Fundamental concepts of heat and mass transfer; applications of these concepts and material and energy conservation calculations for design of heat exchanger and packed absorption/stripping columns. Four lecture hours. Prerequisites: CHE 2216, 3316, 3321.

Includes the formulation and analysis of the first and second laws of thermodynamics; energy conservation; concepts of equilibrium, temperature, energy, and entropy; partial molar properties; pure component and mixture equations of state; processes involving energy transfer as work and heat; reversibility and irreversibility; and closed and open systems and cyclic processes. Corequisite: APMA 2120

Determination of rate equations for chemical reactions from experimental data. Use of kinetics and transport relations in the design of both batch and continuous reactors; homogeneous, heterogeneous, uncatalyzed and catalyzed reactions. Three lecture hours. Prerequisite: CHE 2216, 3316; corequisite: CHE 3322.

Mathematical and computational tools for the analysis and simulation of chemical processes and physicochemical phenomena. Mathematical and numerical methods. Three lecture and one laboratory hour. Prerequisite CHE 2215, CS1110 or CS1111 or CS1112 or CS 1113; Co-requisite: APMA 2130 or MATH 3250, or APMA 2501 topic "Differential Equations & Linear Algebra"

Fundamentals of chemical reaction kinetics and mechanisms; experimental methods of determining reaction rates; introduction to heterogeneous catalysis; application of chemical kinetics, along with mass-transfer theory, fluid mechanics, and thermodynamics, to the design and operation of chemical reactors. Prerequisite: CHE 6625 and 6665.

Experimental study of selected operations and phenomena in fluid mechanics and heat transfer. Students plan experiments, analyze data, calculate results and prepare written and/or oral planning and final technical reports. One hour discussion, four laboratory hours. Prerequisite: CHE 2215 and CHE 3316 and CHE 3321; corequisite: CHE 3322

Fundamental principles common to mass transfer phenomena, with emphasis on mass transfer in diverse chemical engineering situations. Detailed consideration of fluxes, diffusion with and without convection, interphase mass transfer with chemical reaction, and applications. Prerequisite: CHE 6625 and 6665.

Applies engineering science, design methods, and system analysis to developing areas and current problems in chemical engineering. Topics are announced at registration. Prerequisite:Third or Fourth-year standing and instructor permission.

Quantitative engineering aspects of industrial applications of biology including the microbial synthesis of commercial products, environmental biotechnology, and the manufacture of biopharmaceuticals through recombinant microorganisms, transgenic animals, and plants. Three lecture hours. Prerequisite: CHE 2216, CHE 2246, CHE 3321; corequisite: CHE 3318, and 3322.

Introduction to properties, production, and use of biological molecules of importance to medicine and industry, such as proteins, enzymes, and antibiotics. Topics may include fermentation and cell culture processes, biological mass transfer, enzyme engineering, and implications of recent advances in molecular biology, genomics, and proteomics. Prerequisite: Instructor permission.