Describes a summer course in chemical engineering. Includes discussions of the course program, course goals, student performance, and course faculty. Lists examples of informal experiments which have been used, and prerequisite courses that are required for students to enroll in the course. (CW)

Describes the conversion of a laboratory and change in course content in a chemical engineering curriculum. Lists laboratory experiments and computer programs used in the course. Discusses difficulties during the laboratory conversion and future plans for the course. (YP)

Describes a polymerization reactor engineering course offered at Michigan Technological University which focuses on the design and operation of industrial polymerization reactors to achieve a desired degree of polymerization and molecular weight distribution. Provides a list of the course topics and assigned readings. (TW)

Describes a three-hour, one-semester graduate course to provide numerical methods and modeling techniques to handle problems in future courses or engineering practice. Includes rationale for topics such as interpolation, integration, and equation roots, among others. Indicates that all problems require computer use. (SK)

A course where students were required to choose projects and provide studies of the feasibility, consumer need, and process design is discussed. Other projects such as advertising campaigns used to encourage student creativity are discussed. The need to keep second semester seniors interested is stressed. (MVL)

Discusses several options for the incorporation of minimal coursework involving engineering ethics into an already tightly packed curriculum. Topics include integration versus the stand-alone approach; timeliness of course addition; outline of course content and instructional format; students' reflections and instructor's musings; and an annotated…

Addresses the impact of computing on engineering education and the gradual infusion of computing work into the engineering curriculum since the early 1960s. This lecture discusses the academic computing environment in terms of initial developments, what students should know, how to build a network infrastructure, the "first" computing course, the…

Describes a 15-week course in the fundamentals of microelectronics processing in chemical engineering, which emphasizes the use of very large scale integration (VLSI). Provides a listing of the topics covered in the course outline, along with a sample of some of the final projects done by students. (TW)

Outlines a multidisciplinary course which comprises fundamental, practical, and experimental aspects of heterogeneous catalysis. The course structure is a combination of lectures and demonstrations dealing with the use of spectroscopic techniques for surface analysis. (SK)

Presents the framework for a chemical engineering course using ordinary differential equations to solve problems with the underlying strategy of concisely discussing the theory behind each solution technique without extensions to formal proofs. Includes typical class illustrations, student responses to this strategy, and reaction of the…

Discussed is a method to teach undergraduate students how to complete a conceptual design. Presents three tools to use: (1) how to use order-of-magnitude arguments to simplify problems, (2) how to derive design heuristics, and (3) how to decompose large problems into a set of small, simple problems. (Author/MVL)

Describes an engineering course for graduate study in random media. Summarizes random media as bulk properties of ordered and disordered two-phase materials. Gives course outline for one semester. Topics include: disordered systems, microstructure determination, survey of models, connectivity, and effective properties. (MVL)

Proposes that inclusion of waste water treatment subjects within the chemical engineering curriculum can provide students with direct access to environmental issues from both a biotechnological and an ethical perspective. The descriptive details of water recycling at a copper plant and waste water stabilization ponds exemplify this approach from…

Introduces some ideas on teaching scaleup in chemical engineering. Discusses the instructional modes and the general and specific topics. Provides two examples of an experiment with equipment and safety issues. Shows the list of actual individual and team projects in an appendix. (YP)

Discusses the problems created in graduate chemical engineering programs when students enter with a wide diversity of understandings of transport phenomena. Describes a two-semester graduate transport course sequence at the University of Notre Dame which focuses on fluid mechanics and heat and mass transfer. (TW)