The team focuses on the development of materials that possess original and smart chemical and physical properties in order to address societal challenges in the area of sustainable energy, information storage, new electronic materials and medicine. We design materials at the molecular and the nanometric scale using organic chemistry, coordination chemistry and soft chemistry. Our team consists in 7 groups with a particular research area.
In addition to the characterization tools usually used in chemistry, the team is a regular user of large instruments : SOLEIL (Gif-sur-Yvette) and ESRF (Grenoble) synchrotrons, the Laboratoire National des Champs Magnétiques Intenses (Grenoble) et le National High Magnetic Field Lab (Tallahassee, USA). We rely on theoretical calculations (ab initio, DFT) to rationalize our experimental results and as guide for the design of new systems with targeted chemical and physical properties.
The main challenges currently adressed by the team are :
- developing efficient molecular catalysts for the selective reduction of CO2 in a first place to CO,
- achieving the reductive activation of dioxygen via the modulation of molecular and supramolecular properties of non-heme Fe complexes for the development of electro-assisted oxidation catalysis,
- developing a new transition metal K-edge X-ray Magnetic Circular Dichroïsm tool that enables reaching a photomagnetic effect at room temperature for high-density information storage,
- designing single layers of switchable molecules in contact with metallic surface that can be addressed by an electric field,
- designing coordination complexes that behave as qubits for quantum computing devices,
- developing new conducting/ferromagnetic two-dimensional (2D) coordination networks,
- ldesigning coordination nanoparticles for theranostics and gas sensors,
- designing suitable photochromic systems for the photo-regulation of the concentration of different metal ions, in particular those involved in various biological processes,
- designing photochromic molecules as spacers in light controlled spintronic devices,
- designing and synthesising of ring-like conjugated molecules as precursors for the total synthesis of carbon
nanotubes with targeted electronic properties.
Head : Prof. Talal MALLAH (firstname.lastname@example.org / 01.49.15.47.49)
Internship, PhD and post-doc opportunities
Type of offer
Fluorescent MOFs for detection
Spin crossover molecular materials for the switching on metallic surface
Nanotextured silica as nanoreactors for the elaboration of nanoparticles with targeted photomagnetic properties
Elaboration and characterization of metallic nanoparticles. Analyses of the "alloy effects" in the catalysis of carbon nanotubes by CVD