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Nuclear Engineering and Engineering Physics
The Master of Science in Nuclear Engineering and Engineering Physics at the University of Wisconsin is a two year program designed for students seeking advanced knowledge in nuclear systems, energy technologies, and applied physics. The curriculum integrates theoretical foundations with practical applications, emphasizing problem solving, modeling, and experimental techniques in nuclear science and engineering. Students develop core competencies in nuclear physics, reactor design, radiation safety and research methodology, enabling them to analyze complex energy systems, optimize nuclear processes, and address challenges in energy production and technology. Through coursework, laboratory work, and applied research, learners acquire both the technical expertise and analytical skills needed to succeed in research, industry, or advanced academic study.
In addition to technical training, the program fosters research oriented thinking and professional development, encouraging students to engage with contemporary issues in nuclear energy, safety, and policy. Learners participate in independent and collaborative research projects, exploring topics such as reactor physics, radiation transport, and nuclear materials, while developing competencies in data analysis, scientific communication, and problem solving. With access to state of the art laboratory facilities and faculty mentorship, students gain practical experience alongside theoretical understanding. By the end of the program, graduates are well prepared for careers in nuclear engineering, energy consulting, regulatory agencies, or doctoral level research.
Key information
Key Facts
- Program Title: Nuclear Engineering and Engineering Physics
- Degree Type: Master of Science
- Duration: 2 years
- Mode of Study: Full-time, On Campus
- Application Deadline: 15 December 2025
- Location: University of Wisconsin, United States
- Field of Study: Physics
- Language of Instruction: English
Program Structure
Semester 1 – Foundations in Nuclear Engineering and Physics
• Principles of Nuclear Engineering
• Reactor Physics and Engineering Fundamentals
• Radiation Detection and Measurement
• Research Methods in Physics and Engineering
Semester 2 – Advanced Nuclear Systems and Applications
• Nuclear Reactor Design and Safety
• Radiation Protection and Regulatory Standards
• Computational Methods in Nuclear Engineering
• Graduate Research Project
Semester 3 – Specialized Topics in Engineering Physics
• Nuclear Materials and Fuel Cycles
• Radiation Transport and Analysis
• Advanced Laboratory Techniques
• Elective Modules in Energy Systems or Applied Physics
Semester 4 – Master’s Thesis and Applied Research
• Independent Thesis Research
• Nuclear Systems Analysis and Modeling
• Scientific Communication and Professional Presentation
• Capstone Research Project
Career Opportunities
Graduates of this program are prepared for a wide range of careers in nuclear engineering, energy production, research, and regulatory or consulting roles. Many pursue positions in nuclear power plants, government energy agencies, research laboratories, and engineering consulting firms, applying expertise in reactor operation, safety evaluation, and advanced nuclear systems. The program equips students to conduct technical analyses, perform safety assessments, develop energy solutions, and contribute to policy development related to nuclear technology. Graduates often collaborate with multidisciplinary teams to solve complex energy challenges and innovate sustainable nuclear applications. The strong research training also provides a solid foundation for those pursuing doctoral studies, academic research, or leadership positions in the nuclear and energy sectors.
Why Choose This Program
This program offers a rigorous and research intensive approach to nuclear engineering and applied physics, allowing students to develop advanced analytical training and high level technical skills within a structured two year curriculum. The coursework emphasizes problem solving, experimental design, computational modeling, and safety evaluation, preparing learners to address challenges in energy systems and nuclear technology. Students benefit from faculty mentorship, laboratory research, and applied projects that foster both theoretical understanding and practical expertise. Its focus on innovation, technical precision, and interdisciplinary collaboration ensures graduates are well equipped for professional, research, or academic success in nuclear engineering and engineering physics.
Contact Information
For further information, please contact the admissions office at:
Phone: +1 608-262-2433
Email: admissions@grad.wisc.edu
Address: 217 Bascom Hall, 500 Lincoln Drive, Madison, WI 53706, USA
