Top Masters Programs in Nuclear Engineering

MECH_ENG 395: Special Topics: Fundamentals of Nuclear Reactor Physics.

The course is intended for juniors, seniors, and graduate students in engineering or physical science with no previous background in nuclear engineering. The course introduces the student to the physics and engineering of nuclear power reactor cores. Topics included are nuclear reactions, neutron chain reactions, criticality and reactor kinetics, neutron diffusion, energy transport and power distributions, reactivity feedback and control, long-term core behavior. Related issues of radioactive waste disposal, reactor accidents, and weapons proliferation will also be included in discussions.

Lewis, Fundamentals of Nuclear Reactor Physics, Academic Press, Burlington, MA, 2008.

The Nuclear Engineering offers three graduate degree programs: the Doctor of Philosophy (PhD), the Master of Engineering (MEng), and the Public Policy (MPP) Nuclear Engineering (MS) Concurrent Degree Program.

The following minimum requirements apply to all graduate programs and will be verified by the Graduate Division:.

If the applicant has completed a basic degree from a country or political entity (e.g., Quebec) where English is not the official language, adequate proficiency in English to do graduate work, as evidenced by a TOEFL score of at least 90 on the iBT test, 570 on the paper-and-pencil test, or an IELTS Band score of at least 7 on a 9-point scale (note that individual programs may set higher levels for any of these) and.

The Graduate Council views academic degrees not as vocational training certificates, but as evidence of broad training in research methods, independent study, and articulation of learning. Therefore, applicants who already have academic graduate degrees should be able to pursue new subject matter at an advanced level without the need to enroll in a related or similar graduate program.

Applicants with doctoral degrees may be admitted for an additional doctoral degree only if that degree program is in a general area of knowledge distinctly different from the field in which they earned their original degree.

Applicants may apply only to one single degree program or one concurrent degree program per admission cycle.

Unofficial transcripts must contain specific information including the name of the applicant, name of the school, all courses, grades, units, degree conferral (if applicable).

Letters of recommendation: Applicants may request online letters of recommendation through the online application system. Hard copies of recommendation letters must be sent directly to the program, by the recommender, not the Graduate Admissions.

Evidence of English language proficiency:All applicants who have completed a basic degree from a country or political entity in which the official language is not English are required to submit official evidence of English language proficiency. However, applicants who, at the time of application, have already completed at least one year of full-time academic course work with grades of B or better at a US university may submit an official transcript from the US university to fulfill this requirement. The following courses will not fulfill this requirement:.

Courses conducted in a language other than English,.

Courses that will be completed after the application is submitted, and.

Official TOEFL score reports must be sent directly from Educational Test Services (ETS). Official IELTS score reports must be sent electronically from the testing center to University of California, Berkeley, Graduate Division, Sproul Hall, Rm 318 MC 5900, Berkeley, CA 94720. TOEFL and IELTS score reports are only valid for two years prior to beginning the graduate program at UC Berkeley. Note: score reports can not expire before the month of June.

In order to receive the PhD in Nuclear Engineering, all students must successfully complete the following three milestones:.

Major Field (6 Graduate Level Nuclear Engineering Electives). A 3.0 GPA in the major is required.

One Technical Minor Field Outside Nuclear Engineering (2-3 courses 1 course must be graduate level). A 3.0 GPA minimum is required for both minors.

One Technical Minor Field Outside or in Nuclear Engineering (2-3 courses 1 course must be graduate level). All courses taken to fulfill the PhD course requirement must be letter-graded.

Students must pass a written screening exam during the first year in graduate study. Four of the seven areas must be passed in order the pass the exam. There are two chances to pass.

After completion of the coursework for the PhD the student takes the oral exam. The content of the exam is usually a presentation of the student research and questions relating the coursework in the outside minor.

In collaboration with other departments in the College of Engineering, Nuclear Engineering offers a one-year professional master degree. The accelerated program is designed to develop professional engineering leaders who understand the technical, environmental, economic, and social issues involved in the design and operation of nuclear engineering devices, systems, and organizations. Prospective students will be engineers, typically with industrial experience, who aspire to substantially advance in their careers and ultimately to lead large, complex organizations, including governments.

