Master in Chemistry / Polymer Engineering and Materials for the Environment Track / Polymer Systems Engineering Speciality

Course label :	English
Teaching departement :	LVI / Foreign Languages
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_ANG - Anglais

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

English for communicating in a professional environment - English for conversation - English for business: interviews, CVs, phone calls, meetings, negotiations, oral presentations, progression in a multicultural environment, etc. - Preparing for the TOEIC - Particularities of the English specialisation

Educational goals

Boost confidence and improve the ability to progress in a professional environment where English is the language of communication, both written and spoken.

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: - Continuous assessment (50%) oral presentation (expatriation project/CV/cover letter) - Continuous assessment (50%) written exam in December

Online resources

Pedagogy

Students are divided into groups based on their levels The programme can be adapted according to students' levels/needs Method focused on oral communication and role play, active participation in the course is essential

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	24
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Students are expected to reach level B2 at the end of the bachelor's degree. A TOEIC test is used to assess the level at the beginning of the semester.

Maximum number of registrants

Remarks

Course label :	Advanced microscopy and XRD of materials
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_DRX - Microscopie et DRX avancées ma

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Master techniques for the structural characterisation and determination of solids: X-ray diffraction (DRX) and transmission electron microscopy (TEM).

Educational goals

Role play: Which technique to choose to get the information you're looking for - Impact of sampling on information

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Report and final exam

Online resources

Analysis platforms of the Chevreul Institute and the Catalysis and Solid-State Chemistry Unit (UCCS) and Materials and Transformations Unit (UMET) laboratories

Pedagogy

In-person course - case studies

Sequencing / learning methods

Number of hours - Lectures :	9
Number of hours - Tutorial :	6
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Pre-orientation course unit for the first year of the master's degree (M1), core curriculum 1, 2, 4 and 5, or equivalent

Maximum number of registrants

Remarks

Mandatory course for both the ISP (polymer systems engineering) and MI2E (inorganic materials for energy and the environment) specialisations in the IPME (polymers and materials for the environment) track.

Course label :	Advanced spectroscopy and thermal analyses of materials
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_SAT - Spectrosc et analyses thermiq

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Know how to analyse and characterise polymer and inorganic materials as an expert 1- Study of IR-Raman vibrational spectroscopy 2- Thermal analyses & DSC NMR: Solid-state nuclear magnetic resonance (NMR) spectroscopy is a powerful tool for analysing amorphous, crystalline and semi-crystalline materials on an atomic scale. This course will cover the principles of different solid-state NMR approaches used to study the chemical structure of solids, as well as their local structure and any dynamic phenomena (molecular movements) present. Such approaches will be illustrated in the case of organic molecular materials, polymer materials, inorganic compounds, hybrid materials and organic/inorganic nanocomposites.

Educational goals

Make students experts on the characterisation and analysis of polymer and inorganic materials. NMR: The first objective of this course is to understand the difference in appearance between NMR spectra obtained in a solid and solution state, and, in particular, the link with several nuclear interactions involved in the appearance of these spectra. Based on these differences, experimental approaches used to obtain so-called "high resolution" solid-state NMR spectra will be introduced. Such spectra are used to determine the chemical structure of solid-state compounds. Secondly, we will illustrate how these solid-state nuclear interactions can be exploited to study the near-atomic environment and local order, including in the case of amorphous solid materials. Finally, examples of the use of solid-state NMR for the study of molecular movements on distinct time scales will be presented and their involvement in the understanding of the macroscopic behaviour of these materials will be covered.

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Final exam with a repeat session.

Online resources

PowerPoint courses made available to students. NMR: Electronic version (PDF files) of course materials (two course chapters).

Pedagogy

Lectures/Tutorials with case studies. NMR: Six-hour course (four sessions of one hour and 30 minutes), with systematic illustrations using examples, mainly from publications. Some practical aspects of the approaches used in solid-state NMR are also presented.

Sequencing / learning methods

Number of hours - Lectures :	18
Number of hours - Tutorial :	6
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Prior knowledge of vibrational spectroscopy & thermal analyses. NMR: Basic concepts of solution-state NMR spectroscopy could help, by comparison, students to understand the phenomena determining the appearance of the spectra obtained by solid-state NMR spectroscopy.

