Master in Chemistry / Polymer Engineering and Materials for the Environment Track / Advanced Inorganic Materials for the Envrionment Speciality

Course label :	Quality
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_QUA - Qualité

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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 :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_BIB - Biomatériaux & Biosystème

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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 :	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_MIAE_S3_AMB - Alliages métalliques et biosys

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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_MIAE_S3_DID - Développement industriel de di

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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_MIAE_S3_CDT - Constitution Dossier Technique

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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_MIAE_S3_ARC - Affaires réglementaires - Clas

Education team

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

Summary

Does not apply to students enrolled at Ecole Centrale

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 for nuclear energy -2 Materials and Safety
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_MN2 - Matériaux du nucléaire-2 Matér

Education team

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

Summary

This multidisciplinary course combines several scientific disciplines and different areas of nuclear activity: chemistry, physics, mechanics and modelling. It aims to provide the generalist skills needed to understand the complex questions posed by nuclear technologies. It also aims to make students aware of the socio-economic concerns that characterise nuclear technology. More specifically, the module addresses issues related to electro-nuclear energy through current systems (reactors and fuels), their technological and societal developments and operating problems (safety, waste management, environmental releases, etc.). The module consists of three knowledge blocks: - I: ageing of materials: irradiation resistance of structural materials, change in mechanical properties, decay mechanisms, corrosion, (metals), geopolymer confinement matrices, leaching (matrices) - II: Atomic scale modelling (in the form of practical work): presentation of methods, practical exercises on damage in metallic materials and on the migration of fission products - III: safety: migration of fission products in plant circuits and then in the environment

Educational goals

This module is mainly aimed at providing future materials specialists with general know-how on civil nuclear energy. This know-how is specifically focused on skills associated with industrial processes in the nuclear fuel cycle. This know-how allows students to take on the following tasks: - prepare, plan and organise an operation and maintenance assignment in a nuclear environment - oversee this assignment while guaranteeing safety and compliance with regulations, in consultation with the competent services and bodies - capitalise on theoretical knowledge to propose the direction of scientific or technological studies, such as those typically carried out within the framework of a doctorate

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Written final exam (75%) consisting of three independent parts and a practical work report (25%)

Online resources

The necessary course and bibliographic materials 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 entire course will be taught in French. English documents may be provided.

Sequencing / learning methods

Number of hours - Lectures :	6
Number of hours - Tutorial :	2
Number of hours - Practical work :	4
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 and mastery of basic operations in: - mathematics (first- and second-year level [L1-L2]) on logarithmic functions, differential equations and resolution of usual polynomial equations. - mechanics: definitions and methodology acquired in the electromagnetic compatibility courses (CEM4 and CEM6), optional course units for the first year of the master's degree (M1) ￜ Chemistry - Computer science: mastering basic commands in Unix

Maximum number of registrants

Remarks

Mandatory elective for students enrolled at Ecole Centrale

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_MIAE_S3_ANG - Anglais

Education team

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

Summary

Preparation for the TOEIC

Educational goals

Advanced English

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Final exam

Online resources

Pedagogy

In-person course ￜ Students are divided into groups based on their level

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

English in the first year of the master's degree (Master 1)

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 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_MIAE_S3_DRX - Microscopie et DRX avancées de

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 ￜ 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_MIAE_S3_SAT - Spectroscopies et analyses the

Education team

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

Summary

Acquisition of solid-state NMR, IR and thermal spectroscopies and their coupling for the study of solid materials (polymers and inorganic materials): Case study

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 ￜ case studies

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

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 :	Experimental project
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_PEX - 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 ￜ Flipped project approach ￜ 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 :	Interactions between mineral matter and the environment
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_IMM - Interactions matière minérale

