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FAME Master University of Bordeaux

« Advanced Hybrid Materials and Ceramics by Design »

19 février 2019 Titre de votre présentation

2

Bordeaux

Lively and trendy city (90 000 plus students, initiatives like Darwin…)

Swimming in the ocean 45 min Surfing (Basque coast) 90 min Skiing and trekking 120 minutes Snack in Paris, 120 minutes …

Materials in Bordeaux

• Historically: Materials

Chemistry

• Functional Materials

and Materials for Energy

• Hybrid, Ceramic,

Metallic, Organic, Composite Materials…

• Materials Engineering:

strong development

• Materials Physics:

strong for LASERS, (LaPHIA Cluster)

Materials

Materials Physics Materials Engineering Materials Chemistry C

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, S t r u c t u r e , P r

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e r t i e s S t a b i l i t y , F

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t r u c t u r e Surface, Interface, Architecture F u n d a m e n t a l u n d e r s t a n d i n g Application Means, Methods

Energy (Micro/Nano)- Electronics Health Storage Li, H… Conversion Photovoltaics Thermoelectrics … (Multi)Ferroics Organic Electronics … Optics Phosphors, Lasers … Biomaterials, Drug delivery … Powders, Ceramics, Thin films, Single Crystals Nanomaterials From chemical substitutions to nano-/micro-/meso-/macro-scale architectured materials Catalysis, Sensors… Photocatalysis Gas sensors …

Advanced Functional Materials

• n the campus

Sustainable (Chemistry of) Materials

Materials Research Environment

Year 2 specialization in Bordeaux « Advanced Hybrid Materials and Ceramics by Design »

* Compulsory courses

6 ECTS 6 ECTS 6 ECTS

written or oral examinations Bibliographic project : defended with Master Thesis, will include extra assignments

Fall Semester Spring Semester

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie

Hybrid and Nano Materials Large Scale Facilities (Including practicals) Biblio. Project

FAME Master : specific curriculum in the « Master of Chemistry »

Year 2 specialization in Bordeaux « Advanced Hybrid Materials and Ceramics by Design »

* Compulsory courses

6 ECTS 6 ECTS 6 ECTS

All lectures welcome international and local students from multiple tracks Fall Semester Spring Semester

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie

Hybrid and Nano Materials Large Scale Facilities (Including practicals) Biblio. Project

Master Thesis 5 months (~550€/month)

written or oral examinations Bibliographic project : defended with Master Thesis, will include extra assignments

Year 2 specialization in Bordeaux « Advanced Hybrid Materials and Ceramics by Design »

* Elective courses (3 out of 6)

Energy, Communic. and Information Photonics, Lasers and Imaging Applied Nanoscience

6 ECTS 6 ECTS 6 ECTS 6 ECTS 6 ECTS

All lectures welcome international and local students from multiple tracks

written or oral examinations Magnetic & Dielectric Properties Innovative & Composite Materials

6 ECTS

Molecular Simulation

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie

• as of 2018, 71% of Bordeaux FAME students started a PhD following their graduation.
• among them, 32% stayed in Bordeaux (including 4 grants from University of Bordeaux

and 3 IDS-FUNMAT grants)

University of Bordeaux Key facts and figures

 One of the three first excellence

campus selected by French government  First University to be awarded a perenial excellence label http://www.idex-univ-bordeaux.fr/

2017 (Shanghaï ranking) France Institutions 151-200 # 7-9 Natural Sciences 101-150 # 9 Chemistry 101-150 # 4 Physics 151-200 # 12

FAME Master University of Bordeaux

« Advanced Hybrid Materials and Ceramics by Design »

For more information…

University of Bordeaux Key facts and figures

50 000+ students, incl.

1 800+ PhD students 6200+ international students

2 900+ academic staff (Prof., Asst.

Prof., Researchers…)

26 international study programmes 90+ research centers, 8 doctoral schools 50 000+ students, incl.

1 800+ PhD students 6200+ international students

2 900+ academic staff (Prof., Asst.

