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Course Criteria
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3.00 Credits
{Offered upon demand}
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3.00 Credits
(Also offered as ECE, NSMS 518.) Underlying physical and chemical principles (optics, organic and inorganic chemistry, colloid chemistry, surface and materials science) for nanostructure formation using 'top-down' lithography (patternedoptical exposure of photosensitive materials) and 'bottom-up'self-assembly. Labs will synthesize samples. Prerequisite: 510. {Spring}
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3.00 Credits
Theoretical and numerical methods for neutral and charged particle interactions and transport in matter. Linear transport theory, spherical harmonics expansions, PN methods, Gauss quadra, discrete ordinates SN methods, discretization techniques, Fokker-Planck theory. Development of calculational methods including computer codes. Applications to nuclear systems. Prerequisite: 317 and 410 and 525. {Spring, upon demand}
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3.00 Credits
Equations of change applied to momentum, energy and mass transfer. Analogies between these phenomena and their limitations. Transport dependent on two independent variables, unsteady state problems {Spring}
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3.00 Credits
Petsev, Lopez, Han (Also offered as NSMS 522L.) This course exposes students to comprehensive yet essential elements in understanding nanofluidics for the purpose of effective separation of biomolecules: dynamics of complex fluids, colloidal chemistry, biochemistry, biomimetic surface functionalization, electrosomosis/ electrophoresis, electrodynamics, optics, and spectroscopy.
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1.00 - 4.00 Credits
In-depth consideration of radiation detection systems and nuclear measurement techniques. Experiments using semiconductor devices, MCA/MSCs, sampling techniques, dosimeters, tracer techniques and radiochemistry. Emphasis on selection of sampling techniques and instrumentation for measuring low-levels of radiation in air, soil and water. Course credit determined for each student based on the extent of related laboratory work in his or her undergraduate program. Up to 4 credits may apply toward degree. Two lectures, 3 hours lab. {Fall}
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3.00 Credits
Nuclear models and energy levels, cross sections, decay processes, range/energy relationships for alphas, betas, gammas, neutrons and fission products. Ionization, scattering and radiative energy exchange processes. Effect of radiation on typical materials used in the nuclear industry. Both theory and application will be presented. Prerequisite: 316. {Fall}
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3.00 Credits
Mathematical methods used in chemical and nuclear engineering; partial differential equations of series solutions transport processes, integral transforms. Applications in heat transfer, fluid mechanics and neutron diffusion. Separation of variables eigen function expansion {Fall}
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3.00 Credits
Extension of 525 to more advanced methods including Green's functions, Sturm-Liouville theory, special functions, complex variables, integral transforms. Prerequisite: 525. {Spring upon demand}
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3.00 Credits
Ionizing radiation, Kerma, Fluence, Dose, and Exposure, Attenuation and Buildup, Charged Particle Equilibrium, Bragg-Gray Cavity Theory and other Cavities, Fundamentals of Dosimetry, Ionizations Chambers, Integrating Dosimetry, and Pulse Mode Detectors, and Neutron Interactions and Dosimetry. Both theory and applications will be presented. Pre- or corequisite: 466 and 524. {Spring}
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