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Course Criteria
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3.00 Credits
Invited lectures on a variety of topics in hazardous waste, environmental engineering and science and related topics. Students prepare short written assignments. May be counted twice toward a degree.
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3.00 Credits
Mills, Fledderman (Also offered as ECE, NSMS 550.) In this course, students will examine issues arising from this emerging technology, including those of privacy, health and safety, the environment, public perception and human enhancement.
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3.00 Credits
Advanced study, design or research either on an individual or small group basis with an instructor. Recent topics have included convective diffusion, reactor safety, inertial confinement fusion and nuclear waste management.
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3.00 Credits
(Also offered as ECE 553L.) Theory and practice of plasma generation and diagnostics, coordinated lectures and experiments, emphasis on simple methods of plasma production and selection of appropriate diagnostic techniques, applications to plasma processing and fusion. Prerequisite: ECE 534.
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3.00 Credits
(Also offered as ECE 555.) The theory of gas discharges and its application to pulsed power technology. Boltzmann equation, distribution functions, breakdown mechanisms, transport coefficients, self-sustained discharges, collisions, gasses at E/N, electron density generation and decay processes. {Fall}
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3.00 Credits
Theory of the kinetic behavior of a nuclear reactor system with emphasis on control and dynamic behavior. Prerequisite: 410 and 525. {offered upon demand}
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3.00 Credits
Rate equations for simple and complex chemical processes, both homogeneous and heterogeneous. Experimental methods and interpretation of kinetic data for use in chemical reactor design and analysis. Applications to complex industrial problems. {Spring}
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3.00 Credits
Introduction to Monte Carlo techniques, sampling, and statistics of radiation process, charged particle interactions, three dimensional radiation transport, design of shielding, shield materials, shield heating, and shield optimization. Comparisons will be made between the experimental performance and computer predicted performance of student designs. Prerequisite: 525. {Fall, Spring upon demand}
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3.00 Credits
Nuclear system heat transfer and fluid flow; convection in single and two phase flow; liquid metal heat transfer, pressure loss calculations; fuel element design and heat transfer; thermal-hydraulics design of nuclear systems. {Fall}
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3.00 Credits
Introduction to design and mass optimization of Space Power Systems, passive and active energy conversion systems, and design of RTG's, radiation shield, heat pipe theory, design and applications, advanced radiators, TE-EM pumps and orbital lifetime calculations and safety. Prerequisite: 231 and MATH 316. {Spring}
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