You will learn how to program quantum computers with all the necessary background information.
The first course on non-relativistic quantum formalism.
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 PHY103 Electromagnetism and PHY104 Modern Physics
This lab module complements the teaching of PHY101 Mechanics and PHY102 Thermal Physics
This course introduces students to parametric equations and polar coordinates, geometry of space, vector functions, application of partial derivatives, maxima and minima, multiple integrals, iterated integrals, applications of multiple integrals, line and surface integrals, Green’s Theorem, Gauss’s Divergence Theorem and Stokes’s Theorem.
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 solving partial differential equations. The topics are boundary conditions, the wave, heat, and Poisson equations, separation of variables, and special functions.
This is a first course in quantum mechanics. It discusses the failure of classical physics and the birth of modern physics. We also solve various one dimensional potential problems and three dimensional hydrogen problem.We also include introductory atomic and molecular physics`, s`olid state physics and some detail on nuclear physics
This course teaches the concepts of machine learning in physics, linear Algebra, probability, probability distribution, optimization methods, learning algorithms, loss function, Boltzmann machine, Ising model, quantum states. Topics include supervised learning and unsupervised. Simple model computation lab from real systems would be compared and discussed to help students develop an intuitive understanding of the subject.
Undergraduate Research I is a major elective to provide outstanding undergraduates an opportunity to pursue independent research under the supervision of researchers and professors. Students will engage actively in research, discussions, intellectual communications and other creative activities. By complementing the conventional classroom learning, it places students at the frontiers of scientific research.
The aim of this course is to introduce the importance of semiconductor widely. Currently, the war of microchips rises as tehcnologies, such as
gadgets, mobile phones, sensors, rfid, and etc. are increasing towards the modern world. In this course, together we explore the applications
of semiconductors, how can the small chip magically becoming one of the most important thing in the world, and why semiconductors are
important through out our daily lives.