10.37 | Spring 2007 | Undergraduate
Chemical and Biological Reaction Engineering
Course Description
This course applies the concepts of reaction rate, stoichiometry and equilibrium to the analysis of chemical and biological reacting systems, derivation of rate expressions from reaction mechanisms and equilibrium or steady state assumptions, design of chemical and biochemical reactors via synthesis of chemical …
This course applies the concepts of reaction rate, stoichiometry and equilibrium to the analysis of chemical and biological reacting systems, derivation of rate expressions from reaction mechanisms and equilibrium or steady state assumptions, design of chemical and biochemical reactors via synthesis of chemical kinetics, transport phenomena, and mass and energy balances. Topics covered include: chemical/biochemical pathways; enzymatic, pathway, and cell growth kinetics; batch, plug flow and well-stirred reactors for chemical reactions and cultivations of microorganisms and mammalian cells; heterogeneous and enzymatic catalysis; heat and mass transport in reactors, including diffusion to and within catalyst particles and cells or immobilized enzymes.
Learning Resource Types
assignment_turned_in Problem Sets with Solutions
grading Exams with Solutions
notes Lecture Notes
assignment_turned_in Activity Assignments with Examples
A real mixed tank can have bypasses, dead volumes, and recirculation.
In a real mixed tank, there is not perfect mixing due to dead volumes, bypasses, and recirculation. In a real plug flow reactor or packed bed reactor, there is back-mixing, axial dispersion, and channeling. See Lec #10 for how to model these behaviors. (Figure by MIT OCW.)