Maximum number of registrants

Remarks

Course label :	Experimental project
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_PRE - Projet expérimental

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

- Analysis of the physico-chemical structure of a multi-material object and selection criteria

Educational goals

Role play: Which technique to choose to get the information you're looking for - Impact of sampling on information

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Report and final exam

Online resources

Analysis platforms of the Chevreul Institute and the Catalysis and Solid-State Chemistry Unit (UCCS) and Materials and Transformations Unit (UMET) laboratories

Pedagogy

In-person course - Flipped project approach - Case studies

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	12
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Pre-orientation course unit for the first year of the master's degree (M1), core curriculum 1, 2, 4 and 5, or equivalent

Maximum number of registrants

Remarks

Mandatory course for both the ISP (polymer systems engineering) and MI2E (inorganic materials for energy and the environment) specialisations in the IPME (polymers and materials for the environment) track.

Course label :	CAD and additive manufacturing
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX / Mister PIERRE HOTTEBART
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_CAO - CAO et Fabrication additive

Education team

Teachers : Mister FREDERIC CAZAUX / Mister PIERRE HOTTEBART
External contributors (business, research, secondary education): various temporary teachers

Summary

This course allows students to learn the basic concepts of computer-aided modelling for mechanical systems. With the help of 3D printing, students will also learn how to turn their virtual models into physical prototypes. The CAD software is CATIA-V5.

Educational goals

At the end of the course, students will be able to: - Analyse the mechanical functions of a product - Structure the design approach - Define a modelling method - Find their bearings in the steps of the product development process - Use Catia V5 software - Part modelling module - Part assembly module - Part drafting and assembly module - Implement the different steps to create a 3D print using a CAD model

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: One continuous assessment mark

Online resources

- Room CA0: B-023 or B-030 at Ecole Centrale - Catia V5

Pedagogy

CAD tutorial/practical work and prototyping Duration: Four hours: Sketches and drafting parts using the CAD tool Four hours: Creation of assemblies, designing a small mechanical system (1/2) Two hours: Designing a small mechanical system (2/2), rapid prototyping Four hours: Rapid prototyping and design evolution

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	14
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

None

Maximum number of registrants

Remarks

Course label :	Digital simulation
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX / Mister PIERRE HOTTEBART
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_SNU - Simulation numérique

Education team

Teachers : Mister FREDERIC CAZAUX / Mister PIERRE HOTTEBART
External contributors (business, research, secondary education): various temporary teachers

Summary

In a few years, rapid prototyping has established itself as new means of production in many industrial sectors while also offering new possibilities in terms of design. The purpose of this elective is to help students to discover prototyping and understand its advantages, challenges and limits.

Educational goals

At the end of the course, students will be able to: - Compare various 3D printing techniques - Define a 3D printing strategy taking into account dimensional, rheological and economic aspects - Generate digital models used to control production machines - Implement the different steps - Choose duplication methods for resin parts and metal parts - Implement these different duplication methods - Analyse the parts obtained and find possible improvements for the process

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: One continuous assessment mark

Online resources

- Rapid Prototyping Laboratory - Room CA0

Pedagogy

Prototyping lecture/tutorial/practical work Programme: Session 1: Prototyping ￜ Overview ￜ Specificities of the different processes ￜ Industrial challenges Session 2: 3D printing, silicone moulding and obtaining resin parts Session 3: Moulding using a refractory mould to obtain metal parts Session 4: Obtaining parts in a foundry and finishing

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	14
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

None

Maximum number of registrants

Remarks

Course label :	Shaping of thermoplastics and composites
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_MFT - Mise en forme des thermoplasti

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	16
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	Shaping textiles and nanofibres
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_MFN - Mise en forme des textiles et

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

After an explanation of how electrospinning works and the different types of parameters influencing the manufacture of electrospun membranes, students will have to choose which parameters to study, and carry out trials accordingly. During a second session, the scanning electron microscopy analyses of the membranes obtained in this manner will make it possible to determine the quality and distribution of the fibres obtained.

