This course covers mathematical techniques relevant to physics. The first part consists of elementary complex analysis, including complex functions and derivatives, Taylor and Laurent series, and contour integrations. The second part of the course involves methods of solving partial differential equations. The topics are boundary conditions, the wave, heat, and Poisson equations, the separation of variables, and special functions.
This course teaches 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, and electric and magnetic fields in matter.
This lab module complements the teaching of PHY103 Electromagnetism and PHY104 Modern Physics.
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 lab module complements the teaching of PHY101 Mechanics and PHY102 Thermal Physics.
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, non-inertial frames, rotating rigid bodies, and variational principles of mechanics.
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.
The goal of this course is to teach students, whose majors are natural sciences and engineering, the fundamental laws of physics so that they can describe the ideal world with mathematics and predict outcomes in other similar situations. This course leads the students to explore various mechanical and thermodynamical phenomena in terms of a few relatively simple laws.
A first course in quantum physics. Introduce quantum concepts and its application in solid state, atomic and molecular and nuclear physics
This course is an introduction to Astronomy, Astrophysics and Cosmology. The topics will cover astronomy, general knowledge of the celestial mechanics, light and telescopes, stellar classification, formation and evolution, planetary system, galaxy zoo, and basic concepts of the Universe and Cosmology
This is an undergrad thermodynamics based on statistical mechanics. Principles of statistical mechanics are expounded in elucidating concepts of photon, phonons and black-body radiations. Quantum fluid obeying the Fermi- Dirac and the Bose-Einstein statistics will be elaborated in detail. Topics on transport theory, diffusions on thermodynamic systems. Model beyond ideal gas will be discussed in great detail. The non-equilibrium theory on fluctuation and Brownian motion will be covered too.
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. Power series and special functions are also included. 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.
| This course is an introduction to astronomy and astrophysics. The topics will cover a brief history of astronomy, general knowledge of the celestial mechanics, light and telescopes, star and planetary system, galaxy zoo, and basic concepts of the Universe and Cosmology | |||||||||||||
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.
The goal of this course is to teach students, whose majors are natural sciences and engineering, the fundamental laws of physics so that they can describe the ideal world with mathematics and predict outcomes in other similar situations. This course leads the students to explore various mechanical and thermodynamical phenomena in terms of a few relatively simple laws.
PHY105 Physics Lab I supports the teaching of PHY101 Mechanics and PHY102 Thermal Physics. Selected experiments will be performed to validate the theoretical principles of mechanics and thermal physics.
elective course for physics students;to understand the nature of solid state physics
a compulsory course for physics student; Introduce students to quantum physics