- UNM Catalog 2022-2023
- >Colleges
- >School of Engineering
- >Nuclear Engineering
- >Undergraduate Program
Faculty Director of Undergraduate Advisement
Dr. Neven Ali
Undergraduate students in the Nuclear Engineering program may seek admission to a Master of Science (M.S.) engineering program or the Master of Engineering (M.Eng.) in Civil Engineering under the Shared-Credit Undergraduate/Graduate Degrees Program. See the School of Engineering section of this Catalog for specific admission information and requirements.
The Bachelor of Science in Nuclear Engineering (B.S.N.E.) degree program in the Department of Nuclear Engineering provides an outstanding education that prepares students to be productive and responsible members of society, with the skills and knowledge to be successful in their professional careers or post-graduate studies. This is accomplished by engaging students in a variety of academic, research and service activities, and fostering a learning environment that is supportive for a body of students that is diverse in terms of age, gender, ethnicity, and prior educational background.
Nuclear engineering is an exciting, rapidly-evolving field that requires engineers with an understanding of physical processes of nuclear energy and an ability to apply concepts in new and creative ways. Nuclear engineers are primarily concerned with the control, monitoring and use of energy released in nuclear processes. Some nuclear engineers work on the design and safety aspects of environmentally sound, passively safe, proliferation resistant nuclear fission reactors. Still others are looking to future energy solutions through development and implementation of nuclear fusion systems. Others are helping in the exploration and utilization of outer space by developing long term, reliable nuclear energy sources. With the renewed concern in environmental science, nuclear engineers are working on safe disposal concepts for radioactive waste and on methods for reduction of radiation releases from industrial facilities. They also work in developing a wide variety of applications for radioisotopes such as the treatment and diagnosis of diseases; food preservation, manufacturing development, processing and quality control; and biological and mechanical process tracers. For each of these fields there are numerous opportunities for nuclear engineers in basic research, applications, operations and training. Moreover, nuclear engineers with advanced computational skills are in strong demand in the national security, medical physics and radiation processing fields.
The mission of nuclear engineering education is to give the student an excellent understanding of nuclear processes and fundamentals and provide the physical and engineering principles that lead to applications of the basic processes. The goal of the program is to provide rigorous Nuclear Engineering education and training at the Bachelor of Science level. Our undergraduate program is built on an academically strong, research-oriented faculty and a sound graduate program in Nuclear Engineering. This strong foundation is enhanced by the nearby presence of three national laboratories dealing in Nuclear Engineering research (Los Alamos National Laboratory, Sandia National Laboratories and Air Force Research Laboratory).
The educational objectives for graduates of the Nuclear Engineering undergraduate program are:
The most up-to-date version of the educational objectives is available at the department Web site.
The program emphasizes the broad knowledge and intellectual values of a liberal arts education and the fundamentals of engineering science at the lower levels and engineering design and computational tools at the upper levels. The course of study in nuclear engineering gives the student broad training in the fundamentals of mathematics, physics, chemistry and engineering, followed by professional specialty course work involving radiation interaction with matter, radiation transport, radiation detection and protection, nuclear reactor theory and safety, thermalhydraulics and nuclear systems design. Students also select technical electives that allow them to explore in-depth areas of interest in nuclear engineering. The graduate nuclear engineer finds a wide variety of career opportunities or is well prepared to pursue advanced graduate studies.
The goal is to produce highly motivated Nuclear Engineers who have strong verbal and written communication skills and excellent engineering training and knowledge. Graduates have an ability to design, conduct and analyze experiments and experimental data. They have an understanding of professional and ethical responsibility and of the background to understand societal impact and risks/benefits of engineering solutions. Our program provides an academic experience focusing on technically current material, with opportunities for interested undergraduate students to participate in nuclear engineering research projects.
The Department seeks to graduate students capable of making decisions, analyzing alternatives and creating integrated designs that are solutions to engineering problems with economic and political constraints. To help achieve this, design is integrated into courses, from the sophomore through senior year. The philosophy for design is to expose the student to a variety of design topics representative of the types of assignments they may expect in an industrial setting. The faculty feel they should be given exposure to modern computational and design tools and that they should have experience working in groups as well as individually.
Nuclear Engineering students begin their program design experience during their sophomore year with an introduction to open-ended problems and design concepts. This experience continues throughout the program with open-ended work a part of each semester. As students move through the program, the breadth and depth of the design experience increases from a few examples in the introductory courses to a wide variety of projects associated with hardware, systems, and experiments. In their junior year, students are exposed to experimental design and participate in a series of design problems applied to nuclear and radiological systems. Economic issues of design are identified early in the sequence and are integrated throughout our upper level courses. During the senior year, students are exposed to more detailed facets of the design process and design integration. This work culminates with a capstone nuclear design course taken during the second semester of the senior year. This course involves a complete system design, integrating technical, economic, safety and environmental issues at senior year depth. Here, teamwork and careful analysis of trade-offs are essential components for a successful design.