Curriculum of engineering leadership courses (8 units), and an integrative capstone project (5 units). See The Fung Institute for details.

The MEng degree requires a minimum of 25 units of coursework in three areas:.

CORE LEADERSHIP Curriculum (8 units, letter grade, required for degree).

Designed for Master of Engineering students, these courses explore key management and leadership concepts at the executive level that are relevant to technology-dependent enterprises. During the courses, students undertake rigorous case study analysis of actual business situations.

All Technical Electives must be NE graduate-level courses (200) and taken for a letter grade. Units for 298 (seminar) courses do not count for the degree.

The 9-month capstone experience will challenge you to integrate your technical and leadership skills to innovate in a dynamic, results-driven environment. Working on a team of 3 to 6 students over the course of the fall and spring semesters (5 units) you will engineer solutions using cutting edge technology and methods to address crucial industry, market or societal needs.

The Comprehensive Exam will be divided into two components, one devoted to leadership topics (to be administered by the Fung Institute), and the other to technical topics (to be administered by individual departments within COE). The exam may be written, oral, or a combination of the two.

NE students that participate in a capstone project outside of the NE department are required to highlight the NE component of their project or will be tested on NE related topics based on coursework taken.

The Master of Science Track is only accessible to students enrolled in our PhD program. Applicants interested in the Master degree are encouraged to Nuclear Engineering Master of Engineering program.

Students pursuing the MS Degree have two program options: Plan I, and Plan II.

Plan I requires at least 20 semester units of upper division (100 level) and graduate courses (200 level), plus a thesis.

Minimum 8 units of graduate-level courses in NE. Note: No than 2-299 units may count towards these 8 units. All 8 units must be taken for a letter grade (except the 299 units).

Minimum 12 units of graduate-level or upper division courses in NE or another department. Note: No than 2-299 units may count towards these 12 units.

Must have a cumulative GPA of 3.0 or higher to receive the degree.

Please note that you must apply for MS candidacy by submitting an application for advancement to MS candidacy using the eForm in Cal Central.

If a proposed committee member does not belong to the Academic Senate (i.e. LBL or LLNL), you are required to include a request for an exception (and the CV) together with the application for advancement to MS candidacy.

Plan II requires at least 24 semester units of upper division (100 level) and graduate courses (200 level), followed by a comprehensive final examination administered by the department. takes the form of an oral project presentation, and a written report.

Minimum 12 units of graduate-level courses in NE. Note: No than 2-299 units may count towards these 12 units. All 12 units must be taken for a letter grade (except the 299 units).

Minimum 12 units of graduate or upper division courses in NE or another department. Note: No than 2-299 units may count towards these 12 units.

Public Policy (MPP) and Nuclear Engineering (MS) Concurrent Degree Program.

Government and technology interact and with greater consequences, every year. Whether the issue area is nuclear security, environmental protection, intellectual property (copyright and the internet), health care, water or any of myriad other contexts, government agencies at all levels, non-profit organizations and private industry need people who understand technology on its own terms and also the ways government supports, controls, or directs it.

Complete required units in nuclear engineering, plus six elective agreeable to both schools.

Complete a paper that satisfies the MS Plan I or Plan II requirement, and the MPP APA (Advanced Policy Analysis) requirement.

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Terms offered: Fall 2022, Fall 2021, Fall 2020 of the elements of nuclear technology in use today for the production of energy and other radiation applications. Emphasis is on nuclear fission as an energy source, with a study of the basic physics of the nuclear fission process followed by detailed discussions of issues related to the control, radioactivity management, thermal energy management, fuel production, and spent fuel management. A discussion of the various reactor types in use around the world will include analysis of safety and nuclear proliferation issues surrounding the various technologies. Case studies of some reactor accidents and other nuclear-related incidents will be included.Introduction to Nuclear Engineering: [+].

Course Objectives: (1) To give students an understanding of the basic concepts of nuclear energy and other radiation applications, together with an of related aspects such as proliferation and waste management.(2) To provide students an of the elements of nuclear technology in use today for the production of energy and to set those elements in the broader contest of nuclear technology.

