Nuclear Engineering
Nuclear engineering includes the design, development and operation of nuclear power systems; numeric simulation of nuclear systems; health physics and radiation protection; radiation imaging; radiation measurements; national security and non-proliferation; nondestructive examination of materials and structures using radiation techniques; use of radiation in medicine for treatment and diagnostics; and using radiation in food processing, industrial processing and manufacturing control.
About This Major
- College: Engineering
- Degree: Bachelor of Science in Nuclear Engineering
- Hours for the Degree: 127
- Minor: Yes
- Certificate Program: Yes
- Combined-Degree Program: Yes
- Website: www.nuceng.ufl.edu
Overview
A full complement of experimental facilities is available, including a 100 KW research and training reactor, a neutron activation analysis laboratory and a D-D neutron source for radiation studies. The department also has specialized nuclear instrumentation in the radiation detection laboratories located in the Nuclear Science Building and the Nuclear Field Building.
Students should concentrate several electives in one discipline to achieve solid familiarity in a minor field of study. These electives, chosen with an adviser, allow option area specialization in reactor engineering, reactor operations, radioisotopes and nuclear radiation technology, and radiation and biological systems.
Transfer Admission Requirements
It is the department’s policy to admit the best-qualified transfer applicants as demonstrated by academic achievement. Successful applicants must have earned:
- An overall 2.5 grade point average, based on the first 2 attempts in the eight preprofessional (critical tracking) courses;
- Minimum grades of C in Calculus 1 (MAC 2311), Calculus 2 (MAC 2312), Calculus 3 (MAC 2313), Differential Equations (MAP 2302), General Chemistry 1 (CHM 2045/2095 and CHM 2045L), and finally General Chemistry 2 (CHM 2046/2096) or Integrated Principles of Biology 1 (BSC 2010). Only the first two attempts in each course, including withdrawals, will be considered for admission to or retention in the department
- A cumulative minimum 2.0 GPA is required for all courses.
Department Requirements
- Minimum grades of C are required in ENC 3254, ENU 4001, ENU 4191, ENU 4192 and ENU 4905.
- The department encourages students to accept internships and opportunities to study abroad. It is highly recommended that students seek academic advising for appropriate registration planning.
- All nuclear engineering and nuclear radiological sciences majors must pass all required undergraduate department courses with an overall C average.
- All technical electives must be approved by a department adviser. At least three credits of technical electives must be ENU courses.
Educational Objectives
The Department of Nuclear and Radiological Engineering has established the following educational objectives for its undergraduate program. Graduates will
- Have successful careers in nuclear engineering or related disciplines;
- Pursue continuing education or advanced degrees;
- Communicate effectively and work collaboratively in nuclear engineering or related disciplines; and
- Use the knowledge and skills obtained in their undergraduate education to practice high ethical professional standards in nuclear engineering or related disciplines.
Mission
The department will provide quality education and conduct nationally recognized research in nuclear and radiological engineering to serve the needs of Florida and the nation.
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Critical Tracking
To graduate with this major, students must complete all university, college and major requirements.
Equivalent critical-tracking courses as determined by the State of Florida Common Course Prerequisites may be used for transfer students
Semester 1
- 2.0 UF GPA required for semesters 1-5
- 2.5 critical-tracking GPA for semesters 1-5
- Complete 1 of 8 critical-tracking courses with a minimum grade of C within two attempts: CHM 2045 or CHM 2095; CHM 2046 or CHM 2096 or BSC 2010; MAC 2311, MAC 2312, MAC 2313, MAP 2302, PHY 2048, PHY 2049
Semester 2
- Complete 1 additional critical-tracking course with a minimum grade of C within two attempts
Semester 3
- Complete 2 additional critical-tracking courses with minimum grades of C within two attempts
Semester 4
- Complete 2 additional critical-tracking courses with minimum grades of C within two attempts
Semester 5
- Complete all 8 critical-tracking courses with minimum grades of C in each course within two attempts
Recommended Semester Plan
To remain on track, students must complete the appropriate critical-tracking courses, which appear in bold. Students are required to complete HUM 2305 The Good Life (GE-H) in semester 1 or 2.