Educational goals

Understand how electrospinning works, including the parameters influencing the formation of polymer nanofibres. Be able to fittingly choose a series of tests in order to understand a specific phenomenon. Understand the concepts of the fields of application and the usefulness of electrospun membranes.

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Students will be assessed on a report submitted to the teacher.

Online resources

Pedagogy

At the Materials and Transformations Unit (UMET) laboratory, students will be provided with an electrospinning device as well as a Hitachi Flex SEM1000 scanning electron microscope. The solutions used for electrospinning as well as all the consumables for electrospinning and scanning electron microscopy will also be provided. A course handout presenting the theme and the work to be carried out will be provided.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	10
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Fundamentals of the physico-chemistry of polymers (notions of viscosity/rheological behaviour), basic understanding of polymer shaping.

Maximum number of registrants

Remarks

Course label :	Advanced Polymerisation Catalysis
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_CPA - Catalyse de polymérisation ava

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

After reviewing the general catalysis concepts and the associated (industrial and societal) issues, a contextual overview is given of the specific issues (the basic stages, control of macromolecular quantities, stereochemical aspects) of polymerisation and polymers concerned by catalytic synthesis. The course then covers in detail the heterogeneous coordination polymerisation catalysis (known as "Ziegler-Natta") of olefins: history, products obtained, catalysts and co-catalysts, mechanisms. The alternative catalysis to chromium is also presented. Subsequently, the homogeneous catalysis is discussed in detail (organometallic complexes: metallocenes, post-metallocenes, MAO, boron activators, mechanisms and the impact of ligands and geometry of complexes on stereochemistry), with a brief presentation of the supported catalysis. The specific cases of styrene coordination polymerisation, conjugated dienes and cyclic olefins are covered, as well as recent developments in the field (chain walking and chain shuttling). Finally, ring-opening polymerisation (ROP) and biodegradable polymers complete this comprehensive and in-depth overview of polymerisation catalysis.

Educational goals

Have an overview of the coordination polymerisation processes, the reaction mechanisms involved, the basic bricks involved and the variety of products accessible. Be able to understand and explain how catalysts work, and be able to give major examples of applications in the field.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written test (one hour), questions from courses and exercises, analysis of scientific publications

Online resources

Reference works: "La polymï¿œrisation, principes et applications" (Polymerisation, principles and applications). G. Odian. Polytechnica; "Catalyse de polymï¿œrisation" (Polymerisation catalysis). T. Senninger. Techniques de l'ingï¿œnieur (Engineering techniques) publications; "Fifty Years of Ziegler-Natta Polymerization: From Serendipity to Science. A Personal Account". J.J. Eisch. Organometallics, 2012, doi: 10.1021/om300349x; "Polyolefins: 50 years after Ziegler and Natta II. Polyolefins by Metallocenes and Other Single-Site Catalysts". Walter Kaminsky. Ed., Adv. Polym. Sci, 258, 2013 (Springer); "From Multisite Polymerization Catalysis to Sustainable Materials and All-Polyolefin Composites". R. Mulhaupt and coll. Chem Rev. 2016, doi: 10.1021/acs.chemrev.5b00310; Educational materials from the French Polymer Group (GFP).

Pedagogy

PowerPoint presentation with printouts to be completed. Application exercises.

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Third-year level (L3) of organic chemistry and coordination chemistry: reactivity chemistry, notions of stereochemistry and spectroscopic methods, fundamentals of organometallic chemistry and polymer chemistry.

Maximum number of registrants

Remarks

Course label :	Controlled polymerisation
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_POC - Polymérisations contrôlées

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

This course covers the main methods for chemically modifying polymers as well as the controlled radical polymerisation strategies developed to access polymers with perfectly defined macromolecular parameters. The course also illustrates the potential of these strategies to design so-called macromolecular "smart" structures that can be stimulated.

Educational goals

The main objective of the courses and tutorials is to build on engineering students' knowledge of the chemical modification of polymers and to provide them with a solid foundation of scientific knowledge on the development and study of polymer material properties that can be stimulated. At the end of this course, students will be able to design and develop polymers on a toll basis and manipulate their properties under stimulus.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written exam (one hour)

Online resources

Course document to be completed during the session + application exercises and publications sent as PDFs

Pedagogy

PowerPoint presentation. Application exercises.