Student Learning Outcomes: At the end of the course, students should be able to: understand basic theoretical concepts of nuclear physics, reactor physics, and energy removal describe radiation damage mechanisms in materials and biological tissue, estimate radiation dose, understand radiation shielding understand the concepts of chain reaction, neutron balance, criticality, reactivity, and reactivity control describe the main nuclear power reactor designs and identify their major components describe core components and understand their function calculate cost of electricity based on simple economic principles describe the difference between PWR and BWR in terms of core design, steam cycle, and operation understand the concept of design-basis accidents, their causes, and their consequences identify the main steps and related facilities of fuel cycle understand the fundamental aspects of used fuel reprocessing and disposal.

Credit Restrictions: This course is restricted to students enrolled in the Master of Engineering degree program.

NUC ENG 201Nuclear Reactions and Interactions of Radiation with Matter4 Units.

Terms offered: Spring 2022, Spring 2020, Spring 2018 Interaction of gamma rays, neutrons, and charged particles with matter nuclear structure and radioactive decay cross sections and energetics of nuclear reactions nuclear fission and the fission products fission and fusion reactions as energy sources.Nuclear Reactions and Interactions of Radiation with Matter: [+].

Nuclear Reactions and Interactions of Radiation with Matter: Read Less [-].

NUC ENG 204Advanced Concepts in Radiation Detection and Measurements3 Units.

Terms offered: Fall 2022, Fall 2018, Fall 2015 Advanced concepts in the detection of ionizing radiation relevant for basic and applied sciences, nuclear non-proliferation, and land security. Concepts of signal generation and processing with advantages and drawbacks of a range of detection technologies. Laboratory comprises experiments to compare conventional analog and advanced digital signal processing, information generation and processing, position-sensitive detection, tracking, and imaging modalities.Advanced Concepts in Radiation Detection and Measurements: [+].

Advanced Concepts in Radiation Detection and Measurements: Read Less [-].

Terms offered: Fall 2022, Fall 2021 This course is designed to build the basic knowledge base to understand the physical principles of x-ray computed tomography (CT), positron emission tomography (PET), and single photon emission computed tomography (SPECT), radiologic imaging modalities using ionizing radiation. Using examples of CT, PET, and SPECT used in everyday disease management, this course will introduce theoretical foundations and practical applications for comprehensive understanding of these important noninvasive imaging techniques.Physical Principles of CT, PET, and SPECT Imaging: [+].

Course Objectives: The objective of this course is to understand physical principles of how biomedical imaging systems utilizing ionizing radiation (i.e., x-ray and gamma-ray) work.

Student Learning Outcomes: The students will have good understanding of physical principles of CT, PET, and SPECT imaging, and how these ionizing radiation imaging modalities are used in medicine and biomedical research.

Terms offered: Spring 2023, Spring 2022, Spring 2021 Energetics and kinetics of nuclear reactions and radioactive decay, fission, fusion, and reactions of low-energy neutrons properties of the fission products and the actinides nuclear models and transition probabilities interaction of radiation with matter.Nuclear Reactions and Radiation: [+].

Course Objectives: Provide the students with a solid understanding of the fundamentals of those aspect of low-energy nuclear physics that are most important to applications in such areas as nuclear engineering, nuclear and radiochemistry, geosciences, biotechnology, etc.

Student Learning Outcomes: Calculate estimates of nuclear masses and energetics based on empirical data and nuclear models. Calculate estimates of the lifetimes of nuclear states that are unstable to alpha-,beta and gamma decay and internal conversion based on the theory of simple nuclear models. Calculate the consequences of radioactive growth and decay and nuclear reactions. Calculate the energies of fission fragments and understand the charge and mass distributions of the fission products, and prompt neutron and gamma rays from fission Calculate the kinematics of the interaction of photons with matter and apply stopping power to determine the energy loss rate and ranges of charged particles in matter Use nuclear models to predict low-energy level structure and level energies. Use nuclear models to predict the spins and parities of low-lying levels and estimate their consequences with respect to radioactive decay Use nuclear models to understand the properties of neutron capture and the Breit-Wigner single level formula to calculate cross sections at resonance and thermal energies.

NUC ENG 211MRadiation Detection and Nuclear Instrumentation Laboratory4 Units.