Prof., Researchers…)

26 international study programmes 90+ research centers, 8 doctoral schools

AEROSPACE INDUSTRY MARKETS

AIRCRAFT STRUCTURES AIRBUS

CFRC

CABIN AIR TREATMENT

LIEBHERR AEROSPACE AIRCRAFT ENGINES SNECMA SAFRAN GROUP

CMC

SNECMA PROPULSION SOLIDE ROCKET MOTORS MESSIER BUGATTI

C/C

BRAKE DISCS

CMC

LEGEND CMC : CERAMIC MATRIX COMPOSITES CFRC : CARBON FIBER REINFORCED COMPOSITES C/C : CARBON CARBON COMPOSITES

~ 150 businesses making or processing composite materials (5000 jobs)

Materials in Bordeaux

Materials in Bordeaux

• A number of private European research laboratories – Rhodia/Solvay,

Arkema, Eurovia, Saft, SNPE, SNECMA…

• 10% of the French research capacity for chemistry
• A laboratory for excellence (Labex): AMADEUS, for advanced materials
• ELOR PrintTEC « Equipex » for printable materials and organic systems
• Aquitaine Sustainable Chemistry Initiative (ACD)
• European Multifunctional Materials Institute, EMMI

A FRENCH LEADING POSITION : POLYMER BASED ORGANIC ELECTRONICS

• THE "ELORGA" PLATFORM DESIGNED TO ELABORATE AND CHARACTERIZE ORGANIC

ELECTRONICS DEVICES

A COLLABORATIVE INDUSTRY/RESEARCH PROJECT CULTURE

• ORGANIC LIGHT EMITTING DISPLAYS FOR AVIONICS (e.g. OLEDS)
• FLEXIBLE AND LARGE AREA ORGANIC PHOTOVOLTAIC PANELS FOR ENERGY
• INKS AND DATA STORAGE FOR INFORMATION TECHNOLOGY

http://amadeus.labex-univ-bordeaux.fr/

ELORGA PLATFORM COURTESY : LABORATORY INTEGRATION FROM MATERIAL TO SYSTEM [IMS] COURTESY : CENTRE DE RECHERCHE PAUL PASCAL [CRPP] COURTESY : LABORATORY OF CHEMISTRY OF ORGANIC POLYMER [LCPO] ORGANIC PHOTOVOLTAIC PANEL COURTESY : LABORATORY INTEGRATION FROM MATERIAL TO SYSTEM [IMS]

A laboratory for excellence (Labex): AMADEUS, for advanced materials  Metamaterials  Molecular materials  Organic electronics…

Labex AMADEUS

University of Bordeaux Science and Technologies

~8 000 students ~1600 staff ~1000 PhD students 20 research laboratories

An innovative university at the service of learning and training

■ Highly varied educational activities ■ Great choice of paths to take within their

degree course right up to doctorate level

■ Self access centres, which allow students to

study autonomously

Materials in Bordeaux Univ.

 Bordeaux University : Prioritary axis Materials for the future

Gathers many laboratories working on structural materials, soft matter, nanomaterials, composite materials, optical materials, functional materials… Chemistry, Physics, Biology (materials for health)… multiferroics polymers heterogeneous catalysis ferroelectrics coatings photocatalysis piezoelectrics solid state ionics photovoltaics photoactive materials biomaterials nanomaterials sensors and actuators composites metamaterials magnetism

• ptics

transparent conductors

► Institute of Condensed Matter Chemistry

• Oxides, fluorides, metallic and molecular materials
• Powder, ceramic, composite, single-crystals, thin films
• Structural and functional materials
• Dielectric, magnetic, optical materials
• Materials for energy storage and conversion
• Environment and sustainable development

More than 230 people working

• n materials

chemistry, physics and engineering http://www.icmcb-bordeaux.cnrs.fr/index.html

Bibliographic and Research Project for Master Thesis

Photomagnetic molecular compounds Transparent organic electrodes Colloidal liquid crystals Porous materials for photocatalysis

FAME Master recent subjects FAME Master  Defended PhD

Optimization of bistable molecular materials for communication and information processing Effect of electrical and magnetical constraints on ferroelectric ceramics and single-crystals Organization of molecule-magnets by coordination chemistry : towards a new generation of magnetic and photomagnetic materials Bio-mimetic Actuators based on conducting polymers Scattering from plasmonic nanoraspberries Preparation of Gold Saturn Like particles and characterization of their optical properties Synthesis of linear block copolymers from cellulose base

Curriculum of the FAME Specialization at Bordeaux

6 ECTS Hybrid &Nanomaterials General overview concerning the use of the Tools of molecular, macromolecular, sol-gel chemistries and physico-chemistry to elaborate nanomaterials, control the organization and the properties of self- assembled macromolecular structures and of organic/inorganic hybrid materials.

