Green Chemistry and Sustainable Chemical Processes: Research on methods to make chemical processes friendlier for the environment and sustainable—reducing waste generation, with the use of renewable resources.
Nanotechnology in Drug Delivery Systems: Study the design and application of nanotechnology for treatment through effective drug delivery at a site scale and improved success in therapeutic effects.
Catalysis for Organic Synthesis: Learn the role of different catalysts in promoting organic reactions with a focus on developing more efficient and selective catalytic processes.
Investigate the application of some photocatalytic materials in the degradation of pollutants for water remediation, focusing on mechanisms and efficiency in these processes.
Battery technology: new material, new battery design—lithium-ion, solid-state, flow—for increased energy storage capacity and efficiency.
Course Description: Chemical Sensors and Biosensors: An overview on the general design, development, and application of chemical sensors and biosensors in environmental pollution monitoring and control, medical diagnosis, and industry.
Supramolecular Chemistry and Self-Assembly: To give you a solid background in supramolecular chemistry, the design of materials allowing for self-assembly, and applications in nanotechnology and material science.
Organic Photovoltaics: Research on the development of organic photovoltaic materials and their potential in the effective conversion of solar energy economically.
Chemical Kinetics and Reaction Mechanisms: Make it possible to study the course of chemical changes concerning chemical kinetics and the mechanism of changing processes, with the concentration of attention on factors navigating the rate of reactions and their pathways.
Polymers and Polymerization Techniques: The latest trends in polymer synthesis for creating advanced polymer materials along with their tailored properties and applications.
Electrochemistry and Its Applications: Principles and applications in energy storage, corrosion prevention, and electroplating.
Metal-Organic Frameworks (MOFs): The synthesis, properties, and application of metal-organic frameworks in gas storage, catalysis, and drug delivery.
Quantum Chemistry and Computational Modeling: An investigation will be carried out into quantum chemistry and the development of models using this method to predict chemical systems’ behavior.
Environmental Chemistry: To comprehend the processes of chemical reaction of the environment, pollution control, and remediation.
Biomolecular Chemistry: The study of the structure, functions, and interactions of the biological molecule, with an emphasis on its application in the field of biochemistry and molecular biology.
Solid-State Chemistry and Materials Science: Research on the synthesis and characterization of solid-state materials, their structure–property relationships, and possible applications.
Chemical Education and Pedagogy: Study new methods and ways of teaching chemical education in order to improve the student’s understanding and make their participation fruitful, finding new ground on how to teach.
Natural Product Chemistry: The study of extraction, characterization, and synthesis of natural products that could have a prospective application in medicine and industries.
Surface Chemistry and Catalysis: Introduction of principles of surface chemistry, playing an important role as the base toward the catalysis heterogeneously, with particular attention to the design of new material of catalytic.
Chemical Safety and Risk Assessment: Understand the principle of chemical safety, including risk assessment and regulatory practices for the use of chemicals.
Photochemistry and Light-Induced Reactions: Elucidate mechanisms and applications of photochemical reactions with special emphasis on their use in synthetic chemistry and in photodynamic therapy.
Bioinorganic Chemistry: This refers to the study of metal ions in biological systems, with emphasis on metalloenzymes, metalloproteins, and drug development based on metals.
Chiral Chemistry and Asymmetric Synthesis: Understanding the fundamentals of chirality in chemistry and the development of methods in asymmetric synthesis; this includes the chirality of auxiliaries, catalysis, and biocatalysis.
Advanced Spectroscopy Techniques: Study the advanced NMR, IR, and mass spectroscopy techniques used in the analysis and characterization of chemical compounds.