Minimum requirements for admission to the School of Engineering for pre-major and major study in the Nuclear Engineering department are described under “Admission to the School of Engineering” in the School of Engineering section of this Catalog. Additional requirements for major status admission to Nuclear Engineering are as follows:
Students must apply for major study in Nuclear Engineering prior to the completion of third-year courses listed in the B.S.N.E. curriculum. All applicants must have completed ENGL 1110 or the equivalent before admission to major study.
Students admitted or readmitted to the Nuclear Engineering degree program may not apply a course toward the Bachelor of Science in Nuclear Engineering degree if the highest grade earned in the course is a "D+" or less, regardless of where that grade was earned.
The Bachelor of Science in Nuclear Engineering program accredited by the Engineering Accreditation Commission of ABET.
Credit hours required for graduation: 120.
Refer to the Undergraduate Program section of this Catalog for information on courses that meet General Education curriculum and U.S. and Global Diversity and Inclusion requirements. These courses may be taken whenever convenient.
Courses that are required for major study must be completed with a grade of "C-" or better. Courses used to fulfill the UNM General Education curriculum or prerequisites outside of the major require a grade of "C" or better.
Credit Hours |
||
First Year | First Semester | |
NE 101 | Introduction to Nuclear Engineering | 1 |
CHEM 1215 | General Chemistry I for STEM Majors | 3 |
CHEM 1215L | General Chemistry I for STEM Majors Laboratory | 1 |
ENGL 1120 | Composition II | 3 |
MATH 1512 | Calculus I | 4 |
General Education: Humanities | 3 | |
Subtotal | 15 | |
Second Semester | ||
CHEM 1225 | General Chemistry II for STEM Majors | 3 |
CHEM 1225L | General Chemistry II for STEM Majors Laboratory | 1 |
MATH 1522 | Calculus II | 4 |
PHYS 1310 | Calculus-Based Physics I | 3 |
General Education: Arts and Design | 3 | |
General Education: Communication | 3 | |
Subtotal | 17 | |
First Year Total | 32 | |
Second Year | First Semester | |
NE 230 | Principles of Radiation Protection | 3 |
ENG 130L | Introduction to Engineering Computing | 3 |
ECON 2110 | Macroeconomic Principles | 3 |
MATH 2530 | Calculus III | 4 |
PHYS 1320 | Calculus-Based Physics II | 3 |
Subtotal | 16 | |
Second Semester | ||
NE 213 | Laboratory Electronics for Nuclear Engineers | 3 |
NE 231 | Principles of Nuclear Engineering | 3 |
NE 314 | Thermodynamics and Nuclear Systems | 3 |
NE 371 | Nuclear Materials Engineering | 3 |
MATH **316 | Applied Ordinary Differential Equations | 3 |
Subtotal | 15 | |
Second Year Total | 31 | |
Third Year | First Semester | |
NE 311 | Introduction to Transport Phenomena | 3 |
NE 315 | Nuclear Engineering Analysis and Calculations | 3 |
NE **323L | Radiation Detection and Measurement | 4 |
STAT **345 | Elements of Mathematical Statistics and Probability Theory | 3 |
General Education: Second Language | 3 | |
Subtotal | 16 | |
Second Semester | ||
NE 312 | Unit Operations | 3 |
NE 313L | Introduction to Laboratory Techniques for Nuclear Engineering | 4 |
NE *330 | Nuclear Engineering Science | 3 |
NE 410 | Nuclear Reactor Theory | 3 |
Technical Elective | 3 | |
Subtotal | 16 | |
Third Year Total | 32 | |
Fourth Year |
First Semester | |
NE 462 | Monte Carlo Techniques for Nuclear Systems | 3 |
NE 464 | Thermal-Hydraulics of Nuclear Systems | 3 |
NE *497L | Nuclear Engineering Computational Methods | 3 |
Nuclear Engineering Technical Elective | 3 | |
Subtotal | 12 | |
Second Semester | ||
NE *413L | Nuclear Engineering Laboratory I | 3 |
NE 452 | Senior Seminar | 1 |
NE 470 | Nuclear Fuel Cycle and Materials | 3 |
NE 498L | Nuclear Engineering Design | 3 |
Nuclear Engineering Technical Elective | 3 | |
Subtotal | 13 | |
Fourth Year Total | 25 | |
Total | 120 |
Notes: The Technical Elective and Nuclear Engineering Technical Electives are chosen from a list of approved upper-division courses with the approval of the student's advisor. Students are encouraged to take the Fundamentals of Engineering (FE) Examination during their senior year as the first formal step towards professional registration.
The nuclear engineering laboratories are equipped with an AGN-201M nuclear training reactor; a hot-cell facility with remote manipulators; a graphite pile; several solid state detectors for alpha, beta and gamma radiation; computer based data acquisition, analysis and control systems; and supporting radiation measurements systems. In addition to the well-equipped laboratories on campus, the advanced reactors and radiation equipment of Sandia National Laboratories, Lovelace Respiratory Research Institute, Los Alamos National Laboratory and the Air Force Research Laboratory are utilized for instruction and research.
