Chemical and Nuclear Engineering
101.
Introduction to Chemical Engineering and Nuclear Engineering.
(1)
An introduction to the professions of chemical engineering and nuclear engineering; current research in these fields; career choices; guidance and advice on curricular matters and effective study techniques for chemical and nuclear engineering students.
213.
Laboratory Electronics for Chemical and Nuclear Engineers.
(3)
Basic DC and AC circuits including capacitors and inductors and their applications in radiation measurement equipment and chemical process parameter measurements. Oscilloscopes, Op Amps, and Sensors and their use in the CHNE laboratories.
{Spring}
230.
Principles of Radiation Protection.
(3)
Nuclear reactions, decay, interactions of physical radiation with matter, methods of radiation detection and biological effects of radiation, external and internal dosimetry. Open-ended exercises and design project.
Prerequisite: CHEM 121 and 123L, MATH 162.
{Fall}
231.
Principles of Nuclear Engineering.
(3)
Introduction to nuclear engineering and nuclear processes; neutron interactions with matter, cross sections, fission, neutron diffusion, criticality, kinetics, chain reactions, reactor principles, fusion and the nuclear fuel cycle. Includes open-ended exercises. {Spring}
Prerequisite: CHEM 121 and 123L, MATH 162. Corequisite: 314.
251.
Chemical Process Calculations I.
(3)
Extensive problem work in material and energy balances for steady state processes. Students will utilize physical properties, chemistry and computer skills to obtain solutions. Detailed examination of case studies demonstrating the fundamentals of process analysis.
Prerequisite: CHEM 122 and 124L
{Fall}
253.
Chemical Process Calculations II.
(3)
Continuation of 251. Unsteady-state material and energy balances; computer solutions to chemical engineering problems using spreadsheets and commercial process plant simulation programs; staged operations for chemical separations. {Spring}
Prerequisite: 251
302.
Chemical Engineering Thermodynamics.
(4)
Principles of chemical thermodynamics and their applications to energy conversion, phase and reaction equilibrium and the calculation of thermodynamic properties.
Prerequisite: 251
{Spring}
310.
Neutron Diffusion Theory.
(3)
Radioactive decay chains, fission product poison burnup, point reactor kinetics with and without delayed neutrons. Neutron diffusion equation, criticality condition and critical size calculations.
Prerequisite: 231 and MATH 316.
{Spring}
311.
Introduction to Transport Phenomena.
(4)
The mechanisms and the related mathematical analysis of momentum and heat transport in both the molecular and turbulent regimes. Similarities and differences between transport types and the prediction of transport properties.
Prerequisite: (231 or 253) Corequisite: 317
{Fall}
312.
Unit Operations.
(3)
A study of the unit operations involved with momentum and heat transfer. Focus will be on the basics of equipment design and how to synthesize a process from the basic units. Includes extensive use of computer techniques and design exercises.
Prerequisite: 311
{Spring}
313L.
Introduction to Laboratory Techniques for Nuclear Engineering.
(3)
Techniques for error analysis, experiments in fluid flow, heat transfer, neutron detectors and neutron activation plus neutron diffusion theory and Fermi age. Design and development of experiments, emphasis on written presentations.
Prerequisite: ENGL 219 Corequisite: 312
{Spring}
314.
Thermodynamics and Nuclear Systems.
(3)
First and second law of thermodynamics and application to electrical generation, particularly nuclear energy conversion systems. Types of nuclear power plants, primary, secondary systems, feedwater, regeneration, and superheating.
Corequisite: 231
{Spring}
317.
Chemical and Nuclear Engineering Analysis.
(3)
Application of analytical and numerical techniques to the solution of frequently encountered engineering problems. Included are data analysis and interpretation; problem formulation; solution of ODEs and PDEs encountered in transport phenomena and kinetics; and elementary control theory.
Prerequisite: MATH 316 Corequisite: 311
{Fall}
318L.
Chemical Engineering Laboratory I.
(1)
Laboratory experiments in chemical thermodynamics. The lab will include a module on computer aided data acquisition. Students will apply concepts of error analysis and use computer software for interpretation of experimental data.
Prerequisite: 253 and 302.
{Fall}
319L.
Chemical Engineering Laboratory II.
