Objectives of Programme's Learning Outcomes

• Imagine, design, implement and operate compounds, products and materials to specific properties and physical, chemical and biochemical solutions/processes leading to obtaining these materials by integrating needs, contexts and issues (technical, economic, societal, ethical, safety and environmental).
• Based on modelling, design one or more products/processes/solutions addressing the problem raised; evaluate them in light of various parameters of the specifications.
• Mobilise a structured set of scientific knowledge and skills and specialised techniques in order to carry out missions of chemical engineering and materials science, using their expertise and adaptability.
• Master and appropriately apply knowledge, models, methods and techniques specific to the field of chemistry and materials science.
• Analyse and model a problem/process/producing pathway by critically selecting theories and methodological approaches (modelling, calculations), and taking into account multidisciplinary aspects.
• Assess the validity of models and results in view of the state of science and characteristics of the problem.
• Contribute by researching the innovative solution of a problem in engineering sciences.
• Design and implement technical analysis, experimental studies and numerical modelling.
• Acquire and analyse data rigorously.
• Mobilise a structured set of scientific knowledge and skills and specialised techniques in order to carry out missions of chemical engineering and materials science, with a focus on chemical industry processes, using their expertise and adaptability.
• Master and appropriately mobilise knowledge, models, methods and techniques relating to material properties, chemical changes, transport phenomena and thermodynamic properties, characterisation techniques and methods of chemical and material compounds, environmentally friendly production processes, and their optimisation and simulation.
• Analyse and model a process or way of producing a compound by critically selecting theories and methodological approaches (modelling, calculations), and taking into account multidisciplinary aspects.
• Assess the relevance of models and results given the current state of science and characteristics of the problem.

Learning Outcomes of UE

Calculate physical and thermodynamic properties of pure and mixture compounds in "extreme" conditions (concentration, temperature and pressure) ;
apply the laws of thermodynamics in equilibrium between dense fluids ; in supercritical fluids, in electrolyte solutions, in adsorbed phase, in clathrate compounds
determine the thermodynamics properties of systems.

Content of UE

Properties of high pressure fluids ; thermodynamic properties closed to the critical point (retro condensation ) ; chemical reactions ; electrolyte solutions ; polymer solutions ; liquid-liquid equilibrium (stability, miscibility, ...) ; tri-phase equilibria ; Basics of adsorption.

Prior Experience

Laws of thermodynamics,  thermodynamics relations;  Chemical thermodynamics : equation of state , models of solution;

Type of Assessment for UE in Q1

• Written examination

Q1 UE Assessment Comments

Personnel works and reports, 25 % of the mark.
Written examination during the regular examination period, 75 % of the mark, maximum length 4 hours.

Type of Assessment for UE in Q3

• Written examination

Q3 UE Assessment Comments

100 % of the mark, maximum length 4 hours.

Type of Resit Assessment for UE in Q1 (BAB1)

• N/A

Q1 UE Resit Assessment Comments (BAB1)

Not applicable