An introduction to the theory and application of momentum transport in fluids. The basic theoretical equation, e.g., Navier Stokes equations and Boundary Layer analysis developed and used to flow problems, with applications to laminar and turbulent flow in the design of piping and other chemical equipment.

Principles underlying rates of transformations of matter and energy. Review of pertinent differential equations; effect of temperature and catalysis on chemical reaction rates; kinetic and mass transfer effects on rates; design of chemical reactors. Prerequisites: CHEM-ENG 120, 226, 231, MATH 233 and 331. Corequisites: CHEM-ENG 325 and 330

Principles underlying rates of transformations of matter and energy. Review of pertinent differential equations; effect of temperature and catalysis on chemical reaction rates; kinetic and mass transfer effects on rates; design of chemical reactors. Prerequisites: CHEM-ENG 120, 226, 231, MATH 233 and 331. Corequisites: CHEM-ENG 325 and 330

This is a stand-alone independent study designed by the student and faculty sponsor that involves frequent interaction between instructor and student. Qualitative and quantitative enrichment must be evident on the proposed contract before consent is given to undertake the study.

Description not available at this time

Not available at this time

The study of the principles of thermodynamics, including the First and Second Laws, entropy, thermodynamic properties of single component materials, engines, refrigeration, and power cycles.

The study of the principles of thermodynamics, including the First and Second Laws, entropy, thermodynamic properties of single component materials, engines, refrigeration, and power cycles.

This course is intended to be an introduction to many core Chemical Engineering principles, within the context of mammalian cell biology and human physiology. We will cover biological topics of cell division, DNA, receptor-ligand binding, matrix protein assembly, tissue engineering, and cell motility, using a quantitative engineering perspective. Within this biological framework, students will learn the basic principles of mass and energy balances, thermodynamics, kinetics, and transport. (Gen.Ed. BS)

This course is intended to be an introduction to many core Chemical Engineering principles, within the context of mammalian cell biology and human physiology. We will cover biological topics of cell division, DNA, receptor-ligand binding, matrix protein assembly, tissue engineering, and cell motility, using a quantitative engineering perspective. Within this biological framework, students will learn the basic principles of mass and energy balances, thermodynamics, kinetics, and transport. (Gen.Ed. BS)