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic principles of organic chemistry/basic concepts of polymer chemistry and physico-chemistry.

Maximum number of registrants

Remarks

Course label :	Polymers and nanostructures
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_PEN - Polymères et nanostructuration

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Gain in-depth knowledge of surface functionalisation techniques and methods used to characterise these surfaces

Educational goals

Make students experts in surface functionalisation (physical and chemical) and characterisation methods

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Final exam with a repeat session

Online resources

PowerPoint courses made available to students

Pedagogy

Lecture/Tutorials with case study

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Prior knowledge of classic characterisation techniques. Notions of organic chemistry and surface physico-chemistry

Maximum number of registrants

Remarks

Course label :	Associative polymers and polymers in solutions
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_PSA - Polymères en solution et assoc

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Associative polymers and polymers in solutions: This course focuses on natural and synthetic hydrophilic and water-soluble polymers. It covers in detail the chemical structure of these polymers, their properties in solutions and their applications. First, the course presents the general information on water-soluble and hydrophilic polymers, from the point of view of their chemical composition, polymer-solvent interactions, and their behaviour in solutions (concept of conformation). The course then reviews different classes of natural polymers (polysaccharides and proteins), chemically modified natural polymers and synthetic polymers making up both classes of polyelectrolytes and polyamphiphiles. Students study the influence of the composition of these polymers (intrinsic parameters) and solution parameters (extrinsic) on their conformation and their consequences on the physico-chemical properties of the solution (viscosity, etc.). Finally, the course covers the study of hydrogels according to their formation mechanisms (chemical and physical hydrogels) and their characterisation using rheology. Different applications illustrate the courses in the cosmetics, food and biomedical sectors. Microencapsulation: This course presents through different applications the principle and the various processes of microencapsulation. Initially, the concept of microcapsule/microsphere is described, the interest of this technique and the possible release mechanisms of active agents. A review of the various microencapsulation processes used in industry is presented (interfacial polymerisation, coacervation, atomisation, etc.). The intrinsic parameters (associated with the composition [colloids, etc.] and the structure of the particle) and extrinsic parameters (dependent on external factors [temperature, humidity, pH, etc.] influencing the release kinetics are presented.

Educational goals

Associative polymers and polymers in solutions: Provide students with knowledge on the origin and chemical composition of the different types and classes of existing water-soluble and hydrophilic polymers. Thanks to this course, they will be able to predict the influence of parameters intrinsic to the polymer (its nature, molar mass, etc.), and those of extrinsic solution parameters (temperature, pH, salinity, etc.) on the physico-chemical properties of solutions and thereby understand their role within cosmetic compositions, food, paints, etc. The final part of the course, devoted to hydrogels, will give students knowledge of the mechanisms and parameters for the formation of chemical and physical hydrogels (reticulation, self-association, polyelectrolyte complexes, etc.) from uncharged polymers, polyelectrolytes, and amphiphilic polymers. The basic concepts of rheology seen in this chapter will allow students to characterise a sol-gel transition and quantify the viscoelastic parameters of hydrogels. Students will have the theoretical knowledge to address problems in which hydrophilic or water-soluble polymers could provide solutions for the formulation of cosmetics, food compositions, medical devices, etc. Microencapsulation: The aim of the course is to teach students the different processes for encapsulating active ingredients, and to be able to choose the one that would be most appropriate when faced with an issue that they might encounter in industry (pharmaceutical sector, food industry, etc.). The aim is also for students to be able to characterise the microparticles and choose the appropriate analytical techniques in order to control the effectiveness of the encapsulation process used, both in terms of the content of the active ingredient incorporated in the microparticle and in the release kinetics of the active ingredient.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Associative polymers and polymers in solutions: Written test (two hours and 30 minutes), course questions, analysis of scientific publications Microencapsulation: Written test (one hour), course questions and exercises, analysis of scientific publications

Online resources

Associative polymers and polymers in solutions: "Polymers in aqueous media". ACS, ISBN 0-8412-1548-0 "Polyï¿œlectrolytes et nanoparticules" (Polyelectrolytes and nanoparticles). Springer, ISBN 13 978-3-540-46382-5 Microencapsulation "Microencapsulation: Methods and Industrial Applications". Second edition, ISBN 9780824723170

Pedagogy

Associative polymers and polymers in solutions:v Lectures accompanied by a slide show provided to students electronically. Supervised application exercises often using publications to be analysed. Microencapsulation: Lectures accompanied by a slide show provided to students electronically. Supervised application exercises often using publications to be analysed.

