I am deeply passionate about teaching and mentoring students in the fields of chemical engineering, materials science, and computational methodologies. My teaching philosophy is centered on fostering critical thinking, problem-solving skills, and a strong theoretical foundation while integrating computational tools and experimental insights to enhance learning experiences. I am particularly interested in teaching the following subjects at the graduate and postgraduate levels:
Fluid Mechanics & Transport Phenomena: These subjects form the cornerstone of chemical engineering. I aim to provide students with a fundamental understanding of momentum, heat, and mass transfer while integrating computational fluid dynamics (CFD) simulations to bridge theory with real-world applications.
Chemical Engineering Thermodynamics & Chemical Reaction Engineering: Understanding energy transformations and chemical kinetics is essential for process design. My teaching approach combines classical thermodynamics principles with modern computational chemistry techniques, enabling students to predict and optimize reaction behavior.
Soft Matter & Polymer Science: These interdisciplinary subjects connect chemistry, physics, and engineering. My course structure will cover the mechanical, thermal, and rheological properties of polymers and nanocomposites, supported by molecular dynamics (MD) simulations to provide atomistic insights.
Introduction to Metallic Materials: Metals and alloys play a critical role in industrial applications. I plan to introduce students to phase diagrams, mechanical behavior, and corrosion mechanisms, incorporating density functional theory (DFT) simulations and molecular dynamics to explore atomic-scale phenomena.
Mathematical Modeling & Numerical Analysis: With the growing reliance on computational methods, I aim to equip students with numerical techniques for solving engineering problems, covering finite element methods, optimization algorithms, and machine learning-based regression models.
Computational Chemistry: This subject is crucial for material discovery and process optimization. I will teach quantum mechanics, molecular dynamics, and reactive force field simulations to analyze chemical reactivity and catalysis.
Research Methodology: A strong foundation in research methods is critical for graduate students. My course will include experimental design, data analysis, scientific writing, and ethical considerations in research.
By integrating theoretical knowledge with hands-on computational and experimental approaches, I strive to inspire students and prepare them for careers in academia, industry, and research. My goal is to create an engaging learning environment where students can develop a deep understanding of fundamental concepts while acquiring the technical skills necessary to address complex engineering challenges.