• To know the main fabrication processes of inorganic nanomaterials (quantum dots, metals, metal oxide);
• To be able to describe the basics, fundamental chemistry and physics of nanosystems;
• To know the basis of block copolymer self-assembly at the bulk state;
• To know the main properties and applications of block copolymer-based materials as well as the

main techniques to characterize them;

• To manipulate simple physico-chemical concepts to describe functional hybrid materials;
• To know the main classes and applications of hybrid materials;
• To be able to propose different synthetic strategies towards functional hybrid materials.

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_5781/hybrid-and-nanomaterials

Curriculum of the FAME Specialization in Bordeaux

Large Scale Facilities

Objectives

• This lecture aims at discovering the contribution of the large scale facilities (neutron source and synchrotron

radiation), at fundamental as well as applied levels, in the understanding of structural and dynamical properties of matter ranging from materials to macromolecular science.

• Improved knowledge of the large scale facilities in the field of Materials Science and improved capacity to call upon

large scale facilities in Europe. Lecture course content

• General considerations, matter/radiation interaction, sources, facilities, concerned fields of applied and fundamental

research, complementarities with other techniques.

• Nuclear and Magnetic Structure. Specificities and complementarities of neutron diffraction (ND) and X-ray

diffraction (XRD). Neutron Magnetic diffraction. Examples and limits of ND and XRD.

• Large scale structure. Small angle scattering (SAS) techniques. Complementarities of Neutron and X-ray SAS.

Modeling SAS data. Application to macromolecular systems.

• X-ray imaging and spectroscopy. X-ray absorption techniques and Exafs, scanning imaging techniques and full-field

imaging techniques

• Neutron spectroscopy. Elastic, quasi-elastic and inelastic neutron scattering, structure factors, van Hove formalism,

molecular dynamics. Complementarities with computing science (MD simulations…) and applications in solid-state chemistry, materials science and soft materials. Practical course content. In addition to the lectures, a practical training project is organized in the neutron facility near Paris (Nuclear reactor “Orphée” of the “Laboratoire Léon Brillouin”, http://www-llb.cea.fr) during three days. Each group of 5 to 7 students select a training project among several options (e.g. nuclear and magnetic structure of relevant crystals, velocity of sound in materials, diffusion of macromolecules in solution, macromolecular arrangement of polymeric materials, etc…). This project gives the students the opportunity to experience the acquired concepts. It should be noted that such a project is subjected to obtaining the access authorizations.

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_7478/large-scale-facilities-grands-instruments

Curriculum of the FAME Specialization in Bordeaux

6 ECTS Photonics, Laser and Imaging Objectives

• molecules and materials characterization techniques in non linear quadratic optic
• time-resolved spectroscopy : femtosecond temporality, methodology and applications
• emission spectroscopy: transition elements and rare earths luminescence, Phosphors selection,

applications.

• General aspects of second order non-linear optics
• Molecular symmetry determination by hyper-Rayleigh diffusion
• Surfaces, interfaces and thin films characterization by second harmonic generation
• General aspects of physical-chemical events temporality
• Phenomena studied by pump-probe technologies
• Understanding of LASER processes and applications
• Understanding of luminescence mechanisms and interpretation of absorption and emission spectra

(influence of the crystal structure on luminescence) Course content Part I : Introduction to non-linear optics Part II: Introduction to time-resolved spectroscopy Part III : Luminescence of inorganic materials

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4738/photonics-lasers-and-imaging

Dielectric Materials I) Background

• Dipoles, polarisation, dipolar interactions, microscopic models
• Complex dielectric permittivity, dielectric losses
• Frequency spectra: relaxations, resonances (…) fundamental relations
• Measuring dielectric properties: impedance spectroscopy, optical spectroscopies
• Interfaces between electrodes and dielectric materials

II) low permittivity dielectrics

• The most used oxide in electronics: amorphous SiO2
• Other oxides: Al2O3 , MgO, Ta2O5, TiO2

III) high permittivity dielectrics

• Substituted alkali halides : KCl:OH, KCl:Li
• Ferroelectric materials: spontaneous polarisation, ferroelectric domains

Relaxor materials Ferroic and multiferroic materials IV) Chemical Bonding / Polarisability / Dielectric permittivity

