The discipline of Engineering Physics is an interdisciplinary field that combines the principles of physics and engineering to develop technical solutions to practical problems. This major focuses on the application of physical theories to the design and analysis of engineering systems, and includes a wide range of topics including mechanics, electricity and magnetism, thermodynamics, and materials. Engineering physicists are able to work in various industries thanks to their advanced analytical and technical skills.

Fields of study of engineering physics:

• Mechanics: The study of motion and forces acting on objects, and their application in the design of machines and structures.
• Electricity and Magnetism: The study of electrical and magnetic phenomena and their application in the design of electrical circuits and electronic systems.
• Thermodynamics: the study of the transfer of heat and energy, and its applications in the design of power plants and cooling and heating systems.
• Materials Physics: The study of the properties of materials and the development of new materials to improve the performance of engineering products.
• Photonics and Optics: The study of light and its applications in the design of optical devices such as lasers and fiber optics.
• Quantum Mechanics: Applying the principles of quantum mechanics to the design and development of nano systems and advanced technologies.

Objectives of studying engineering physics:

• Developing new technologies: Using a deep understanding of physical principles to develop new technologies and products.
• Engineering Systems Analysis: Providing accurate and reliable analysis of engineering systems to ensure their efficiency and effectiveness.
• Practical problem solving: Apply physics knowledge to solve complex engineering problems and improve industrial processes.
• Integration between physics and engineering: achieving effective integration between physical theories and engineering applications.

Job opportunities for engineering physics graduates:

• Research and Development: Work in research and development laboratories to design and improve technological products.
• Technical industries: Work in industries such as electronics, energy, aviation, and communications.
• Industrial Engineering: Improving industrial processes and developing production systems.
• Academic education: teaching at universities and educational institutes and providing research.
• Engineering consulting: Providing consultations in various fields of engineering to develop innovative technical projects.

Practical applications of engineering physics:

• Robotics Design: Applying the principles of mechanics and electricity to design intelligent robots for use in industries and medicine.
• Nanotechnology: Using the principles of quantum mechanics and materials to develop devices and technologies at the nanoscale.
• Renewable energy: Design and improve solar and wind energy systems to ensure their efficiency and sustainability.
• Medical Devices: Developing advanced medical technologies and devices to improve healthcare and diagnose diseases.

The Engineering Physics major provides a unique blend of theoretical knowledge and practical applications, making it an exciting field with multiple opportunities to contribute to technological and industrial progress.