Terms offered: Prior to 2007 Basic science of radiation measurement, nuclear instrumentation, neutronics, radiation dosimetry. The lectures emphasize the principles of radiation detection. The weekly laboratory applies a variety of radiation detection systems to the practical measurements of interest for nuclear power, nuclear and non-nuclear science, and environmental applications. Students present goals and approaches of the experiments being performed.Radiation Detection and Nuclear Instrumentation Laboratory: [+].

Radiation Detection and Nuclear Instrumentation Laboratory: Read Less [-].

NUC ENG 215MIntroduction to Nuclear Reactor Theory4 Units.

Terms offered: Spring 2023, Spring 2022, Spring 2021 Neutron interactions, nuclear fission, and chain reacting systematics in thermal and fast nuclear reactors. Diffusion and slowing down of neutrons. Criticality calculations. Nuclear reactor dynamics and reactivity feedback. Production of radionuclides in nuclear reactors. General aspects of nuclear core designs.Introduction to Nuclear Reactor Theory: [+].

Introduction to Nuclear Reactor Theory: Read Less [-].

NUC ENG 220Irradiation Effects in Nuclear Materials3 Units.

Terms offered: Spring 2023, Spring 2021, Spring 2019 Physical aspects and computer simulation of radiation damage in metals. Void swelling and irradiation creep. Mechanical analysis of structures under irradiation. Sputtering, blistering, and hydrogen behavior in fusion reactor materials.Irradiation Effects in Nuclear Materials: [+].

Irradiation Effects in Nuclear Materials: Read Less [-].

Terms offered: Fall 2022, Fall 2021, Fall 2020 Effects of irradiation on the atomic and mechanical properties of materials in nuclear reactors. Fission product swelling and release neutron damage to structural alloys fabrication and properties of uranium dioxide fuel.Nuclear Materials: [+].

Course Objectives: Develop an understanding of failure mechanism in materials and their impact in nuclear technology.

Review those aspects of fundamental solid state physics that are pertinent to understanding the effects of radiation on crystalline solids.Show how radiation, particularly by fast neutrons, affects the mechanical properties of fuel, cladding, and structural materials in a reactor core.

Student Learning Outcomes: Analyze the processes of fission gas release and swelling of reactor fuel. Deal with point defects in solids how they are produced at thermal equilibrium and by neutron irradiation how they agglomerate to form voids in metals or grow gas bubbles in the fuel. Kinchin-Pease model. Know the principal effects of radiation on metals: dislocation loops, voids, precipitates, and helium bubbles. Solve diffusion problems beginning from Fick law understand how the diffusion coefficient is related to the mobility of atoms in the crystalline lattice. Understand how the grain structure influences properties such as creep rate and fission product release (ceramic UO2). Understand the concept and quantitative properties of dislocations, and how irradiation-produced point defects influences their motion and hence material properties.

Prerequisites: Introductory course on properties of materials (MAT SCI 45) and upper division course in thermodynamics (ENGIN 40 or CHM ENG 141).

NUC ENG 221Corrosion in Nuclear Power Systems3 Units.

Terms offered: Spring 2022, Spring 2018, Spring 2016 Structural metals in nuclear power plants properties and fabrication of Zircaloy aqueous corrosion of reactor components structural integrity of reactor components under combined mechanical loading, neutron irradiation, and chemical environment.Corrosion in Nuclear Power Systems: [+].

Corrosion in Nuclear Power Systems: Read Less [-].

Prerequisites:NUC ENG 124 or an upper division course in differential equations.

Terms offered: Spring 2015, Spring 2013, Spring 2011 This course is intended for graduate students interested in acquiring a foundation in nuclear fuel cycle with topics ranging from nuclear-fuel reprocessing to waste treatment and final disposal. The emphasis is on the relationship between nuclear-power utilization and its environmental impacts. The lectures will consist of two parts. The first half includes mathematical models for individual processes in a fuel cycle, such as nuclear fuel reprocessing, waste solidification, repository performance, and nuclear transmutation in a nuclear reactor. In the second half, these individual models are integrated, which enables students to evaluate environmental impact of a fuel cycle.The Nuclear Fuel Cycle: [+].