• Simple oxides polarisability
• Case of transition metal oxides
• Anisotropy and permanent dipole in octahedral symmetry
• Influence on chemical bonding

V) Implementation of dielectric materials

• Shaping constraints
• Multilayer ceramic capacitors, contribution of grain boundaries
• Supercapacitors (Ta, Nb, Al)
• Thin films, nanoparticles
• Finite size effects in dielectrics
• Composites

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4621/magnetic-dielectric-properties

Magnetic Properties: from Molecules to Materials

I)

• I. Compounds with one single magnetic center

II) Fundamental formula in magnetism and Curie law. Examples. Deviations from the Curie law III) Tutorial: Application of the Curie law for different ions: transition and lanthanides ions. IV)

• II. Compounds with two magnetic centers in interaction

V) Exchange interaction: experiment and theory. Heisenberg Hamiltonian. Kahn’s model. Goodenough- Kanamori rules. Comparison of the two models. VI) Tutorial: Examples of dinuclear compounds, prediction of the nature of the interaction. VII)

• III. Magnetic Ordering. Applications to non-conducting materials.

VIII) Magnetic ordering: through binuclear system to the solid in the mean-field approximation. Phase transition (notion of the order parameter and the critical temperature Tc). Criteria to get a high Tc. IX) From molecules to networks: polynuclear compounds and Prussian blue analogs. Ferro- and ferrrimagnetic ordering. Antiferrromagnetic ordering in oxides. X) Tutorial: Prussian blue analogs AMIICr(CN)6 : can we rationalize the evolution of their TC ? XI) Tutorial: Application of the Goodenough-Kanamori rules to oxides materials. XII)

• IV. Dynamic Phenomena: magnetic hysteresi .

XIII) Examples in molecular systems: single-molecule magnets. Approximation of the macrospin (giant spin). Magnetization relaxation. Nanoparticules: Superparamagnetism. Dipolar interactions. XIV) Tutorial: study of the Mn12O12 and/or a nanoparticule. XV) Magnetization process. Domains formation and observations. Domain walls.

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4621/magnetic-dielectric-properties

Energy, Communication, Information Organic Electronics Introduction, overview (polymer-based electronic devices, conjugated polymers, LED) Electronic Structure Molecular structure / electronic properties relationships of conjugated polymers : orbital treatment Polymers doping and electrical conduction Interaction of conjugated polymers with light Non-linear polarization phenomena Optical excitations Charge transport in conjugated polymers Charges movement mecanisms Analysis methods at various scales Structure of conjugated polymers in the solid state Molecular conformation, local order Morphology Synthesis and design (Main synthesis methods, Impact of synthetic tools on electronic properties) Applications and devices principles Fuel Cells : General considerations, PEMFC, SOFC, issues and opportunities of Fuel Cells. Batteries : Past, present and future Hydrogen : Classical and new production modes, direct and indirect uses, Storage, Current trends Project : Group work on the design of a system (for example a computer with data storage, energy supply, display, processing unit, input/output lines…) based on organic and inorganic materials.

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4609/energy-communication-information

Applied Nanosciences These multi-disciplinary courses, presented by chemists, expose the contribution of molecular and supramolecular concepts in various application areas, including renewable energy and information processing. The basic principles that are acquired, such as nano-structuring, design of molecules and of specific supramolecular interactions, will also enable the guided analysis of scientific publications. Understand the molecular elements that generate a specific function in organized supramolecular systems and at the nanoscale. Learn how to the design molecules and organic and inorganic assemblies for applications in nanosciences. Know the principles of important technological applications. Discover the importance of nanostructuring. Learn how to analyse publications in the multidisciplinary field of nanoscience, with the knowledge of the application, (supra- )molecular approaches and characterization techniques. Part I : Molecular Nanosciences Chapter I : Introduction Chapter II: Applications 1: Renewable Energy Chapter III: Applications 2: Information Technology Chapter IV: Future Developments Part II: Tools and Techniques for Nanosciences Chapter V: Techniques used for the study of nano-organic and inorganic systems. Chapter VI: Analysis of experimental data and publications Part III: A short overview on Molecular Materials Chapter VII: Applications 3: Information Storage Chapter VIII: Applications 4: Nanoparticles of Molecular Materials

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4992/applied-nanosciences-nanosciences-appliquees

