Engineering Physics
The Bachelor of Science in Engineering Physics at University of Stanford combines rigorous training in physics with advanced engineering principles, providing students with a multidisciplinary foundation in both theoretical and applied sciences. In the first year, students gain fundamental knowledge in classical mechanics, electromagnetism, calculus, and introductory engineering concepts, which cultivate analytical thinking, quantitative proficiency, problem-solving skills, and research methodology. Through lectures, laboratory exercises, and collaborative projects, students acquire hands-on experience in experimental design, computational modeling, and applied physics, laying the groundwork for advanced study in engineering and physical sciences.
As students advance, the curriculum emphasizes modern physics, materials science, electronics, thermodynamics, and applied engineering projects, alongside independent research opportunities. Honors-level coursework and seminars refine students’ critical thinking, technical skills, research methodology, and applied problem-solving abilities. The program encourages students to design experiments, develop engineering solutions, and analyze complex physical systems. By graduation, students are prepared for careers in engineering, research, technology, applied physics, or advanced graduate study in physics, engineering, or interdisciplinary sciences.
Key information
Key Facts
- Program Title: Engineering Physics
- Degree Type: Bachelor of Science
- Duration: 4 years
- Mode of Study: Full-time, On Campus
- Application Deadline: 05 January 2026
- Location: Stanford University, United States
- Field of Study: Physics
- Language of Instruction: English
Program Structure
Year 1 – Foundations in Engineering Physics
• Introduction to Classical Mechanics and Electromagnetism
• Calculus and Linear Algebra
• General Physics Laboratory
• Fundamentals of Engineering Principles
• Writing and Critical Thinking in Scientific Research
Year 2 – Core Physics and Engineering Applications
• Thermodynamics and Statistical Mechanics
• Quantum Mechanics I
• Electronics and Materials Science
• Seminar: Research Methods in Physics and Engineering
• Electives in Computational Methods or Applied Sciences
Year 3 – Advanced Applications
• Quantum Mechanics II
• Engineering Design Projects
• Applied Laboratory Techniques
• Independent Research Projects
• Electives in Specialized Physics and Engineering Topics
Year 4 – Capstone and Honors Project
• Senior Thesis or Independent Research Project
• Advanced Seminar in Engineering Physics
• Applied Research and Computational Modeling
• Presentation and Academic Portfolio Development
• Specialized Electives in Theoretical or Applied Engineering
Career Opportunities
Graduates of this program are prepared for careers in engineering, applied physics, research, technology, aerospace, and advanced scientific industries. The curriculum develops analytical reasoning, research proficiency, technical expertise, and problem-solving abilities, enabling students to pursue roles as research scientists, engineers, technology developers, data analysts, or educators. Hands-on experience through laboratory work, computational modeling, and applied projects ensures that graduates can design innovative solutions, conduct experiments, and contribute to scientific and technological advancements. Additionally, the program provides a strong foundation for graduate study in physics, engineering, materials science, or interdisciplinary applied sciences, equipping students to lead in both research and industry.
Why Choose This Program
This program is ideal for students who wish to combine advanced physics knowledge with engineering applications through a rigorous, research-focused curriculum. Its structure emphasizes critical thinking, analytical proficiency, research methodology, and applied problem-solving, providing students with both theoretical understanding and practical experience. Through seminars, independent research, laboratory work, and engineering projects, learners develop the skills to analyze complex systems, implement innovative solutions, and conduct impactful research in both physics and engineering contexts. Graduates leave with the expertise, confidence, and professional readiness to pursue careers in applied physics, engineering, technology, research, or advanced graduate study in interdisciplinary sciences.
Contact Information
For further information, please contact the admissions office at:
Phone: +1 650 000 0000
Email: admissions@standord.edu
Address: University of Standord, 450 Serra Mall, Stanford, CA 94305, United States