Terms offered: Spring 2023, Spring 2022, Spring 2021 This course provides the student with a modern introduction to the basic industrial practices, modeling techniques, theoretical background, and computational methods to treat classical and cutting edge manufacturing processes in a coherent and self-consistent manner.Modeling and Simulation of Advanced Manufacturing Processes: [+].

Course Objectives: An introduction to modeling and simulation of modern manufacturing processes.

Terms offered: Spring 2023, Spring 2022, Spring 2021 Use of nuclear measurement techniques to detect clandestine movement and or possession of nuclear materials by third parties. Nuclear detection, forensics,signatures, and active and passive interrogation methodologies will be explored. Techniques currently deployed for arms control and treaty verification will be discussed. Emphasis will be placed on common elements of detection technology from the viewpoint of resolution of threat signatures from false positives due to naturally occurring radioactive material. Topics include passive and active neutron signals, gamma ray detection, fission neutron multiplicity, and U and Puisotopic identification and age determination.Analytical Methods for Non-Proliferation: [+].

Prerequisites:NUC ENG 101, PHYSICS 7C, or equivalent course in nuclear physics.

Terms offered: Fall 2022, Fall 2021, Fall 2020 Biomedical imaging is a clinically important application of engineering, applied mathematics, physics, and medicine. In this course, we apply linear systems theory and basic physics to analyze X-ray imaging, computerized tomography, nuclear medicine, and MRI. We cover the basic physics and instrumentation that characterizes medical image

Have scores sent to Georgia Institute of Technology, Graduate .

Determine if you will pay in-state or out-of-state tuition. For example, if you are an in-state resident and planning to take six credits for the Master of Architecture degree, the tuition cost will be $4,518.

Master of Science in Materials Science and Engineering.

Doctor of Philosophy with a major in Materials Science and Engineering.

Doctor of Philosophy with a major in Nuclear Engineering Sciences.

The Nuclear Engineering Program is housed within the Materials Science Engineering (MSE).

The requirements for completing a Master of Science (Non-Thesis) in Nuclear Engineering include a minimum number of credit hours, nuclear core courses, and a final project report. 30 credit hours of course work are required to earn a M.S. Students with graduate work in nuclear engineering or a related field from a different institution may transfer up 9 hours from that institution at the discretion of the Graduate School. Credit for nuclear engineering courses may be given at the discretion of the Graduate Program Coordinator. Students with graduate work in a different graduate program at the University of Florida may transfer up to 9 hours from that program at the discretion of the Graduate Program Coordinator.

A minimum of 24 of the 30 credit hours must be graded (A-E) lecture or lab courses with numbers with any engineering, science, math, or statistics prefix.

12 of the 30 credit hours must be graded (A-E) lecture or lab courses with numbers 5000+ with the nuclear engineering (ENU) prefix.

Letter graded). S U graded) may not be used for the M.S. non-thesis degree, nor may ENU 7979 (Advanced Research) and ENU 7980 (Doctoral Research).

Students should be advised that transitioning between the M.S. non-thesis and thesis programs may not be possible in the middle of their graduate studies. Even when allowed, not all credits may transfer to the new degree.

In conjunction with their course work, M.S. non-thesis students are required to produce an M.S. project report.

For students without a mentor, it is the responsibility of the student to propose an M.S. project for the approval of the Graduate Program Coordinator and to abide by the deadline set by the Graduate Program Coordinator for submission of the project (this deadline will be earlier than those set by the graduate school to allow time for technical review of the work). In this case the satisfactory unsatisfactory determination will be made by the Graduate Program Coordinator.

As a guideline, students should expect to spend not fewer than 300 hours (i.e. a half-time effort over a semester or a quarter-time effort over an academic year) on their M.S. project and to produce a report of 15 pages or .

In this case, the graduate coordinator will evaluate the M.S. project selected and produced by the student.

The requirements for completing a Master of Science (Thesis) in Nuclear Engineering include a minimum number of credit hours, nuclear core courses, and a final project report.