Education team

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

Summary

Brief programme: 1. Introduction of concrete/containment matrices (Univ. Lille, F. Mï¿œar, seven and a half hours of lectures/tutorials): (i) introduction to cementitious materials: general information, manufacture and hydration reactions; (ii) presentation of the various ultimate storage alternatives for nuclear waste, including high-, medium- and low-activity waste. Vitrification, inorganic binder matrices, alternative matrices for special waste (problem of caesium, iodine and sulphates). 2. Cementitious materials (Eqiom, C. Charron, eight hours of lectures): presentation of the cement industry and the company's actions. Methods for formulating cements/concretes depending on the environment (soil pH, saline environments, etc.) and use. Highlighted using concrete examples. 3. Leaching, chemical durability (CEA, L. Campayo, six hours of lectures): presentation of leaching tests and standardisation. Ageing mechanisms: aqueous alteration, influence of intrinsic parameters (structure and composition) and extrinsic parameters (temperature in ï¿œC, pH, ionic strength). Kinetic aspects of alteration, structure of corrosion gels and diffusion layers, methodology for studying long-term behaviour. Study methodology, examination of standardised tests, methods for characterising altered surfaces. 4. Treatment of chemical and/or radioactive effluents (Orano, B. Morel, six hours of lectures): presentation of normative aspects and decontamination processes (concentration by evaporation, precipitation and filtration, sorption, membrane processes, treatment of organic matter). 5. Mineral processing and material sorting (Severine Marquis, four and a half hours of lectures/tutorials, two hours of practical work)

Educational goals

The purpose of this course unit is to study the interactions between mineral matter and the environment: management of waste from construction, nuclear energy, etc., formulation of technical concretes for construction and containment matrices for nuclear energy. - Knowledge: Interactions between mineral matter and the environment. Alteration and corrosion mechanisms. Concepts and methods. Normative aspects. - Skills: 1-ability to understand the alteration phenomena and to deduce suitable solutions from them; 2-knowledge of alterations between mineral matter and the environment; 3-ability to write a summary; 4-ability to present one's work

Sustainable development goals

Knowledge control procedures

Continuous Assessment
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 - Case studies - The tutorials are organised into mini-bibliographic projects and site visits are planned. - Part of the course is taught by industry experts from the sector: EQIOM, CEA (the French Alternative Energies and Atomic Energy Commission), ORANO, Centre terre et Pierre, and others.

Sequencing / learning methods

Number of hours - Lectures :	16
Number of hours - Tutorial :	4
Number of hours - Practical work :	2
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

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_MIAE_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) - Processing 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, 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
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 :	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_MIAE_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: 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 :	Physical measurements and characterisations
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_MPC - Mesures physiques et caractéri

Education team

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

Summary

Brief programme: physics of semiconductors; techniques for measuring their physical properties; application to thermoelectricity. This module covers the physics of semiconductor materials through techniques for measuring their physical properties (essentially electrical and thermal) and through one of their specific applications for energy conversion and thermoelectricity, which makes it possible to convert heat into electricity or vice versa.

Educational goals

- Know how to define the physical quantities that determine the properties of a semiconductor material: electrical and thermal conductivity, Seebeck coefficient, figure of merit - Know how to describe and explain in a clear and concise manner the different methods for measuring these quantities - Be able to explain how a thermoelectric generator works - Know how to state the major families of thermoelectric materials, their advantages and disadvantages and the various current improvement strategies - 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: 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 (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 - The entire module 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 :	10
Number of hours - Tutorial :	14
Number of hours - Practical work :	4
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

No specific prerequisites, concepts of physics from the first and second years (L1 and L2)

Maximum number of registrants

Remarks

Course label :	Materials for nuclear energy -1 Fuel cycle
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_MN1 - Matériaux du nucléaire-1 Cycle