Innovative and Composite Materials

Whatever the nature of materials (organic, mineral), their structure can be tailored at different scales as soon as a right choice of process for manufactoring is done. This controlled degree of structuration allows new properties to be obtained, from nanometric to macroscopic scales. Mastered competences: To know how to make a material and to control its microstructure at different scales. To experience the physical et chemical phenomena that allows to modulate and/or modify the properties (chemical, physical (optic, electric, mechanic),...). Approach of the integrative chemistry, to manufacture materials according to requirements of the specifications. Course content : I- Methods for the fabrication of amorphous and crystallised ceramics: bulk and thin films II- Modifications of metals properties III – Porous materials IV- Composite materials

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4573/innovative-composite-materials-materiaux-innovants-et-composites

Molecular Simulation

Numerical simulation is a complementary approach with respect to theroretical and experimental approaches, with important contributions to the study of microscopic systems, from isolated molecules to polymers, materials... This course will allow the students becoming familiar with underlying concepts of this scientific approach, and with the methods, potentialities and limits of various simulations methods..They will develop their ability to conduct and analyse a numerical simulation, to grasp the limits of commercial softwares, and ultimately to develop their own simulation tools. They will acquire a better understanding of the microscopical mechanisms underlying the chemical and physical properties of condensed matter, an ability to modelize micro/macroscopic phenomena and to correlate them to microscopic processes. Program 1) Modeling of condensed phases by numerical simulations 2) Simulation techniques for thermodynamical assembly at equilibrium 3) Properties calculations 4) Interaction models 5) Applications Four practicals on computers will allow the students to gain experience in the use of the knowledge acquired during the course. P1: Numerical experiment, concepts of statistical quality and ensemble average. Monte Carlo method. P2: Ionic solutions structure simulation. Comparison with experiment. P3 et P4: Discovery and applications of a materials modelisation software

Curriculum of the FAME Specialization at Bordeaux

http://www.u-bordeaux.fr/formation/2016/PRMA_61/chimie/enseignement/FRUAI0333298FCOEN_4739/molecular-simulation-simulation-moleculaire

FAME Master Contacts

International Relationships Office (DRI, Building A37):

Head: Mrs Véronique Debord-Lazaro, veronique.debord-lazaro@u-bordeaux.fr Assistant: Mrs Florina Camarasu, florina.camarasu@u-bordeaux.fr

(Erasmus Mundus Grants, Registration, Language courses, Accommodation problems, Bank account…) Department of Chemistry (UFR, Building A11): Head:

• Prof. J.L. Bobet, bobet@icmcb-bordeaux.cnrs.frr

Assistant: Mrs S. Herrada, severine.herrada@u-bordeaux.fr Master of Chemistry Head:

• Pr. Olivier Mondain-Monval, mondain@crpp-bordeaux.cnrs.fr

Assistant: Mrs C. Jalibert, Corinne.jalibert@u-bordeaux.fr

FAME speciality

Coordinators:

• Dr. Michael Josse, Michael.josse@u-bordeaux.fr

FAME students currently in Bordeaux:

Margaux Lassaunière (M2)

http://www.emmi-materials.eu

FAME Scholars in Bordeaux

Specific Seminars Given by Scholars invited by the FAME Master 2008 Dr. Jelena Cirakovic (Du Pont de Nemours (USA)) 2009 Dr. Alla Artemenko (Institute for Problems in Material Science (Kiev)) 2010 Prof. Mas Subramanian from University of Oregon (USA) 2011 Prof. Sumit Bhaduri from Northwestern University (USA) 2012 Prof. Eric Prouzet from Waterloo (Canada) 2012/2013 Prof. Alain Pignolet from Montréal (Canada) 2014 Prof. Cherif Balde from Ziguinchor (Sénégal) 2016 Prof. Gopinath Chinnakonda (India)

Semester 3 in Bordeaux Schedule

Key dates for current academic year 1) 1st week of September: Start of the lectures 2) During September: Master Thesis topics released (& bibliographic project) 3) End of November : practicals in Saclay (Large Scale Facilities) 4) Exams:

• 1st session early January (typically from 3 to 21st of Jan.)
• 2nd session in June (typically around 23-27th of Jun.)

5) Master Thesis

• Bibliography as soon as the subject is selected
• Experimental work from ~1st of February to ~25th of June

6) PhD opportunities

• students start applying around February
• many opportunities until June/July
• be proactive, be reactive !