(1)
Laboratory experiments in fluids and heat transfer. Students will apply concepts of error analysis and use computational fluid dynamics software for interpretation of experimental data.
Prerequisite: 311
{Spring}
321.
Mass Transfer.
(3)
Continuation of 311. The mechanisms and the related mathematical analysis of mass transport in both molecular and turbulent regimes. Similarities and differences among mass, momentum and heat transport. Predication of mass transport properties. Design of separation systems based on mass transfer.
Prerequisite: 253 and 311.
{Spring}
**323L.
Radiation Detection and Measurement.
(3)
Radiation interaction with matter and detection techniques for nuclear radiations. Experiments will be performed using gas, scintillation and semiconductor counters and include the design of experiments and identification of unknown radionuclides.
Prerequisite: 230
{Fall}
*330.
Nuclear Engineering Science.
(2)
Nuclear reactions, cross sections and reaction rates, quantum effects, atomic structure, nuclear properties, nuclear stability and decay modes.{Spring}
Prerequisite: 230 and 231 and MATH 316 and PHYC 262
361.
Biomolecular Engineering.
(3)
This course introduces concepts and principles of biomolecular engineering as they reflect the chemical engineering discipline. It builds on issues in biological systems to introduce contemporary technology avenues in biochemical, biomaterials, metabolic and tissue engineering.
371.
Introduction to Materials Engineering.
(3)
This course develops an understanding of materials from a molecular viewpoint. The structure, properties, and processing of metals, ceramics, polymers, and nanostructured materials are treated in an integrated fashion. Applications include nanotechnology, and biology.
{Spring}
372.
Nuclear Materials Engineering.
(2)
Understanding of material behavior from a molecular viewpoint. The effects of structure, properties, and processing of materials used in nuclear systems on their behavior in radiation environments.
{Spring}
403 / 503.
Heterogeneous Catalysis Seminar.
(2 to a maximum of 20 Δ)
Discussion of current research in heterogeneous catalysis and materials characterization. Students learn to read the literature critically and to present reviews of ongoing research.
404 / 504.
Nanomaterials Seminar.
(2 to a maximum of 20 Δ)
Investigate, evaluate, and discuss current frontier topics in sol-gel synthesis of nanostructured materials through a series of presentations.
405 .
High Performance Engines.
(3)
(Also offered as ME 405)
Students will capitalize on 1) applications of engineering fundamentals to engine operation and design; 2) implementation of computing and information technology for modeling, simulation, visualization, and design; and 3) cases studies of “famous” racing engines.
Prerequisite: 302 or ME 301
406 / 506.
Bioengineering Seminar.
(2 to a maximum of 20 Δ)
Emerging bioengineering concepts and applications with emphasis on materials and device technologies.
*410.
Nuclear Reactor Theory I.
(3)
Neutron transport equation, differential scattering cross section, diffusion approximation, one group diffusion theory including green’s function and eigenfunction expansion, Breit-Wigner formula, slowing down theory, reactor kinetics, multigroup methods, topics selected from numerical methods for reactor analysis.
Prerequisite: 314 and MATH 316
{Fall}
*413L.
Nuclear Engineering Laboratory.
(3)
Laboratory investigations of the theory and practice of nuclear chain-reacting systems including open-ended experiments and experimental design, covering reactor kinetics, importance functions and criticality.
One lecture, 6 hours lab.
Prerequisite: 313L and 410
{Spring}
418L.
Chemical Engineering Laboratory III.
(1)
Laboratory experiments in mass transfer and unit operations. Students will plan experiments to study the operation of process equipment such as heat exchanger, distillation columns, etc. Fundamental experiments on mass transfer are also included.
Prerequisite: 312 and 321
{Fall}
419L.
Chemical Engineering Laboratory IV.
(2)
Laboratory experiments in kinetics and process control. Students will also do an in-depth project in their chosen chemical engineering concentration.
Prerequisite: 461 Pre- or corequisite: 454
{Spring}
432.
Introduction to Medical Physics.
(3)
(Also offered as MPHY 432)
Basic atomic physics, radiation interactions, image formation, scatter and resolution, x-ray equipment and digital properties, digital imaging, computed tomography, magnetic resonance imaging, ultrasound imaging, radiation oncology principles, brachytherapy, nuclear medicine physics, radiation protection, regulations, and radiation biology.