30 credit hours of course work are required to earn a M.S. Students with graduate work in nuclear engineering or a related field from a different institution may transfer up 9 hours from that institution at the discretion of the Graduate School. Credit for nuclear engineering courses may be given at the discretion of the Graduate Program Coordinator. Students with graduate work in a different graduate program at the University of Florida may transfer up to 9 hours from that program at the discretion of the Graduate Program Coordinator.

S U graded). letter-graded) may not be used for the M.S. thesis degree, nor may ENU 7979 (Advanced Research) and ENU 7980 (Doctoral Research).

Areas of interest for the applicants include (a) materials in nuclear and space environments (b) radiation interactions effects in materials and materials survivability (c) chemical engineering and processing of nuclear materials and (d) nuclear reactor thermal hydraulics.

The RadLab at The University of Texas at Austin focuses on research using radiation and radioactivity to improve security and quality of life.

The NETL reactor, designed by General Atomics, is a TRIGA Mark II nuclear research reactor. The NETL is the newest of the current fleet of U.S. university reactors.

The Nuclear and Applied Robotics Group is an interdisciplinary research group whose mission is to develop and deploy advanced robotics in hazardous environments in order to minimize risk for the human operator.

Dr. Derek Haas as Principal Investigator and Dr. Kevin Clarno and Dr. William Charlton as Co-Principal investigators, have received the single largest grant ever funded to the Nuclear and Radiation Engineering Program to lead the design of the reactor bay experimental research facilities and collaborate on the design and safety analysis for the first university-based molten salt research reactor. The $3.8 million grant is part of $30 million dollars allocated to The Nuclear Energy eXperimental Testing Research Alliance launched in spring 2019 and also includes Abilene Christian University (lead university where the research reactor will be built), Texas A M University and Georgia Institute of Technology all who are partnering with Natura Resources. They are also recruiting students and hiring several positions to staff the project, including one research fellow, one senior research fellow and a research associate.

The NSF GRFP recognizes and supports outstanding graduate students in NSF-supported STEM disciplines who are pursuing research-based master and doctoral degrees at accredited US institutions. The fellowship includes three years of including an annual stipend of $34,000 and a cost of education allowance of $12,000 to the institution. Khiloni will continue to work with Dr. Derek Haas in Nuclear Forensics.

The three-year, $161,000 fellowship includes a stipend for an internship at a national laboratory. Collin will continue to work with Dr. Kevin Clarno in computational nuclear engineering.

The Cockrell School of Engineering awards highly qualified first year graduate students one-year and partial fellowship.

Upayan Mathkari is First Student in NRE Integrated Bachelor and Master Degree Program.

We congratulate Upayan Mathkari as the first student in our Integrated Bachelor and Master Degree Program in our Nuclear and Radiation Engineering Program. By applying AP and Credit by Exam courses, having students take recommended summer courses, and allowing seniors to enroll in graduate-level engineering courses reserved for graduate credit, the program enables graduates to complete both degree requirements in five years.

Dr. Pryor heads up the highly successful national and internationally known Nuclear and Applied Robotics Group and has graduated multiple PhD and MS students involved in interdisciplinary research programs for applied robotics in hazardous environments.

Ryan Lester, MS student working with Dr. Derek Haas is designing a facility on one of the neutron beam ports in the reactor bay for the production of gaseous radiotracers for nuclear forensics application. Using cryogenic technology allows the placement of the sample much closer to the reactor core thus receiving a much higher neutron flux.

Research Engineer Mark Andrews working with Dr. William Charlton is studying the impact of irradiation of electronic components by mixed-fields of neutron and gamma-ray radiation with specific interests in the impact of thermal neutrons and the change in degradation due to the order of radiation incidence (for example, gamma-rays followed by neutrons versus neutrons followed by gamma-rays). The specific modes of damage vary depending upon the type and energy of the radiation incident upon the device.

PhD Student Adam Samia working with Dr. William Charlton is studying enhanced radiochemical separation of reactor-produced medical radioisotopes using the well-known Szilard-Chalmers effect with capture of the activated products during irradiation. He is studying two pathways for capture of the products: (1) using a solid adsorber suspended in an aqueous target solution and (2) by chemical reaction with a chelator in solution with the target material in solid form. Both pathways lead to simplified post-irradiation separation of the no-carrier-added product material through simple filtration techniques.

