Program Overview

The educational objective of the Master in Applied Chemistry is to train high-level scientists with a solid foundation in chemistry. The programs are designed to enable students to deepen both fundamental and applied aspects, allowing them to either pursue doctoral studies or directly enter the workforce. It begins with acquiring theoretical and practical knowledge, enabling students to understand and apply the fundamental principles of this discipline. Subsequently, the study of major chemical processes on an industrial scale provides a comprehensive and operational vision of the processes used in the field. Simultaneously, students learn to master synthesis and analytical methods essential for the design and characterization of catalytic materials, which play a key role in various industrial sectors. Finally, a section dedicated to entrepreneurship encourages students to develop their initiative and consider creating start-ups, offering an alternative to job seeking and aligning with the directives of the Ministry of Higher Education and Scientific Research.

Teaching Language : English/French

Curriculum Highlights

Core Courses

Semester 1:

· Heterogeneous Catalysis

· Advanced Kinetics

· Experimental Design

Semester 2:

· Solid-State Chemistry and Nanomaterials

· Homogeneous Catalysis

· Chemical Reaction Engineering

Semester 3:

· Photochemistry, Electrochemistry

· Metal Catalysis

· Thermodynamics of Chemical Reactions

Advanced Topics

Research domains for the Master in Applied Chemistry may include:

1. Catalysis and Catalytic Materials:

o Synthesis and characterization of homogeneous and heterogeneous catalysts.

o Studies of reaction mechanisms and optimization of catalytic processes.

2. Nanomaterials and Solid-State Chemistry:

o Development and applications of nanomaterials.

o Study of the properties of crystalline solids and organic-inorganic hybrids.

3. Spectroscopic and Chromatographic Analyses:

o Development and application of spectroscopic techniques (IR, Raman, UV-Visible, etc.).

o Chromatographic techniques for the separation and identification of chemical compounds.

4. Green Chemistry and Sustainable Development:

o Photocatalysis for water and air purification.

o Treatment of industrial wastewater and pollutant management.

5. Biochemistry and Medicinal Chemistry:

o Synthesis of compounds for the treatment of neurodegenerative diseases.

o Studies of molecular interactions for therapeutic applications.

6. Electrochemistry and Energy:

o Development of fuel cells and other electrochemical generators.

o Study of solid electrolytes and applications in sensors and batteries.

7. Industrial Chemistry and Processes:

o Optimization of chemical reactors.

o Studies of transfer phenomena in catalytic processes.

8. Theoretical and Computational Chemistry:

o Modeling and prediction of reaction pathways.

o Calculations of molecular properties and optimization of chemical structures.

9. Entrepreneurship in Chemistry:

o Creation of innovative technological solutions and startups in applied chemistry.

o Development of SMEs in fields such as cosmetics, detergents, and plastic materials.

Applied Chemistry

Program Overview

Curriculum Highlights

Core Courses

Semester 1:

· Heterogeneous Catalysis

· Advanced Kinetics

· Experimental Design

Semester 2:

· Solid-State Chemistry and Nanomaterials

· Homogeneous Catalysis

· Chemical Reaction Engineering

Semester 3:

· Photochemistry, Electrochemistry

· Metal Catalysis

· Thermodynamics of Chemical Reactions

Advanced Topics

Research domains for the Master in Applied Chemistry may include:

1. Catalysis and Catalytic Materials:

o Synthesis and characterization of homogeneous and heterogeneous catalysts.

o Studies of reaction mechanisms and optimization of catalytic processes.

2. Nanomaterials and Solid-State Chemistry:

o Development and applications of nanomaterials.

o Study of the properties of crystalline solids and organic-inorganic hybrids.

3. Spectroscopic and Chromatographic Analyses:

o Development and application of spectroscopic techniques (IR, Raman, UV-Visible, etc.).

o Chromatographic techniques for the separation and identification of chemical compounds.

4. Green Chemistry and Sustainable Development:

o Photocatalysis for water and air purification.

o Treatment of industrial wastewater and pollutant management.

5. Biochemistry and Medicinal Chemistry:

o Synthesis of compounds for the treatment of neurodegenerative diseases.

o Studies of molecular interactions for therapeutic applications.

6. Electrochemistry and Energy:

o Development of fuel cells and other electrochemical generators.

o Study of solid electrolytes and applications in sensors and batteries.

7. Industrial Chemistry and Processes:

o Optimization of chemical reactors.

o Studies of transfer phenomena in catalytic processes.

8. Theoretical and Computational Chemistry:

o Modeling and prediction of reaction pathways.

o Calculations of molecular properties and optimization of chemical structures.

9. Entrepreneurship in Chemistry:

o Creation of innovative technological solutions and startups in applied chemistry.

o Development of SMEs in fields such as cosmetics, detergents, and plastic materials.

Admissions Information

Licenses in Chemistry:

· L3 Fundamental Chemistry

· L3 Materials Chemistry

· L3 Inorganic Chemistry

· L3 Analytical Chemistry

· L3 Physical Chemistry

· L3 Organic Chemistry

· L3 Pharmaceutical Chemistry

- Any other degree recognized as equivalent by the training team