Semester 1 |
Credits |
CHM 2045 General Chemistry 1 (GE-P) or CHM 2095 Chemistry for Engineers 1 (GE-P) |
3 |
CHM 2045L General Chemistry 1 Laboratory (GE-P) |
1 |
ENU 1000 Introduction to Nuclear Engineering |
1 |
MAC 2311 Analytic Geometry and Calculus 1 (GE-M) |
4 |
Composition (GE-C, WR) |
3 |
Social and Behavioral Sciences (GE-S) |
3 |
Total |
15 |
Semester 2 |
Credits |
ENC 3254 Professional Communication for Engineers (GE-C) |
3 |
HUM 2305 What is the Good Life (GE-H) |
3 |
MAC 2312 Analytic Geometry and Calculus 2 (GE-M) |
4 |
PHY 2048 Physics with Calculus 1 (GE-P) |
3 |
PHY 2048L Physics with Calculus 1 Laboratory (GE-P) |
1 |
Total |
14 |
Semester 3 |
Credits |
ENU 4934 Fundamentals of Nuclear and Radiological Engineering |
1 |
MAC 2313 Analytic Geometry and Calculus 3 (GE-M) |
4 |
PHY 2049 Physics with Calculus 2 (GE-P) |
3 |
PHY 2049L Physics with Calculus 2 Laboratory (GE-P) |
1 |
STA 3032 Engineering Statistics |
3 |
Humanities (GE-H) |
3 |
Total |
15 |
Semester 4 |
Credits |
BSC 2010 Integrated Principles of Biology 1 or CHM 2046 General Chemistry 2 or CHM 2096 Chemistry for Engineers 2 |
3 |
COP 2271 Computer Programming for Engineers |
2 |
EGM 2511 Engineering Mechanics - Statics |
3 |
EML 3100 Thermodynamics |
3 |
MAP 2302 Elementary Differential Equations |
3 |
Total |
14 |
Semester 5 |
Credits |
EGM 3520 Mechanics of Materials |
3 |
EMA 3010 Materials |
3 |
Humanities (GE-H) or Social Science (GE-S) |
3 |
Total |
9 |
Semester 6 |
Credits |
EEL 3003 Elements of Electrical Engineering |
3 |
EGN 3353C Fluid Mechanics |
3 |
EGN 4034 Professional Ethics |
1 |
ENU 4001 Nuclear Engineering Analysis 1 |
4 |
ENU 4605 Radiation Interactions and Sources 1 |
4 |
Total |
15 |
Semester 7 |
Credits |
EML 4140 Heat Transfer |
3 |
ENU 4103 Reactor Analysis and Computation 1 - Statics |
4 |
ENU 4144 Nuclear Power Plant Reactor Systems 1 |
3 |
ENU 4800 Introduction to Nuclear Reactor Materials |
3 |
Social and Behavioral Sciences (GE-S) |
3 |
Total |
16 |
Semester 8 |
Credits |
ENU 4134 Reactor Thermal Hydraulics 2 |
4 |
ENU 4191 Elements of NRE Design |
1 |
ENU 4612 Radiation Detection and Instrumentation Systems |
3 |
ENU 4612L Radiation Detection and Instrumentation Systems Laboratory |
1 |
ENU 4630 Fundamental Aspects of Radiation Shielding |
3 |
Technical elective |
3 |
Total |
15 |
Semester 9 |
Credits |
ENU 4145 Risk Assessment for Radiation Systems |
3 |
ENU 4192 Nuclear and Radiological Engineering Design 1 |
3 |
ENU 4505L Nuclear and Radiological Engineering Laboratory 1 |
3 |
ENU 4641C Applied Radiation Protection |
2 |
Technical elective |
3 |
Total |
14 |
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ENU Technical Electives
The choice of engineering science and technical electives allows emphasis in nuclear power engineering, health physics, engineering physics, nuclear instrumentation, radioisotope applications, radiation imaging, medical treatment and scientific computing.
Of the six credits of technical electives required, three credits must be ENU and three credits may be any engineering, mathematics or science course 3000-level or above.
ENU 4905 Individual Work |
3 max |
ENU 4949 Internship |
3 max |
ENU 4930 Special Topics |
3 max |
ENU 5626 Radiation Biology |
3 |
ENU 5658 Image Analysis with Medical Physics Applications |
3 |
ENV 4212 Nuclear Power Radioactive Waste Technology |
3 |
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