Restriction: Permission of instructor
436 / 536.
Biomedical Technology.
(3)
Fundamental concepts of the transport processes in the human body. Applications of the basic transport principles to the biomedical systems, e.g., artificial organs and the measurement of the rheological properties of blood. Use of biomaterials.
439 / 539.
Radioactive Waste Management.
(3)
(Also offered as CE 539)
Introduction to the nuclear fuel cycle emphasizing sources, characteristics and management of radioactive wastes. Types of radiation, radioactive decay calculations, shielding requirements. Radwaste management technologies and disposal options.
{Fall}
449 .
Seminar in Hazardous Waste Management.
(1, no limit Δ)
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.
451 / 452.
Senior Seminar.
(1, 1)
Senior year. Reports on selected topics and surveys; presentation and discussion of papers from current technical journals, and topics of interest to chemical and nuclear engineers.
{Fall, Spring}
454.
Process Dynamics and Control.
(3)
Application of special mathematical techniques to the analysis of chemical processes and the elements of process control. Computer experience suggested.
Prerequisite: 317
{Spring}
**461.
Chemical Reactor Engineering.
(3)
Elementary principles of chemical reactor design and operation utilizing the kinetics of homogeneous and heterogeneous-catalytic reactions.
Prerequisite: 311 and 317
{Fall}
462.
Monte Carlo Techniques for Nuclear Systems.
(3)
Monte Carlo methods for nuclear criticality and reactor analysis and radiation shielding calculation using production Monte Carlo codes, understand basics of probability and statistics and of particle transport in the context of Monte Carlo methods.
Corequisite: 410
{Fall}
464 / 564.
Thermal-Hydraulics of Nuclear Systems.
(3)
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.
Prerequisite: 311 and 313L and 317
{Fall}
*466.
Nuclear Environmental Safety Analysis.
(3)
Radiation environment, transport, shielding, dose calculations, safety, monitoring, guidelines and regulations; radioactive waste handling and disposal.
Prerequisite: MATH 316
{Fall}
468 / 568 .
Introduction to Space Nuclear Power.
(3)
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 311
{Spring}
470.
Nuclear Fuel Cycle and Materials.
(3)
Materials for use in nuclear reactors, metallurgy and irradiation behavior, fundamentals of the nuclear fuel cycle including the uranium, thorium, and advanced fuel cycles.
{Spring}
*475.
Polymer Science and Engineering.
(3)
Curro
(Also offered as NSMS 575)
Introduces wide range of contemporary polymer science topics, emphasizing physical chemistry, polymer physics and engineering properties of polymer systems. Exposure to unique behavior of polymers in engineering applications and preparation for further studies in polymers.
*476.
Nuclear Chemical Engineering.
(3)
Fuel cycles in nuclear reactors; production of reactor fuels; processing of spent fuels by precipitation, solvent extraction, etc.; and separation of isotopes.
{Offered upon demand}
477 / 577.
Electrochemical Engineering.
(3)
Introduction of the principles of electrochemistry and their applications in materials characterization, corrosion, electro-plating and etching. The course builds on electrochemical kinetics and discusses the design of sensors, batteries and fuel cells.
Prerequisite: 302
{Spring upon demand}
*485.
Fusion Technology.
(3)
The technology of fusion reactor systems including basic magnetic and inertial confinement physics; system designs; material considerations; shielding; blanket designs; fuel cycle; plant operations; magnets; and ICF drivers.
Prerequisite: MATH 316
{Spring}
486 / 586.
Statistical Design of Experiments for Semiconductor Manufacturing.
(3)
Essential statistical tools for the collection, analysis, and interpretation of data, as applied to the design and control of processes for semiconductor manufacturing. Basic statistical concepts; simple comparative experiments; analysis of variance; randomization, replication and blocking; full-factorial, fractional factorial, response-surface, nested and split-lot designs, utilization of RS/1 software.
491 – 492.
Undergraduate Problems.
(1-3 to a maximum of 6 Δ)
Advanced studies in various areas of chemical and nuclear engineering.
{Summer, Fall, Spring}
493L.
Chemical Engineering Design.