Education team

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

Summary

This multidisciplinary course combines several scientific disciplines and different areas of nuclear activity: chemistry and radiochemistry, subatomic physics, basic principle of the design of a nuclear reactor and a historical review of the scientific context. It aims to provide the generalist skills needed to understand the complex questions posed by nuclear technologies. It also aims to raise student awareness of the socio-economic concerns that characterise nuclear technology. More specifically, the module addresses issues related to electro-nuclear energy through current systems (reactors and fuels), their technological and societal developments and operating problems (safety, resource and cost management, waste management, etc.). Students will be put in contact with joint teams of research professors and experts to acquire theoretical knowledge and industrial practices. The module consists of three knowledge blocks: - I: background, history of nuclear development, overview of the various nuclear power reactors in the world. Storage scenarios associated with decay periods and radiotoxicity (short ￜ medium ￜ long) - II: Radioactivity and upstream of the cycle: the different radioactive emissions and decays, associated energies and definition of effective macroscopic sections; extraction, chemistry, enrichment and production of fuel - III: Downstream of the cycle: storage, reprocessing, recovery of Plutonium (Pu), waste flows, conditioning (glass, concrete, inerting, etc.)

Educational goals

This module is mainly aimed at providing future materials specialists with general know-how on civil nuclear energy. This know-how is specifically focused on skills associated with industrial processes in the nuclear fuel cycle. This know-how allows students to take on the following tasks: - prepare, plan and organise an operation and maintenance assignment in a nuclear environment - oversee this assignment while guaranteeing safety and compliance with regulations, in consultation with the competent services and bodies - capitalise on theoretical knowledge to propose the direction of scientific or technological studies, such as those typically carried out within the framework of a doctorate

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Written final exam (66%), consisting of two independent parts, and continuous assessment in the form of the composition of a summary report (34%)

Online resources

The necessary course and bibliographic materials 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 entire course will be taught in French. Documents in English may be provided. Part of the course is taught by industry experts (from Orano):

Sequencing / learning methods

Number of hours - Lectures :	16
Number of hours - Tutorial :	4
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 and mastery of basic operations in: - mathematics (first- and second-year level [L1-L2]) on logarithmic functions, differential equations and resolution of usual polynomial equations - Subatomic physics: definition of radioactivity, good understanding of the notions of radioactive periods and the main nuclear decay processes - Chemistry: redox phenomena, solubility, reaction quotients and chemical equilibriums associated with thermodynamics (Gibbs free energy of a reaction) and reaction kinetics

Maximum number of registrants

Remarks

Mandatory course for the MI2E (inorganic materials for energy and the environment) specialisation

Course label :	Nanomaterials and thin films
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_NCM - Nanomatériaux et couches mince

Education team

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

Summary

With the development of nanotechnologies and the race to miniaturise, knowledge of the synthesis methods, the characterisation of nanomaterials, and nanostructured thin films is essential. The design of multi-functional nanomaterials opens the door to the extreme miniaturisation of devices and the reduction of size allows for the exploration of new physico-chemical phenomena. The objective of this course section is therefore to present an overview of synthesis techniques and (experimental and digital) tools for characterising thin-film nanomaterials. Applications using nanocompounds are shown. Brief programme : - Physical deposition techniques: cathode sputtering, pulsed laser ablation, molecular-beam epitaxy, etc. - Chemical deposition techniques: vapour phase deposits, solution deposits, etc. - Vacuum measurement ￜ Vacuum gauges - Manufacture of nano-objects: top-down and bottom-up approaches - Methods for synthesising oxides and nanostructured metals using soft chemistry, such as coprecipitation, sol-gel and/or hydrothermal synthesis - Techniques for characterising the size of crystallites (X-ray diffraction, transmission electron microscopes [TEM] and dynamic light scattering [DLS]) - Simulation techniques at atomic scale: Density-functional theory, molecular dynamics and Monte-Carlo - Calculation of the electronic structure of nanomaterials - Simulation codes of nanomaterials

Educational goals

- Know how to clearly describe and explain the operating principle of techniques used to synthesise and characterise nanomaterials and thin films - Know how to interpret physico-chemical phenomena involved in nanostructured materials - Know how to clearly describe and explain different digital simulation methods at the nanometre scale Skills acquired: - Ability to understand the operating method and operating principle of techniques used to synthesise thin films - Ability to understand the operating protocol of major synthesis methods using soft chemistry - Ability to understand the techniques commonly used to determine the size of crystallites - Know the different methods for modelling and simulating nanomaterials - Know the different computer programmes used for the study of nanomaterials

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: Final exam (written)

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 entire course will be taught in French. English documents may be provided.