Computers provide the basic computational tool for today’s modern engineer. The department maintains a computer pod equipped with PC computers. Additional computers are available in the many University of New Mexico computer pods maintained by the University of New Mexico’s Information Technology Services. Freshman engineering students are introduced to the many computer facilities and programming. Numerical analysis is an important part of each year’s instruction in engineering, and by the senior year students make extensive use of sophisticated neutron transport and thermal hydraulics production codes. In addition to these technical software packages, students also gain experience with mathematical packages such as spreadsheets and symbolic manipulation software.
Upperclassmen in the Department of Nuclear Engineering are urged to enroll in the departmental honors program. Nuclear Engineering students may graduate with Baccalaureate Honors, Departmental Honors, or both. Information is available from departmental advisors.
Nuclear engineering students may participate in the cooperative education program. Excellent opportunities exist throughout the country for undergraduate students. For further information, refer to "Section III: Cooperative Education Program" in the School of Engineering - Other Courses of Instruction section of this Catalog, or contact the Director of Career Services.
NE 101. Introduction to Nuclear Engineering. (1)
NE 213. Laboratory Electronics for Nuclear, Chemical and Biological Engineers. (3)
NE 230. Principles of Radiation Protection. (3)
NE 231. Principles of Nuclear Engineering. (3)
NE 311. Introduction to Transport Phenomena. (3)
NE 312. Unit Operations. (3)
NE 313L. Introduction to Laboratory Techniques for Nuclear Engineering. (4)
NE 314. Thermodynamics and Nuclear Systems. (3)
NE 315. Nuclear Engineering Analysis and Calculations. (3)
NE **323L. Radiation Detection and Measurement. (4)
NE *330. Nuclear Engineering Science. (3)
NE 371. Nuclear Materials Engineering. (3)
NE 410 / 510. Nuclear Reactor Theory. (3)
NE *413L. Nuclear Engineering Laboratory I. (3)
NE 439 / 539. Radioactive Waste Management. (3)
NE 449. Seminar in Hazardous Waste Management. (1, no limit Δ)
NE 452. Senior Seminar. (1)
NE 462 / 562. Monte Carlo Techniques for Nuclear Systems. (3)
NE 464 / 564. Thermal-Hydraulics of Nuclear Systems. (3)
NE 468 / 568. Introduction to Space Nuclear Power. (3)
NE 470. Nuclear Fuel Cycle and Materials. (3)
NE *485. Fusion Technology. (3)
NE 491–492. Undergraduate Problems. (1-3 to a maximum of 6 Δ, 1-3 to a maximum of 6 Δ)
NE 495–496. Nuclear Engineering Honors Problems I and II. (1-6 to a maximum of 6 Δ, 1-6 to a maximum of 6 Δ)
NE *497L. Nuclear Engineering Computational Methods. (3)
NE 498L. Nuclear Engineering Design. (3)
NE 499. Selected Topics. (1-3, no limit Δ)
NE 501. Nuclear Engineering Seminar. (1, no limit Δ)
NE 502. Nuclear Engineering Research Methods Seminar. (1, no limit Δ)
NE 508. Nuclear Engineering Research Seminar. (2, may be repeated nine times Δ)
NE 510 / 410. Nuclear Reactor Theory. (3)
NE 511. Advanced Nuclear Reactor Theory. (3)
NE 513L. Graduate Nuclear Engineering Laboratory. (1-4 to a maximum of 4 Δ)
NE 515. Special Topics. (1-3, no limit Δ)
NE 520. Radiation Interactions and Transport. (3)
NE 523L. Environmental Measurements Laboratory. (1-4 to a maximum of 4 Δ)
NE 524. Interaction of Radiation with Matter. (3)
NE 525. Methods of Analysis in Chemical, Biological, and Nuclear Engineering. (3)
NE 527. Radiation Biology for Engineers and Scientists. (3)
NE 528. External Radiation Dosimetry. (3)
NE 529. Internal Radiation Dosimetry. (3)
NE 539 / 439. Radioactive Waste Management. (3)
NE 551–552. Problems. (1-3, no limit Δ; 1-3)
NE 562 / 462. Monte Carlo Techniques for Nuclear Systems. (3)
NE 564 / 464. Thermal-Hydraulics of Nuclear Systems. (3)
NE 568 / 468. Introduction to Space Nuclear Power. (3)
NE 571. Radiation Damage in Materials. (3)
NE 591. Practicum. (3 or 6 to a maximum of 6 Δ)
NE 599. Master's Thesis. (1-6, no limit Δ)
NE 610. Advanced Methods in Radiation Transport. (3)
NE 699. Dissertation. (3-12, no limit Δ)
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