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Course Criteria
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3.00 Credits
An introduction to transport phenomena in cellular and whole organ systems. Application of transport theory including advection and diffusion to the movement of molecules in biological systems, including the cardiovascular system (heart and microcirculation), and the lung. Prerequisite: CBEMS120A or CBEMS125A or consent of instructor. (Design units: 0)
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4.00 Credits
Fluid statics, surface tension, Newton's Law of viscosity, non-Newtonian and complex flows, momentum equations, momentum transport, laminar and turbulent flow, velocity profiles, flow in pipes, flow around objects, design of piping systems, pumps and mixing and other applications to chemical and related industries. Prerequisites: CBEMS45A-B-C; Mathematics 3D. Only one course from CBEMS125A, CBEMS120A, MAE130A, MAEH130A, CEE170, and CEEH170 may be taken for credit. (Design units: 1)
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3.00 Credits
Principles of conduction, radiation, and convection of heat; phenomenological rate laws, differential and macroscopic energy balances; heat transfer rates, steady state and unsteady state conduction, convection; applications to chemical and related industries. Prerequisite: CBEMS125A. Only one course from CBEMS125B, CBEMS120B, and MAE120 may be taken for credit. (Design units: 1)
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3.00 Credits
Molecular and continuum approaches to diffusion and convection in fluids and multi-component mixtures; mass transfer rates; steady state, quasi-steady state and transient mass transfer; effect of reactions on mass transfer; convective mass transfer coefficients; simultaneous mass, heat and momentum transfer; applications to chemical and related industries. Prerequisite: CBEMS125B. CBEMS125C and BME150 may not both be taken for credit. (Design units: 1)
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3.00 Credits
Biophysical principles governing the interaction of laser radiation with biological materials, cells, and tissues. Utilization of these principles in several biomedical therapeutic and diagnostic applications is also covered and discussed in detail. Prerequisites: CBEMS120A-B or CBEMS125A-B-C; or consent of instructor. Concurrent with CBEMS226. (Design units: 0)
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4.00 Credits
Application of equilibria and mass and energy balances for design of separation processes. Use of equilibrium laws for design of distillation, absorption, stripping, and extraction equipment. Design of multicomponent separators. Prerequisite: CBEMS40B or CBEMS45B-C. (Design units: 3)
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3.00 Credits
Recovery and purification of biologically produced proteins and chemicals. Basic principles and engineering design of various separation processes including chromatography, electrophoresis, extraction, crystallization, and membrane separation. Prerequisites: CBEMS40A-B or CBEMS45A-B-C; CBEMS120A or CBEMS125A. (Design units: 1)
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3.00 Credits
Unique features of bioreactors. Analyses and design of bioreactors of batch, fed-batch, and continuous flow types. Microbial reactors with and without cell recycles. Bioreactor operations for industrial-important biological products and for biological treatment of wastewater. Prerequisites: CBEMS110. (Design units: 1.5)
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4.00 Credits
Dynamic responses and control of chemical process equipment, dynamic modeling of chemical processes, linear systems analysis, analyses and design of feedback loops and advanced control systems. Prerequisites: CBEMS110; CBEMS120B or CBEMS125B-C. (Design units: 1)
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4.00 Credits
Experimental study of thermodynamics, fluid mechanics, and heat and mass transfer. Operation and evaluation of process equipment, data analysis. Prerequisites: CBEMS40B or CBEMS45B-C; CBEMS110; and CBEMS120B or CBEMS125B-C. (Design units: 1)
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