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Course Criteria
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: grade "C" or higher in CHEM 101 or equivalents. The first of two introductory chemical and life science engineering courses. Covers material balances on steady-state chemical processes. Formerly EGRC 201.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: grades of "C" or higher in CLSE 201, CHEM 101-102 and MATH 200-201 or equivalents. The second of two introductory chemical and life science engineering courses. Covers energy balances on steady-state chemical processes, computer-aided balance calculations and balances on transient processes and introduction to thermodynamics. Formerly EGRC 202.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisite MATH 151 or equivalent. Intended for chemical and life science engineering majors. Introduction to the concepts and practice of structured programming using Fortran 95 and/or C. Problem solving, top-down design of algorithms, objects, basic syntax, control structures, functions and arrays.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisite: grade of "C" or higher in CLSE 201 and 202. Basic concepts of transport phenomena as applied to chemical and life science engineering. Topics include transport of mass momentum and energy in single and multidimensions. Formerly EGRC 301.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: grades of "C" or higher in CLSE 301 and 305. Concepts of transport phenomena as applied to chemical and life science engineering. Topics include advanced multicomponent, multiphase systems, integral analysis, and an integrated view of momentum, heat and mass transport in unit operations. Formerly EGRC 302.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisite: grade of "C" or higher in CLSE 201 and 202. Continuation of CLSE 202. Thermodynamic properties of fluids and mixtures, partial molar quantities, phase equilibria, activity coefficients and correlations, equations-of-state, chemical reaction equilibria for liquid, vapor and multiphase reactions, and the use of equations-of-state and activity/fugacity correlations to obtain the thermodynamic functions required for the calculation of chemical reaction equilibrium constants. Computing using Excel VBA are a required component of this course. Formerly EGRC 305.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: Chemical engineering students: CLSE 201, CLSE 205 or permission of the instructor; chemistry students: CHEM 302 and CHEZ 302L. A study and analysis of the most important industrial applications of inorganic chemistry, with emphasis on structure/properties correlation, material and energy balances, availability and logistics of starting materials, economic impact and environmental effects. Formerly EGRC/CHEM 306.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: CLSE 301 and 305. Introduces the student to the analysis of reactors via coupling of empirical reaction rates and thermodynamic constraints with reactor material and energy balances. The behavior of the ideal reactor types (batch, CSTR and PFR) is emphasized with attention given to departure from these ideals by real systems. Formerly EGRC 312.
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2.00 Credits
Semester course; 6 laboratory hours. 2 credits. Prerequisites: grades of "C" or higher in CLSE 201 and 202. Co-requisite: CLSE 301. This laboratory introduces students to a variety of measurement instruments used in modern chemical engineering laboratories and process plants. Detailed laboratory reports are required for each of the experiments undertaken by the students. Formerly EGRC 320.
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3.00 Credits
Semester course; 3 lecture hours. 3 credits. Prerequisites: BIOL 101, 102, 103 or 151 and CLSE 201. An introductory and survey level course required for all chemical engineering students. This course introduces concepts and principles of chemical engineering to problems and issues in the life sciences, biotechnology and medicine. Students apply heat and mass transfer concepts, separations and controls to topics that include clinical diagnostics, bioanalytical instrumentation, biosensors and biochips, bioprocess engineering including fermentation, biochemical pathway engineering, protein folding and aggregation, bioreactors and tissue engineering. Formerly EGRC 325.
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