(3)
Principles and practices of chemical engineering design, including process flow sheets, equipment design and specification, process modeling and simulation, economic analysis, and hazard analysis. In-depth design of at least one commercial-scale chemical process.
Prerequisite: 253 and 302 and 312 and 321
{Fall}
494L.
Advanced Chemical Engineering Design.
(3)
Continued practice in creative chemical engineering design, including safety, health and environmental issues. Detailed project on a major open-ended process design or research problem.
Prerequisite: 493L
{Spring}
495 – 496.
Chemical and Nuclear Engineering Honors Problems I and II.
(1-6, 1-6 to a maximum of 6 Δ)
Senior thesis for students seeking departmental honors.
{Summer, Fall, Spring}
*497L.
Introduction to Nuclear Engineering Design.
(3)
Problem solving techniques, nuclear systems, design, interactions of parameters and the importance of trade-offs and optimization in design. Neutronics, computer models and impact of cross sections and materials on fissile systems.
Two lectures, 2 hours lab.
Prerequisite: 317 or 330 or 410
{Fall}
498L.
Nuclear Engineering Design.
(4)
Students will work in teams on a capstone design project requiring the application of nuclear engineering principles and the integration of material from other disciplines, with emphasis on creativity, decision-making and interactive design.
Three lectures, 3 hours lab.
Prerequisite: 464 and 497L.
{Spring}
499.
Selected Topics.
(1-3, no limit Δ)
A course which permits various faculty members to present detailed examinations of developing sciences and technologies in a classroom setting.
{Offered upon demand}
501.
Chemical and Nuclear Engineering Seminar.
(1, no limit Δ)
Colloquia, special lectures and individual study in areas of current research. A maximum of 3 credits can be applied toward degree.
{Fall, Spring}
502.
Chemical and Nuclear Engineering Research Methods Seminar.
(1)
Students will work on developing research proposals for their masters or doctoral degree. The course will involve oral presentations of proposals and journal article critiques.
{Fall}
503 - 403.
Heterogeneous Catalysis Seminar.
(2 to a maximum of 20 Δ)
Discussion of current research in heterogeneous catalysis and materials characterization. Students learn to read the literature critically and to present reviews of ongoing research.
504 / 404.
Nanomaterials Seminar.
(2 to a maximum of 20 Δ)
Investigate, evaluate, and discuss current frontier topics in sol-gel synthesis of nanostructured materials through a series of presentations.
506 / 406.
Bioengineering Seminar.
(2 to a maximum of 20 Δ)
Emerging bioengineering concepts and applications with emphasis on materials and device technologies.
507 .
Surface and Material Engineering.
(2 to a maximum of 20 Δ)
Modern concepts of surface science and materials engineering are discussed within the context of surface functionalization, surface analysis, heteroepitaxy, nanocrystal synthesis, and fluidic separation.
2 hours seminar.
{Fall, Spring}
508 .
Nuclear Engineering Seminar.
(2 to a maximum of 20 Δ)
Discussion of topics such as space nuclear power and propulsion, reactor design thermal-hydraulics, nuclear fuel cycles and materials, energy conversion, computation and simulation, space radiation effects and shielding, criticality safety, and instrumentation and control.
{Fall, Spring, offered upon demand}
511.
Nuclear Reactor Theory II.
(3)
The theory of nuclear chain-reacting systems with emphasis on computer methods used in current applications. Multigroup diffusion theory, transport theory and Monte Carlo methods and applications to nuclear system design.
Prerequisite: 410 and 525
{Spring}
512.
Characterization Methods for Nanostructures.
(3)
(Also offered as NSMS 512)
Nanostructure characterization methods. Examine principles underlying techniques and limitations, and how to interpret data from each method: electron beam, scanning probe, x-ray, neutron scattering, optical and near field optical. Lab demonstrations and projects provide experience.
513L.
Nuclear Engineering Laboratory II.
(1 to a maximum of 4 Δ)
Laboratory investigations of the theory and practice of nuclear chain-reacting systems. Experiments on the UNM AGN-201M reactor and the ACRR at SNL. Course credit based on the extent of related course work in student’s undergraduate program.
One lecture, 6 hours lab.
{Spring upon demand}
515.
Special Topics.
(1-3, no limit Δ)
{Offered upon demand}
516.
