Examines topics related to classical solution thermodynamics, considering energy, enthalpy, and the Gibbs function. Applicable mathematical equations are introduced and discussed when appropriate. (JN)

Introduces a chemistry course offered to business and science students as an elective course. Provides an understanding of chemical engineering among students and features six sections: (1) "Introduction"; (2) "Chemicals and Their Sources"; (3) "The Production of Chemicals"; (4) "The Financial Performance of Chemical Corporations"; (5) "Product…

Presents survey data of (n=63) chemical engineering curricula. (MKR)

A realistic applied chemical engineering experimental design and statistical analysis project is documented in this article. This project has been implemented as part of the professional development and applied statistics courses at Villanova University over the past five years. The novel aspects of this project are that the students are given a…

An open-ended student conference project involving sophomore, junior, and senior chemical engineering students is described. The project is designed to address outcomes in each of the courses in which those students are enrolled, as well as broader "soft skills" including multidisciplinary teamwork, communications, lifelong learning, and…

A novel approach to the Chemical Engineering curriculum sequence of courses at West Point enabled our students to experience a much more realistic design process, which more closely replicated a real world scenario. Students conduct the synthesis in the organic chemistry lab, then conduct computer modeling of the reaction with ChemCad and…

Equipment selection during process design is a critical aspect of chemical engineering and requires engineering judgment and subjective analysis. When educating chemical engineering students in the selection of proprietary equipment during design, the focus is often on the types of equipment available and their operating characteristics. The…

Energy is necessary for any phenomenon to occur or any process to proceed. Nevertheless, energy is never consumed; instead, it is conserved. What is consumed is available energy, or exergy, accompanied by an increase in entropy. Obviously, the terminology, "energy consumption" is indeed a misnomer although it is ubiquitous in the…

The author is a chemical engineer (doing a research in mass transfer operations at a national laboratory) and an adjunct faculty member. The advantages of being such a faculty member are discussed, indicating that this is an effective mechanism for maintaining technical as well as educational skills. (JN)

This article: (1) traces some of the history behind the International Business Machines (IBM) and academic arrangement; (2) describes the Advanced Control System and how it is used in undergraduate process control courses; (3) discusses benefits to students and teachers; and (4) summarizes future plans. (JN)

Summarizes and compares time domain and Z-transformation methods for sampled data process control design and analysis. Shows that all of the results and concepts usually considered in undergraduate exercises can be developed more quickly, clearly, and intuitively in the time domain. (JN)

Describes a course for chemical engineers, chemists, and petroleum engineers that focuses on colloid and surface science. Major topic areas in the course include capillarity, surface thermodynamics, adsorption contact angle, micelle formation, solubilization in micelles, emulsions, foams, and applications. (JN)

A special-topics course in polymer processing has acquired regular course status. Course goals, content (including such new topics as polymer applications in microelectronics), and selected term projects are described. (JN)

Describes a course designed to show similarities between electrochemistry and corrosion engineering and to show graduate students that electrochemical and corrosion engineering can be accomplished by extending their knowledge of chemical engineering models. Includes course outline, textbooks selected, and teaching methods used. (JN)

Analyzes steady-state multiplicity in chemical reactors, focusing on the use of two mathematical tools, namely, the catastrophe theory and the singularity theory with a distinguished parameter. These tools can be used to determine the maximum number of possible solutions and the different types of bifurcation diagrams. (JN)