Postdoctoral Fellow Dr. Blake Anderson working with Dr. Mitch Pryor has developed a robotic system and analysis algorithms for locating unknown radioactive sources in nuclear environments. A scintillating detector on the robot collects a sequence of measurements at different locations, and the source positions and activities are estimated using statistical filtering methods. Gamma-ray spectroscopy identifies the species of the sources and enables robust background subtraction. The developed capabilities include modelling of attenuation by solid objects and decay of short-lived isotopes.

Tucker Sawyer and John Barlow working with Dr. Kevin Clarno are helping with the design and licensing of an advanced nuclear reactor, fueled with molten salt, that will be built in Texas in 2025. They are using the SCALE nuclear analysis code suite to model the transport of radiation throughout the reactor to determine the spatial distribution of the heat being generated from fission energy and assess how that distribution and magnitude will change as the fuel depletes and reactor operates.

This pilot program is to ascertain the provenance of fifteen ancient pottery samples using neutron activation analysis (Colin Brennan) and principal component analysis (Amaya Sinha).

Master of Science and PhD, Nuclear Engineering and Engineering Physics.

Bachelor of Science in Engineering Mechanics (+ Aerospace Engineering option).

Research and PhD, Engineering Mechanics.

For alumnus, benefits of nuclear engineering graduate education are clear.

Due to safety concerns for all prospective students during the COVID-19 crisis, GRE scores are optional for applications to all Engineering Mechanics and all Nuclear Engineering and Engineering Physics graduate programs through the Fall 2022 semester.

A broad program of instruction and research is offered in the principles of the interaction of radiation with matter and their applications, and in several areas of engineering physics. The program has strong engineering and applied science components. It emphasizes several areas of activity, including the research, design, development, and deployment of fission reactors fusion engineering plasma physics radiation damage to materials applied superconductivity and cryogenics and large-scale computing in engineering science.

The department is considered to have one of the top five nuclear engineering programs in the nation over the last 40 years. It incorporates several research organizations including the Wisconsin Institute of Nuclear Systems, the Pegasus Toroidal Experiment Program, the Fusion Technology Institute, and the Center for Plasma Theory and Computation.

Research may be performed in areas including next generation fission reactor engineering fluid and heat transfer modeling for transient analysis reactor monitoring and diagnostics fuel cycle analysis magnetic and inertial confinement fusion reactor engineering, including the physics of burning plasmas, plasma-wall interactions, neutron transport, tritium breeding, radiation damage, and liquid-metal heat transfer experimental and theoretical studies of plasmas including radio frequency heating, magnetic confinement, plasma instabilities, and plasma diagnostics industrial plasma physics, such as plasma processing and plasma source ion implantation superconducting magnets and cryogenics and theoretical and experimental studies of the damage to materials in fission and fusion reactors.

For s of our major research areas, lab tours and check out the EP grad recruiting page!

The Engineering Physics (EP) reviews Nuclear Engineering and Engineering Physics graduate student applications for the fall, spring and summer terms of each year.

Scores may not be than 5 years old from the start of the admissions term for which applicants are applying.

Please do not send any hard copies of transcripts unless specifically instructed to do so by the UW-Madison Graduate School.

All applicants must submit a statement of purpose reasons for graduate study. Note that information on research interests and aspirations is important for the application review process.

International Students: International applicants must submit TOEFL or IELTS scores. Scores are accepted if they are within two years of the start of the admissions term for which applicants are applying. IELTS scores should be electronically sent directly from IELTS to UW-Madison, Graduate Studies.

You earned a degree from a regionally accredited U.S. college or university not than 5 years prior to the anticipated semester of enrollment.

Window within your MyUW portal (information on this is received after submitting an application). You may need to activate a NetID to gain access to the MyUW portal (information sent after submitting an application).

Most admissions decisions are made by the end of March or by early April.

Graduate-student funding is an important consideration for both prospective students and the Department. Apart from national fellowships, graduate students in the Department are funded by research assistantships (RAs), teaching assistantships (TAs), project assistantships (PAs), internal fellowships, or they are self-funded. Decisions on RA positions are made at the investigator level and not at the Department level.