Medical Imaging I-X-ray Physics.
(3)
(Also offered as MPHY 516)
Course provides review of x-ray interactions, x-ray production, film-screen and film processing, mammography, fluoroscopy, image quality, digital radiography, physics of computed tomography, PACS and digital systems, and diagnostic radiation shielding.
Corequisite: 517L
{Fall}
Restriction: permission of instructor
518.
Synthesis of Nanostructures.
(3)
(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 (patterned optical exposure of photosensitive materials) and ‘bottom-up’ self-assembly. Labs will synthesize samples.
Prerequisite: NSMS 510
{Spring}
519.
Medical Imaging II - MR, Ultrasound and Nuclear Medicine Physics.
(3)
(Also offered as MPHY 518)
MR basic physics, MR imaging equipment, and ultrasound imaging physics. Nuclear medicine imaging physics including: radioactive decay, isotope production, detector systems, Na I gamma camera imaging systems, PET/SPECT cameras systems, regulations and patient dose calculations.
Corequisite: 519L
Restriction: permission of instructor.
519L.
Medical Imaging Laboratory II - MR, Ultrasound and Nuclear Imaging Physics.
(1)
(Also offered as MPHY 519L)
Perform MRI ACR QC tests and Ultrasound ACR QA tests. Perform QC tests on dose calibrator, gamma camera, PET camera, SPECT camera. Perform a leak test on a sealed radioactive material source. Visit a PET cyclotron.
Corequisite: 519
Restriction: permission of instructor
520.
Radiation Interactions and Transport.
(3)
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}
521.
Advanced Transport Phenomena I.
(3)
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}
522L.
Fundamentals of Nanofluidics.
(3)
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.
523L.
Environmental Measurements Laboratory.
(1 to a maximum of 4 Δ)
In-depth consideration of radiation detection systems and nuclear measurement techniques. Experiments using semiconductor devices, MCA/MCSs, 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.
Two lectures, 3 hours lab.
{Fall}
524.
Interaction of Radiation with Matter.
(3)
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: 330 and MATH 316.
{Fall}
525.
Methods of Analysis in Chemical and Nuclear Engineering.
(3)
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}
526.
Advanced Analysis in Chemical and Nuclear Engineering.
(3)
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}
527.
Radiation Biology for Engineers and Scientists.
(3)
(Also offered as MPHY 527)
Covering fundamentals of the biological effects of ionizing radiation on living systems, especially man; basic biological mechanisms which bring about somatic and genetic effects; and the effect of ionizing radiation on cell cultures.
Restriction: permission of instructor.
528.
External Radiation Dosimetry.
(3)
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: 524
{Spring}
529.
Internal Radiation Dosimetry.
(3)
Internal contamination, radiation quantities, ICRP dose methodologies, lung models, bioassay, whole body counting, uranium and plutonium toxicology and metabolism, alpha dosimetry and ventilation control/air sampling.
Prerequisite: 524
{Fall}
530.
Surface and Interfacial Phenomena.
(3)
Van Swol
(Also offered as NSMS 530)
Introduces various intermolecular interactions in solutions and in colloidal systems; colloidal systems; surfaces; interparticle interactions; polymer-coated surfaces; polymers in solution, viscosity in thin liquid films; surfactant self-assembly; and surfactants in surfaces.
531.
Nanoscale Quantum Structure Growth and Device Applications.
(3)
(Also offered as NSMS 531)
Introduction to vapor-phase transport and surface phenomena that govern crystal growth, nanostructure patterning, and device performance.
{Fall upon demand}
536 / 436.
Biomedical Technology.
(3)
Fundamental concepts of the transport processes in the human body. Applications of the basic transport principles to the biomedical systems, e.g., artificial organs and the measurement of the rheological properties of blood. Use of biomaterials.
539 / 439.
Radioactive Waste Management .
(3)
(Also offered as CE 539)
Introduction to the nuclear fuel cycle emphasizing sources, characteristics and management of radioactive wastes. Types of radiation, radioactive decay calculations, shielding requirements. Radwaste management technologies and disposal options.
{Fall}
540.
Radiation Oncology Physics.
