6.00 credits
45.0 h + 15.0 h
Q2
Teacher(s)
Garcia Yann;
Language
English
Main themes
The teaching will cover the following topics:
- defects in inorganic solids and their formation mechanisms.
- description of the chemical bond in inorganic solids (band theory)
- description of electrical properties (conductors, semi-conductors, superconductors), magnetic, optical and photo-physical properties of principal inorganic solids, and the current applications in the growing domain of functional materials.
- defects in inorganic solids and their formation mechanisms.
- description of the chemical bond in inorganic solids (band theory)
- description of electrical properties (conductors, semi-conductors, superconductors), magnetic, optical and photo-physical properties of principal inorganic solids, and the current applications in the growing domain of functional materials.
Learning outcomes
At the end of this learning unit, the student is able to : | |
| 1 | This course is directed to students having a basic formation in inorganic chemistry and aiming to complete their formation by advanced notions in physical chemistry of functional inorganic materials. It aims at giving a fundamental understanding of chemical bonding in solids and at illustrating the various applications that result. The functionality associated to molecular electronics is also covered based on an orbital and structural approach. |
Content
I. Point defects and non-stoichiometry : defect types, origin of intrinsic crystalline defects, point defects (Kröger-Vink notation), non-stoichiomety, extended defects.
II. Electronic structure and electrical properties of solids : bonding in solids (band theory), relation between band structure and electronic properties, semi-conductors, electrical properties of some inorganic solids (MO monoxides of the 3d series, transition metal sulfides MS2), ionic and molecular conductors.
III. Magnetic properties of materials : basic concepts, molecular magnetism, magnetism associated to conduction electrons, collective magnetism associated to ions.
IV. Analysis methods of magnetism : susceptometers based on a force or induction measurement. Electronic paramagnetic resonance (EPR). Muon spin relaxation spectroscopy (MuSR). Neutron diffraction (structural aspects, spin density maps). X-ray magnetic circular dichroïsm (XMCD).
V. Various magnetic materials and applications : ferrites, garnets, hard and soft magnets, molecular magnets, spin crossover materials, photo-switches and hybrid materials.
VI. Superconduting materials : metallic conductivity and superconductivity, review of superconductivity, BCS theory, superconducting oxides with a high critical temperature, applications of superconductors.
VII. Optical and dielectric properties of solids : inorganic lasers, cooperative dielectric properties (ferroelectricity, piezoelectricity).
II. Electronic structure and electrical properties of solids : bonding in solids (band theory), relation between band structure and electronic properties, semi-conductors, electrical properties of some inorganic solids (MO monoxides of the 3d series, transition metal sulfides MS2), ionic and molecular conductors.
III. Magnetic properties of materials : basic concepts, molecular magnetism, magnetism associated to conduction electrons, collective magnetism associated to ions.
IV. Analysis methods of magnetism : susceptometers based on a force or induction measurement. Electronic paramagnetic resonance (EPR). Muon spin relaxation spectroscopy (MuSR). Neutron diffraction (structural aspects, spin density maps). X-ray magnetic circular dichroïsm (XMCD).
V. Various magnetic materials and applications : ferrites, garnets, hard and soft magnets, molecular magnets, spin crossover materials, photo-switches and hybrid materials.
VI. Superconduting materials : metallic conductivity and superconductivity, review of superconductivity, BCS theory, superconducting oxides with a high critical temperature, applications of superconductors.
VII. Optical and dielectric properties of solids : inorganic lasers, cooperative dielectric properties (ferroelectricity, piezoelectricity).
Teaching methods
Classic or reverse class.
Evaluation methods
oral exam (15/20) and oral defense of a project (5/20) with one or several guest international professors.
Other information
Background :
Inorganic chemistry I and II (CHM 1331 and CHM 2130). Basic notions in crystallography (CHM 1251A).
The course could be partly or totally delivered by an invited lecturer.
Inorganic chemistry I and II (CHM 1331 and CHM 2130). Basic notions in crystallography (CHM 1251A).
The course could be partly or totally delivered by an invited lecturer.
Online resources
Moodle
Bibliography
- Introduction à la chimie du solide, L. Smart and E. Moore (trad. J.-P. Jolivet), Masson, 1997.
- Solid State Chemistry and its Applications, A.R. West, Wiley, 1984.
- Molecular Magnetism, O. Kahn, Wiley, 1993.
- Fascicule reprenant la copie des transparents utilisés par l'enseignant.
- Fascicle containing a copy of overhead transparencies used by the teacher.
- Solid State Chemistry and its Applications, A.R. West, Wiley, 1984.
- Molecular Magnetism, O. Kahn, Wiley, 1993.
- Fascicule reprenant la copie des transparents utilisés par l'enseignant.
- Fascicle containing a copy of overhead transparencies used by the teacher.
Teaching materials
- syllabus LCHM2231 (à la DUC)
Faculty or entity
CHIM