Sequencing / learning methods

Number of hours - Lectures :	21
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Associative polymers and polymers in solutions: First-year master's degree (M1) level for polymer chemistry and polymer physico-chemistry Microencapsulation: First-year master's degree (M1) level for polymer chemistry + prior knowledge of water-soluble and associative polymers

Maximum number of registrants

Remarks

Course label :	Mechanical behaviour of solid polymers
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_CMP - Comportement mécanique des po

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

General concepts of material mechanics: Stress and deformation tensors. Elastic behaviour ￜ Hooke's law Visco-elastic behaviour ￜ Basic rheological models Plastic behaviour and characteristics of microscopic mechanisms of plasticity and damage. Polymer fracture

Educational goals

Provide students with the necessary fundamentals for analysing mechanical behaviour, utilising a mechanical test, and understanding the influence of structure and experimental conditions on the mechanical response of a polymer material.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: One final exam (two hours)

Online resources

Various reference works ("Introduction ￜ la mￜcanique des polymￜres" [Introduction to polymer mechanics] by G'Sell and J-M Haudin, "Traitￜ des matￜriaux: Matￜriaux Polymￜres: propriￜtￜs mￜcaniques et physiques" [Polymer materials: mechanical and physical properties] (vol. 14), "Introduction ￜ la physique des polymￜres" [Introduction to polymer physics] by S. Etienne and L. David, "Principles of polymer engineering' by Bucknall et al.

Pedagogy

Lectures and tutorials (50%/50%) PowerPoint presentation

Sequencing / learning methods

Number of hours - Lectures :	15
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Polymer physics: Structure and cohesion of solid-state polymer materials Some general mechanical concepts

Maximum number of registrants

Remarks

Course label :	Rheology of gels and solids
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_RGS - Rhéologie des gels et solides

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

After reviewing the general concepts related to the structure and physico-chemical properties of polymers, students are introduced to rheology, in a broad sense, and its applications. The course then covers in detail: - The different rheological behaviours - The rheological behaviour of thermoplastic polymers - The interpretation of this/(these) rheological behaviour(s) in terms of macromolecular structure - The influence of different parameters on rheological behaviour (temperature, pressure, etc.) - Viscosity measurement methods Practical work particularly illustrates monitoring a hydrogel's formation.

Educational goals

Have a general understanding of the rheological behaviour of polymers, the structural origin and the implications on polymer shaping. Know how to use the basic functions of a rheometer and analyse information obtained from it.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: A written deliverable on a concrete case study A practical work report

Online resources

Educational materials from the French Polymer Group (GFP)

Pedagogy

Course given with PowerPoint presentations

Sequencing / learning methods

Number of hours - Lectures :	15
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Knowledge of the macromolecular structure of polymers and their physico-chemical properties. Course on gel rheology Course on associative polymers and polymers in solutions

Maximum number of registrants

Remarks

Course label :	Energy storage and conversion materials
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_MSC - Matériaux de stockage et de co

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

- Materials for future energies: context, barriers and applications: energy generation (thermoelectricity, batteries, fuel cells, etc.), storage and transport (hydrogen vector, etc.) - Structure/physical properties relationships: Ionic conductors, electronic conductors/insulators, thermoelectrics, magnetic properties, etc. - Concepts of solid-state chemistry: coordination numbers, stability, structural transformations and structures, defects, substitution, doping. - Synthesis and shaping methods: "classic high temperatures", ceramics, hydrothermal, controlled atmospheres, crystalline growth and "new low temperatures", soft chemistry, topotactic transitions, in solutions, in ionic liquids, etc.

Educational goals

- Understand the concepts of solid-state chemistry to design and develop new materials with physical properties determined according to the applications sought. - Know how to read an in-depth scientific article in English and be able to implement a bibliographic strategy to understand all its concepts and purposes. - Be able to understand a scientific issue through articles from scientific journals.