For PhD students, program admission and funding via assistantships are linked, subject to the following policies:.

If the Department extends an offer and the prospective PhD student accepts, the intention is to fund the student through degree completion, even if a student requires time than the guaranteed period.

It should be noted that research progress is required, regardless of the funding mechanism or funding level in order to maintain satisfactory progress toward the PhD degree.

Qualified students may be admitted without if they guarantee their own funding.

PhD students initially serving in TA positions typically move to RA positions when focusing on research. However, changes in research funding from federal agencies may also require a student to take a TA or PA position, at least temporarily, after holding an RA or fellowship. Students interested in gaining teaching experience may also request a TA position.

Because admission and are linked, a prospective PhD student may not be admitted until the Department has made the respective funding decision or the student has provided evidence of external fellowship support or a guarantee of self-funding.

Re-entry applicants: If you were previously enrolled as a graduate student in the Engineering Physics but have had a break in enrollment for a minimum of a fall or spring term, you will need to re-apply to resume your studies. Please review the Graduate School requirements for re-entry students.

PhD technical minor approval form (entered Fall 2019 or after).

The following is a list of available fellowship programs for Nuclear Engineering and Engineering Physics graduate students to apply:.

Defense Science, Mathematics And Research for Transformation (SMART) Scholarship.

U.S. Air Force Graduate Student Fellowships in Nuclear Engineering.

National Science Foundation (NSF) Graduate Research Fellowship Program.

Graduate Fellowships for Science, Technology, Engineering, and Mathematics Diversity.

The Nuclear, Plasma, and Radiological Engineering (NPRE) offers programs leading to Master of Science and Doctor of Philosophy degrees in Nuclear, Plasma, and Radiological Engineering. The Master of Science and Doctor of Philosophy degree programs are centered around five theme areas:.

Advanced course work and active research programs are offered in all of these areas.

The NPRE department also administers for The Grainger College of Engineering a Master of Engineering degree program with a Concentration in Energy Systems.

Doctor of Philosophy (Ph.D.) in Nuclear, Plasma, and Radiological Engineering.

Doctor of Medicine (M.D.) through the Medical Scholars Program.

Computational and Science and Engineering (CSE) graduate option.

Energy and Sustainability Engineering (EaSE) graduate certificate option.

The Medical Scholars Program permits highly qualified students to integrate the study of medicine with study for a graduate degree in a second discipline, including Nuclear, Plasma, and Radiological Engineering.

NPRE ILLINOIS Graduate Student Handbook (a supplement to the University of Illinois' Graduate College).

Read MS and PhD Theses from NPRE Illinois.

Nuclear Enterprise Management Option (Ph.D.).

The specialization in Nuclear Enterprise Management in the doctoral program is designed for students with a specific interest in leadership and management careers throughout the nuclear industry and leads to a Doctor of Philosophy with a major in Nuclear Engineering.

The nuclear engineering graduate program at Ohio State is designed to prepare students for successful careers in a variety of specialty areas associated with the application of radiation, radioactive materials and nuclear fission. Our program is housed within the Mechanical and Aerospace Engineering. Our research is further strengthened by the presence of Ohio State Nuclear Reactor Lab (OSU-NRL).

From developing a neutron detector capable of operating in high-radiation environments to improving the traditional probabilistic risk assessment approach, our students are impacting a variety of environmental and nuclear science areas. You can generate a bright future by pursuing nuclear engineering at Ohio State.

International graduates of this major are approved by the land Security for three (3) years of work permission in the United States after graduation.

Mechanical, Aerospace, and Nuclear Engineering Master of Science (M.S.).

Mechanical, Aerospace, and Nuclear Engineering Doctoral Program (Ph.D.).

Among the available degrees are the M.Eng., which is perceived to be practically oriented and includes a research project the M.S., which is considered scholarly or fundamental and must include a thesis and Ph.D.

The department offers graduate programs in mechanical engineering, aeronautical engineering, nuclear engineering, and engineering physics.

Students who successfully complete our graduate programs will be able to:.

Demonstrate advanced proficiency in the core program area.

Demonstrate preparedness for professional careers or further graduate studies.