid flow, heat and mass transfer.

Build the background and skills needed to understand the application of molecular theory and simulation in modelling fluids and fluid mixtures.