A first course in quantum physics consists of two parts. The first part is on the failure 0f classical physics and birth of quantum physics. The second part is on the introduction of quantum mechanics
A first course in thermal physics consists of two parts. The first part is on thermodynamics and the second part on statistical mechanics
This is a guided design lab module to stimulate students' creativity in designing experiments and/or instruments for the investigation of physics phenomena. At the end of the module, students will undergo a brief viva to explain their design steps taken to investigate their physics problem.
This course introduces students to basics techniques in solving linear ordinary differential equations (ODE). Topics covered are Homogeneous and Inhomogeneous differential (first and second order) equations, Various method employed to solve these ODEs mentioned and connection to physical problems are also depicted.. Idea of damping and driving forces on to the system dynamics will also be introduced. Systems of first order linear equations related to dynamical equations will be introduced.
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This course teaches intermediate to advanced methods of classical mechanics. Topics include a brief review of Newtonian mechanics, N-body problems, non-inertial frames, rotating rigid bodies, and variational principles of mechanics. |
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This course teaches the electrodynamics using vectors and differential and integral calculus. Topics include electrostatic and magnetostatic fields, electric scalar and magnetic vector potentials, multipole expansion, electromagnetic induction, Maxwell’s equations and electromagnetic wave, Poisson and Laplace’s equations, electric and magnetic fields in matter. |
This course teaches quantum mechanics at the 2nd year undergraduate level. Topics include Hilbert space and the bra-ket notation, two-state systems, the harmonic oscillator, angular momentum and hydrogen-like atoms, and introduction to entanglement.
This course teaches the fundamentals of mechanics. Topics include kinematics, Newton’s laws of motion, conservation of energy and momentum, rigid body rotation, gravitation, waves, oscillations and an introduction to special relativity.
This course will cover the historical development of astronomy, starting from the development of various models of our Universe, the discovery of gravity, the Space Race, the different space missions and their implications, all the way up to the latest advancements in the field.
This course teaches the fundamentals of mechanics. Topics include kinematics, Newton’s laws of motion, conservation of energy and momentum, rigid body rotation, gravitation, waves, oscillations and an introduction to special relativity.
This course teaches quantum mechanics at the 2nd year undergraduate level. Topics include Hilbert space and the bra-ket notation, two-state systems, the harmonic oscillator, angular momentum and hydrogen-like atoms, and introduction to entanglement.
This is an guided design lab module to stimulate student's creativity of designing experiments and/or instruments for investigation of physics phenomena. At the end of the module, students will undergo a brief viva to explain their design steps taken to investigate their physics problem.
This course teaches intermediate to advanced methods of classical mechanics. Topics include a brief review of Newtonian mechanics, N-body problems, non-inertial frames, rotating rigid bodies, and variational principles of mechanics.
This course is an introduction to astronomy and astrophysics.
The topics will cover a brief history of astronomy, general knowledge of celestial mechanics, spectroscopy and telescopes, star and planetary system, Galaxy Zoo, and basic concepts of the Universe and Cosmology.
No prior knowledge of astronomy is required, and relevant basic physics is introduced along the way.