Linear cause-effect relationship; molecular aspects, microscopic mass, momentum and energy balances leading to the field equations of change; emphasis is on both isothermal and nonisothermal, steady state flow of incompressible Newtonian fluids; integral forms of the equations of change: macroscopic balances for laminar as well as turbulent isothermal and nonisothermal systems: engineering correlations.

Senior Design provides, over the course of two semesters, collaborative design experiences with a problems of industrial or societal significance. Projects can originate with an industrial sponsor, from an engineering project on campus, or from other industrial or academic sources. In all cases, a project is a capstone experience that draws extensively from the student's engineering and scientific background and requires independent judgments and actions. Advice from the faculty and industrial sponsors is made readily available. The projects generally involve a number of unit operations, a detailed economic analysis, simulation, use of industrial economic and process software packages, and experimentation and/or prototype construction. The economic thread initiated in Design VI is continued in the first semester of Senior Design by close interaction on a project basis with E 421. Leadership and entrepreneurship are nourished throughout all phases of the project. The project goals are met stepwise, with each milestone forming a part of a final report with a common structure.

Analysis of batch and continuous chemical reactions for homogeneous, heterogeneous, catalytic, and non-catalytic reactions; influence of temperature, pressure, reactor size and type, mass and heat transport on yield and product distribution; design criteria based on optimal operating conditions and reactor stability will be developed.

Discussions of aspects of the technology of processing procedures involved in the fabrication of microelectronic devices and microelectromechanical systems (MEMS). Topics with respect to IC fabrication include crystal growth, epitaxy, silicon oxide growth, impurity doping, ion implantation, photo and electron beam lithography, etching, sputtering, thin film metallization, passivation and packaging. Students will also learn that MEMS are sensors and actuators that are designed using different areas of engineering disciplines and they are constructed using a microlithographically-based manufacturing process in conjunction with both semiconductor and micromachining microfabrication technologies.

Selected topics of current interest in the field of chemical engineering will be treated from an advanced point of view.

Assessment of current and potential energy systems, covering extraction, conversion and end use, with emphasis on meeting regional and global energy needs in the 21st century in a sustainable manner; systems engineering and economic analysis tools for sustainable energy systems; climate change; energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types; storage, transmission, and conservation; evaluation and analysis of energy technology systems in the context of engineering, economic, environmental, political and social aspects.