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: 50% continuous assessment using the project/problem-based learning approach (oral presentations + written reports) (50%) and a final exam (50%) (written exam)

Online resources

The necessary course and bibliographic elements are available on the course's Moodle page as well as on dedicated websites (online courses from the French Academy of Sciences, Web of Science, bibliographic research via the Lilliad centre, etc.)

Pedagogy

In-person course - Case studies - The course is in French but the bibliographical documents are in English - Most of the module (90%) uses the project/problem-based learning approach and the Lilliad centre's resources for this purpose (rooms and laptops).

Sequencing / learning methods

Number of hours - Lectures :	8
Number of hours - Tutorial :	18
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

"Materials" pre-specialisation course units for the first year of the master's degree (M1), or equivalent

Maximum number of registrants

Remarks

- Mandatory course for the MI2E (inorganic materials for energy and the environment) specialisation, and an optional course for the ISP (polymer systems engineering) specialisation in the IPME (polymers and materials for the environment) track.

Course label :	Conductive polymers
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_PCO - Polymères conducteurs

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Review of general concepts of semiconductor materials Definition of organic semiconductors (OSC)/conductive polymers Description of charge transport in these materials Description of anodes and cathodes ￜ metal/OSC interface Description of energy conversion devices using OSCs (organic photovoltaic cells, organic light-emitting diodes, thermoelectric generators, etc.) Introduction to energy conversion devices that do not use OSCs (piezoelectric devices, photochromic devices, etc.)

Educational goals

Be familiar with/identify conductive polymers and have a good understanding of their transport mechanisms Be able to explain the operating principle of a set of energy conversion devices based on organic/polymer materials

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written test

Online resources

Book entitled "Polymer Materials for Energy and Electronic Applications". H. Peng, X. Sun, W. Weng, X. Fang, Elsevier, 2017

Pedagogy

PowerPoint presentation with printouts

Sequencing / learning methods

Number of hours - Lectures :	12
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic concepts of physics - Bachelor's degree level

Maximum number of registrants

Remarks

Course label :	Formulation of paints and varnishes
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_FPV - Formulation des Peintures et v

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

1-Resins: Polyesters, Alkyds, Polyurethanes, Epoxides, etc. 2-Paint film drying mechanisms 3-Pigments and fillers (organic and mineral) 4-Additives 5-Formulation of a paint 6-Discussion on guidance formulas 7-Exercises: Calculation of dry extracts (ES) of volume pigment concentrations (CPV)

Educational goals

To give students the basics to understand the different raw materials present in a painting. To provide a knowledge base that will allow the student to formulate paintings. To know how to recognize an aqueous paint, a solvent phase paint. To know how to calculate with the critical CPV, whether a paint will be matte, satin or gloss. To recognize its drying method (in air, in the oven, by condensation reaction, addition, etc.).

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: 1h30 exam, without document

Online resources

"Techniques de l'Ingￜnieur: Formulation des peintures - Physico-chimie et matiￜres pulvￜrulentes" (Engineering techniques: formulation of paints ￜ Physico-chemistry and powdery substances), Jean-Claude Laout, J2270 (2005)

Pedagogy

Handout distributed, course in powerpoint

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

L3 organic chemistry and polymer course

Maximum number of registrants

Remarks

Types and sectors of activity for which this course prepares: Ink and paint industries, where the student will be asked to be able to mix different ingredients (solvents, binders, pigments, fillers, additives) so as to obtain a formulated product possessing the desired properties while meeting the specifications charge.

Course label :	Functional textiles
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_TEF - Textiles fonctionnels

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

This course discusses in detail the processes for developing added-value textiles thanks to specific properties for certain applications, such as biomedical devices (implants and textile prostheses), air filtration (protective masks) and contaminated water, etc. After introducing the different natural and synthetic materials and the different forms of traditional textiles, the course presents the different processes for depositing surface coatings (coating and layer-by-layer deposition) and textile surface treatments using chemical and physical methods (plasma, electronic bombardment, gamma rays, UV-curing, polycondensation) or polymer electrospinning to obtain nanofibre textiles. Concrete examples of applications are discussed as the different processes are covered.