(3)
(Also offered as MPHY 540)
The course will cover the operation of linear accelerators, measurement of absorbed dose and quality of x-ray beams, dose distribution and scatter analysis, and clinical dose calculations for electron and photon beams. Techniques such as IMRT, total body irradiation, and SRS will be discussed. Brachytherapy treatment planning including HDR, LDR and intravascular treatments will be covered.
Corequisite: 541L
Restriction: permission of instructor
541L.
Radiation Oncology Physics Laboratory.
(3)
(Also offered as MPHY 541L)
Complete a number of clinical treatment plans, participate in the annual calibration of a linear accelerator, acquire basic photon and electron dose data for a computerized treatment planning system, perform several brachytherapy treatment plans including HDR and LDR plans, and perform an IMRT QA validation.
Corequisite: 540
Restriction: permission of instructor
542.
Advanced Chemical Engineering Thermodynamics.
(3)
Advanced thermodynamics with reference to its application in chemical engineering.
{Fall}
546.
Charged Particle Beams and High Power Microwaves [Charged Particle Beams.] .
(3 to a maximum of 9 Δ)
(Also offered as ECE 558)
Overview of physics of particle beams and applications at high-current and high-energy. Topics include review of collective physics, beam emittance, space-charge forces, transport at high power levels, and application to high power microwave generation.
Prerequisite: ECE 557 or CHNE 545
550.
Social and Ethical Issues in Nanotechnology.
(1-3, [3])
(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.
551 – 552.
Problems.
(1-3, 1-3 each semester Δ)
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.
560.
Nuclear Reactor Kinetics and Control.
(3)
Theory of the kinetic behavior of a nuclear reactor system with emphasis on control and dynamic behavior.
Prerequisite: 410 and 525
{Offered upon demand}
561.
Kinetics of Chemical Processes.
(3)
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}
563.
Advanced Radiation Shielding.
(3)
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}
564 / 464.
Thermal-Hydraulics of Nuclear Systems.
(3)
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}
568 / 468.
Introduction to Space Nuclear Power.
(3)
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}
575.
Selected Topics in Material Science.
(1-3, no limit Δ)
May be counted an unlimited number of times toward degree, with departmental approval, since content varies. Credit is determined based on the content of the course.
{Offered upon demand}
576.
Selected Topics in Aerosol Science.
(3 to a maximum of 6 hours Δ)
Analysis of the motion of both charged and neutral aerosol particles; molecular and convective diffusion, particle size and classification, coagulation, precipitation and particle capture, current aerosol research and instrumentation.
{Offered upon demand}
577 / 477.
Electrochemical Engineering.
(3)
Introduction of the principles of electrochemistry and their applications in materials characterization, corrosion, electro-plating and etching. The course builds on electrochemical kinetics and discusses the design of sensors, batteries and fuel cells.
Prerequisite: 302, 461
{Spring upon demand}
582.
Inertial Confinement Fusion.
(3)
Theory and technology of inertial confinement fusion, including target physics: laser and particle beam physics and technology; reactor engineering.
Pre- or corequisite: 534
{Offered upon demand}
586 / 486.
Statistical Design of Experiments for Semiconductor Manufacturing.
(3)
Statistical tools for collection, analysis, and interpretation of data. Design and control of processes for semiconductor manufacturing. Analysis of variance; randomization, replication, blocking; full-factorial, response-surface, nested, split-lot, Taguchi designs; utilization of RS/1 software.
591.
Practicum.
(6)
Also offered as MPHY 591. Professional practice experience in radiation protection and environmental measurements in non-traditional settings under the guidance of health physicists and radiation protection engineers. Internship arrangement with a local facility employing health physicists or related personnel such as a national laboratory, analytical facility, or hospital.
{Summer, Fall, Spring}
599.
Master’s Thesis.
(1-6, no limit Δ)
See Graduate Programs section for total credit requirements.
Offered on a CR/NC basis only.
610.
Advanced Nuclear Reactor Theory.
(3)
Advanced numerical methods in neutral and charged particle transport, including discontinuous finite element methods, structured and unstructured grids, adjoint techniques and Monte Carlo methods.
Prerequisite: 511
{Fall 2005 and alternate years}
699.
Dissertation.
(3-12, no limit Δ)
See Graduate Programs section for total credit requirements.
Offered on a CR/NC basis only.