• 2008-2009:

3 PhD in Bordeaux, 1 PhD in FAME Master partner university

• 2009-2010:

1 PhD in Bordeaux, 1 PhD in Germany

• 2010-2011:

1 PhD in Germany, 1 work in South-Korea

• 2011-2012:

1 PhD in Germany

• 2012-2013:

1 PhD in Bordeaux, 1 PhD in Nancy, 1 PhD, 1 repeat

• 2013-2014:

2 PhD in Bordeaux, 1 work in China, 1 repeat

• 2014-2015:

3 PhD (USA, Switzerland, Germany/Bordeaux), 1 Master in Optics

• 2015-2016:

1 PhD in Toulon, 1 PhD in Germany, 1 R&D Eng. in South-Korea,

• 2016-2017:

2 PhD (1 in Bordeaux), 1R&D Engineer in Bordeaux

• 2017-2018:

2 PhD (1 in Bordeaux), 1 Master in Eco-Engineering

• 2018-2019 :

1

After the specialization at UB

Some Laboratories for FAME Students Master Thesis

► Institute of Condensed Matter Chemistry

• nanomaterials
• functional materials
• energy
• environment and sustainable development

Master Fame contact: michael.josse@icmcb.cnrs.fr

► Paul Pascal Research Center

• soft matter
• hybrid materials

Master Fame contact: ravaine@crpp-bordeaux.cnrs.fr

► Institute of Molecular Sciences

• class II hybrid materials
• nanosciences for plastic electronics

Master Fame contact: t.toupance@ism.u-bordeaux1.fr

► LCPO…

• Ph.D. possibilities and financial support :
• French government grants (top 5% student)
• Aquitaine region and/or CNRS grants
• French or european projects (ANR, ERC grants, Marie-Curie fellowships…)
• Industries

Career perspectives

• Erasmus Mundus II Edition: for PhD IDSFunMat

In 2010, 2014, and 2015, 1 Fame student in Bordeaux received a grant,

Selected industry partners :

• Arkéma
• CEA
• SAFT
• Chemtura
• Corning
• SNECMA
• Dassault
• Du Pont de Nemours
• SNPE
• EADS
• Guerbet
• Merck
• Saint-Gobain
• Turbomeca
• Thalès
• Philips Semiconductors
• Qualiflow
• Rhodia
• Photogenics
• ST Microelectronics
• L’Oreal
• In 2009, 3 of the 5 Fame students received a PhD grant from the University of

Bordeaux (one student obtained such a grant in 2015, but elected for IDS-FUNMAT)

University of Bordeaux MAP

ISM DRI Department of Chemistry

University of Bordeaux MAP

ICMCB CRPP IMS, LCPO Village 1 Library LCTS

• Ph.D. possibilities, some from EMMI (IDS-FUNMAT international doctoral school)

Career perspectives

• as of 2018, 22 of 31 Bordeaux

FAME students started a PhD following their graduation.

• among them, 10 stayed in

Bordeaux (including 4 grants from University of Bordeaux and 3 IDS-FUNMAT grants)

Academic Members & Partners Universities / Research Organisations Industry Members

Masters Education Doctoral Education

IDS-FunMat Joint PhDs Erasmus Mundus

Research Project

(European SSCP examples)

Industry R&D Industry Support Group

MaCoMuFi

FAME-Master Erasmus mundus

OXIDES METACHEM

Legal Foundation: EMMI AISBL Statutes, Internal Regulation Legal Framework:

Model Contracts Good Practices Charter

EMMI Information Services:

databases for know-how & equipmt website, newsletter, tutorials MOLOC

EMMI

European Multifunctional Materials Institute Academic Members & Partners Universities / Research Organisations Industry Members

Masters Education Doctoral Education

IDS-FunMat Joint PhDs Erasmus Mundus

Research Project

(European SSCP examples)

Industry R&D Industry Support Group

MaCoMuFi

FAME-Master Erasmus mundus

OXIDES METACHEM

Legal Foundation: EMMI AISBL Statutes, Internal Regulation Legal Framework:

Model Contracts Good Practices Charter

EMMI Information Services:

databases for know-how & equipmt website, newsletter, tutorials MOLOC

EMMI

European Multifunctional Materials Institute

EMMI

European Multifunctional Materials Institute

See you in Bordeaux !

Master ERASMUS MUNDUS FAME