Theoretical Physics 1 focuses on the foundational principles of physics that govern the natural world. Topics typically include classical mechanics, thermodynamics, waves, optics, and electricity.
Classical Mechanics explores the motion of objects, forces, and energy. It covers Newton's laws of motion, work-energy theorems, and the concepts of momentum, rotational dynamics, and conservation laws. Students learn to apply these principles to real-world scenarios, such as projectile motion and harmonic oscillators.
Thermodynamics introduces the laws governing heat, energy transfer, and the behavior of gases. Key concepts include temperature, pressure, internal energy, entropy, and the first and second laws of thermodynamics, which describe the flow and conservation of energy.
Waves and Vibrations cover the propagation of mechanical and electromagnetic waves, including sound waves, light waves, and wave phenomena such as interference, diffraction, and resonance. This section also explores the mathematical description of wave motion.
The theoretical part of the course emphasizes mathematical modeling, problem-solving, and applying these concepts to both everyday situations and more complex physical systems. Students also engage in laboratory work to experimentally verify the theoretical predictions.
Classical Mechanics explores the motion of objects, forces, and energy. It covers Newton's laws of motion, work-energy theorems, and the concepts of momentum, rotational dynamics, and conservation laws. Students learn to apply these principles to real-world scenarios, such as projectile motion and harmonic oscillators.
Thermodynamics introduces the laws governing heat, energy transfer, and the behavior of gases. Key concepts include temperature, pressure, internal energy, entropy, and the first and second laws of thermodynamics, which describe the flow and conservation of energy.
Waves and Vibrations cover the propagation of mechanical and electromagnetic waves, including sound waves, light waves, and wave phenomena such as interference, diffraction, and resonance. This section also explores the mathematical description of wave motion.
The theoretical part of the course emphasizes mathematical modeling, problem-solving, and applying these concepts to both everyday situations and more complex physical systems. Students also engage in laboratory work to experimentally verify the theoretical predictions.
- Teacher: Mr. Mohammed Jad