Sequencing / learning methods

Number of hours - Lectures :	24
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

Pre-specialisation course units for "Materials" and Theoretical Chemistry for the bachelor's degree and the first year of the master's degree in Chemistry (M1), or equivalent

Maximum number of registrants

Remarks

Mandatory course for the MI2E (inorganic materials for energy and the environment) specialisation

Course label :	Technological glass
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S3_VET - Verres technologiques

Education team

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

Summary

Brief programme: 1. General information 2. Major glass families 3. Structural models of glass 4. Thermal properties 5. Preparation and shaping methods 6. Relationship of properties ￜ structure ￜ composition 7. Case studies: sealing glasses for fuel cells, glass for nuclear energy, etc.

Educational goals

The aim of this course unit is to study vitreous materials for innovative energy-related applications. - Knowledge: chemistry of glass, properties and application in energy - Skills: know how to analyse material issues, know how to define properties according to usage criteria, link the concepts of materials science and solid-state chemistry to concrete case studies

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Final written exam (70%) + mark for the mini-projects and practical work (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 entire course will be taught in French. Documents in English may be provided. Part of the course is taught by industry experts: Food contact materials, Baccara; Glass and glass-ceramics, Corning

Sequencing / learning methods

Number of hours - Lectures :	20
Number of hours - Tutorial :	8
Number of hours - Practical work :	4
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 in Chemistry (M1), or equivalent

Maximum number of registrants

Remarks

Mandatory course for the MI2E (inorganic materials for energy and the environment) specialisation

Course label :	Experimentation in the form of a challenge
Teaching departement :	CMA /
Teaching manager :	Mister FREDERIC CAZAUX
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S4_EFC - Expérimentation ss forme chall

Education team

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

Summary

Brief programme: experimental project launched by the teaching staff or a company

Educational goals

Know how to propose solutions to address a challenge-based (industrial or research) project by utilising all the knowledge acquired during the master's degree

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: Report written as a publication (50%) and an oral presentation (individual assessment) (50%)

Online resources

The necessary course and bibliographic materials 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 entire course will be taught in French. English documents may be provided.

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

All course units taken in semester 3

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. - Project work per group of no more than five students from the two mixed specialisations

Course label :	Project management tools
Teaching departement :	ESO / Business and Society
Teaching manager :	Mister FREDERIC CAZAUX / Mister REMI BACHELET
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_MIAE_S4_OGP - Outils de gestion de projet

Education team

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

Summary

- Identify the different project profiles in companies - Organise effective meetings - Lead the project cycle and manage risks - Define batches and responsibilities - Budget and manage the project

Educational goals

Know how to manage a project from A to Z

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

The necessary course and bibliographic materials are available on the course's Moodle page as well as on dedicated websites

Pedagogy

Hybrid - MOOC developed by Centrale Lille - The entire course will be taught in French. English documents may be provided

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

No specific prerequisites

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

Education team

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

Summary

End-of-study project, in a research and development laboratory or in industry, in France or abroad

Educational goals

- Know how to propose solutions to address a project by utilising all the knowledge acquired during the master's degree - Know how to manage a project

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments: End-of-study internship report (40%), oral presentation (30%), advisor's assessment of the internship (30%)

Online resources

Websites dedicated to bibliography (Web of Science, bibliographic research at the Lilliad centre, etc.), resources made available on site

Pedagogy

In-person course

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

All units taken in semester 3 and project management course units

Maximum number of registrants

Remarks

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