In this course, you will calculate electric fields, apply Gauss's law, and analyze electric potential, capacitance, current, and resistance using various methods, with a focus on fundamental principles and practical applications.

In this course, you will study advanced topics in electromagnetism, including Ampere's law, Faraday's law of induction, magnetic fields, electromagnetic waves, and the properties of materials in electric and magnetic fields, with a focus on deeper problem-solving techniques and practical applications.

In this course, you will explore the foundations of quantum mechanics, including wave-particle duality, the Schrödinger equation, quantum states, operators, and the principles of superposition and uncertainty, with a focus on solving problems in atomic and molecular systems.

In this course, you will study advanced quantum mechanics topics, including perturbation theory, angular momentum, spin, identical particles, and applications to atomic, molecular, and solid-state systems, with an emphasis on problem-solving and real-world applications.

In this course, you will explore the fundamentals of nuclear physics, including nuclear structure, radioactive decay, nuclear reactions, binding energy, and applications such as nuclear fission, fusion, and medical imaging, with a focus on theoretical and practical understanding.

In this course, you will study the fundamental building blocks of matter, including quarks, leptons, and bosons, as well as their interactions through the strong, weak, and electromagnetic forces. Topics include the Standard Model, particle decays, symmetries, and the principles of high-energy physics.

In this course, you will study the basic principles of thermodynamics, including the first and second laws, energy conservation, heat transfer, work, internal energy, and entropy, with a focus on understanding thermodynamic systems and their applications in everyday physical processes.

In this course, you will explore the principles of thermodynamics, including the laws of thermodynamics, heat, work, entropy, and thermodynamic processes, with applications to engines, refrigerators, and real-world physical systems.

In this course, you will explore the fundamental concepts of solid-state physics, including crystal structures, lattice dynamics, electronic properties of solids, band theory, and semiconductors, with applications in materials science, electronics, and nanotechnology.

In this course, you will study the fundamentals of plasma physics, including the properties of ionized gases, plasma behavior, electromagnetic fields, plasma oscillations, and confinement techniques, with applications in fusion energy, space physics, and industrial processes.

In this course, you will study advanced mathematical methods, including Legendre polynomials, Fourier series, and the Frobenius method for solving differential equations. These techniques will be applied to problems in classical mechanics, electromagnetism, and other areas of theoretical physics.

In this course, you will learn the basics of electronics, including semiconductor theory, diodes, transistors, amplifiers, and digital circuits. The course covers circuit analysis, signal processing, and the design and application of electronic components in various systems.

In this course, you will delve into advanced topics in modern physics, including special relativity, quantum mechanics, the theory of relativity, wave-particle duality, and the concepts of spacetime. The course will also cover applications in particle physics, cosmology, and modern technological advancements.

Explores the basics of motion, forces, energy, and waves. Key topics include kinematics, Newton’s laws, work, momentum, rotational motion, and oscillations. This course builds a strong foundation in classical physics for first-year students.

Focuses on electricity, magnetism, and thermodynamics. Topics include electric fields, circuits, magnetism, electromagnetic waves, and the principles of heat and thermodynamics. This course equips first-year students with a deeper understanding of physical phenomena. 

In this course, you will learn the basics of medical physics, including radiation therapy, diagnostic imaging, dosimetry, and radiation safety, with applications in X-rays, MRIs, and CT scans.

In this course, you will study the principles of medical imaging, focusing on techniques like X-ray, CT scans, and MRI, including their physics, image formation, and clinical applications.

In this course, you will learn image enhancement, restoration, filtering, segmentation, and frequency domain analysis for practical applications.

In this course, you will study the principles of medical imaging, focusing on techniques like X-ray, CT scans, and MRI, including their physics, image formation, and clinical applications.

In this course, you will learn about radiation safety, protection, and dosimetry, focusing on the principles and practices used to protect individuals and the environment from harmful effects of radiation in medical, industrial, and research settings.

In this course, you will study the fundamentals of radiation, including types of radiation, radioactive decay, detection methods, and radiation interactions with matter, with applications in medicine, industry, and nuclear energy.

In this course, you will explore the effects of radiation on biological systems, including cellular damage, radiation therapy, radiobiological principles, and the mechanisms of radiation-induced mutations and cancer.