Educational goals

Provide students with general knowledge of the different types of technical textiles used in different technological fields, and identify what gives them added value and how they achieve it. To provide students with theoretical knowledge of the functionalisation processes applicable to textiles, from the point of view of specific usable equipment, process steps, the influence of process parameters, and the related chemical reactions depending on the mechanisms (grafting-from and grafting-onto polymerisation). Teach students to choose qualitative and quantitative characterisation techniques for functionalised textiles (dosimetric, spectroscopic and microscopic techniques, etc.). Thanks to examples illustrated during the course, they learn how to choose a functional molecule, monomer and polymer to undergo electrospinning or to be immobilised on the textile medium in order to give it various properties, such as ion exchange, antimicrobial activity or anti-stain treatment.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written test (two hours), questions from courses, analysis of scientific publications.

Online resources

"Biopolymer Grafting: Applications". ISBN: 9780128104620, eBook ISBN: 978012810463 "Medical and healthcare textiles". ISBN 978-1-84569-224-7 "Active coatings for smart textiles". ISBN 978-0-08-100263-6 Educational materials from the French Polymer Group (GFP).

Pedagogy

A PowerPoint presentation of the course is provided to students electronically. Supervised application exercises often using publications to be analysed.

Sequencing / learning methods

Number of hours - Lectures :	14
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

First-year master's degree (M1) level for organic chemistry and polymer chemistry; knowledge of spectroscopic techniques (Fourier-transform infrared spectroscopy [FTIR], UV-visible, solid-state NMR)

Maximum number of registrants

Remarks

Course label :	Glues and adhesion
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_CEA - Colles et adhésion

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

This course covers the details of various phenomena related to adhesion, the different classifications of adhesives and the preparation of materials for glue optimisation. Firstly, adhesion mechanisms (chemical, physical, electrical, etc.) are presented with details on phenomena at the adhesive-substrate interfaces (surface chemistry). The various industrial processes for preparing substrates (plasma, washing, etc.) on polymer and metal materials are presented. Polymers used in the different classes of glues and their reactivity are explained in detail (chemistry of glues). Glues will be classified according to their hardening process, shape or chemical composition.

Educational goals

The aim of the course is to provide students with theoretical knowledge for solving glue-related issues in various industrial fields, including the biomedical sector: which glue should be chosen based on the substrate to be glued and depending on the assembly's use conditions? Which preparation should be applied to the substrate beforehand?

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written test (30 minutes), course questions and exercise for simulating a glue-related issue.

Online resources

"Science et technologie du collage" (Glue science and technology) (Cognard). Presses polytechniques et universitaires romandes, ISBN 2-88074-410-5

Pedagogy

Lectures supported by a slide show provided to students electronically.

Sequencing / learning methods

Number of hours - Lectures :	6
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

First-year master's degree (M1) level for chemistry of polymers, basic knowledge of surface characterisation techniques.

Maximum number of registrants

Remarks

Course label :	Nanocomposites
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_NAN - Nanocomposites

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

General information on polymer matrix composites Architecture and mechanical properties (elastic deformation) of composites Advantage of nanocomposites ￜ Description of 0D, 1D and 2D nano-objects Impact on the polymer matrix structure Viscoelastic properties of nanocomposites Electrical properties of nanocomposites based on conductive nanofillers

Educational goals

Have a general understanding of composites and nanocomposites Be able to describe different types of nanometric fillers Be able to explain the impact of nanofillers on the structure and viscoelastic or electrical properties of nanocomposites

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Written test

Online resources

"Polymer Nanocomposites". Yiu-Wing Mai Zhong-Zhen Yu, Elsevier, 2006; "Polymer matrix composites and technology". R.-M. Wang, S.-R. Zheng, Y.-P. Zheng, Elsevier, 2011; "Polymer Nanocomposites Handbook". Rakesh K. Gupta, Elliot Kennel, Kwang-Jea Kim, CRC Press, 2009, "Carbon Nanotubes". M.S. Dresselhaus, G. Dresselhaus, Ph. Avouris, Springer, 2001

Pedagogy

PowerPoint presentation with supporting documents printed out

Sequencing / learning methods

Number of hours - Lectures :	10
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic concepts of physics - Bachelor's degree level

Maximum number of registrants

Remarks

Course label :	Polymers and fire resistance
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_PTF - Polymères et tenue au feu

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

This six-hour course covers polymer fireproofing and addresses the following themes: - General information on combustion and the different phases of fire development - Concepts of fire reaction and resistance - Standardisation and the major associated tests/trials - Polymer fireproofing strategies - Fire retardant action mechanisms - Main families of fire retardants

Educational goals

Acquire the main concepts relating to polymer fireproofing. Be able to use this knowledge to understand scientific articles or to converse with an industrial stakeholder working in the sector.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Final one-hour exam with application of the concepts seen in class, based on an article taken from a scientific publication.

Online resources

Course materials provided to the students.

Pedagogy

Slide show presented to the students; course illustrated by examples from recent scientific publications.

Sequencing / learning methods

Number of hours - Lectures :	6
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Knowledge on polymers: implementation methods and general synthesis mechanisms.

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_ARC - Affaires réglementaires - Clas

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	4
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_BBI - Biomatériaux & Biosystème

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	5
Number of hours - Tutorial :	1
Number of hours - Practical work :	3
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_CDT - Constitution Dossier Technique

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	6
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_DID - Développement industriel de di

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	6
Number of hours - Tutorial :	3
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_AMB - Alliages métalliques et biosys

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	4
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	Materials and the circular economy
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_MEC - Matériaux et économie circulai

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Brief programme: - Waste issues: regulations and treatment channels (two hours of lectures, four hours of tutorials), introduction to radiation protection (two hours) - The methods and concepts of (i) life cycle analysis (LCA): introduction to LCA, methodology, environmental impact of the manufacturing, use and disposal stages, important parameters when assessing the life cycle of a material. (ii) eco-design (int. ext. Act-Environment): context, internal pollution, tools (LCA, FDSE, HQE), environmental debt, carbon footprint approach, application on a particular product (four hours of lectures, four hours of tutorials, ten hours of practical work, including four hours of site visits) - Treatment and recycling of plastic waste (four hours of lectures) - Case study: phosphates: industrial aspects, environmental problems (phosphogypsum and eutrophication), recycling and recovery. (two hours of lectures, two hours of tutorials)

Educational goals

- Fully understand the concepts and know the standards and certifications that regulate the fields of recycling, eco-design and recovery. - Know how to critically use assessment tools and methods (life cycle analysis [LCA], environmental and health declarations, etc.) specific to this field. - Acquire the eco-design fundamentals and the High Environmental Quality (Haute Qualitￜ Environnementale ￜ HQE) approach and put these concepts into practice on a particular product. - Know the main recycling and recovery channels for waste in general and waste related to chemistry in particular and the regulations associated with their management.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: Final exam (written exam) (70%) + mark for the mini-project (30%).

Online resources

The necessary course and bibliographic elements are available on the course's Moodle page as well as on dedicated websites (Web of Science, bibliographic research via the Lilliad centre, etc.)

Pedagogy

In-person course - The tutorials are organised into mini-projects (the project/problem-based learning approach) and practical work consists of case studies that make use of specific software for life cycle analysis (LCA). - Site visits are planned.

Sequencing / learning methods

Number of hours - Lectures :	14
Number of hours - Tutorial :	10
Number of hours - Practical work :	10
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

"Materials" pre-specialisation course units for the first year of the master's degree (M1), or equivalent

Maximum number of registrants

Remarks

Mandatory course for the MI2E (inorganic materials for energy and the environment) specialisation, and an optional course for the ISP (polymer systems engineering) specialisation in the IPME (polymers and materials for the environment) track.

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S3_QUA - Qualité

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	32
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	ESO / Business and Society
Teaching manager :	Mister REMI BACHELET
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S4_OGP - Outils de gestion de projet

Education team

Teachers : Mister REMI BACHELET
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_ISP_S4_ESF - Expérimentation ss forme chall

Education team

Teachers : Mister FREDERIC CAZAUX
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :
Teaching departement :	CMA /
Teaching manager :
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	-

Education team

Teachers :
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks