None

None

None

None

None

None

introduce the overview of climatology basics, including a discussion on climatology versus meteorology and an introduction to the atmosphere. then introduce more advanced concepts, such as microscale transfer of energy, matter, and momentum; the global water balance; global atmospheric circulation; climatic classification with special emphasis on the regional differences within the same climate types; and much more.

None

None

The atmospheric air and water on the Earth surface are our familiar fluids due to their flows makeing much effects on our dailylife at all times.Fluid Mechanics is a scientific subject evidently exploring the law of the macroscopical motion of this kind of Newtonian fluid. The term fluid includes both gases and liquids. The methods and techniques in fluid mechanics are widely applied to deal with many problems in biofluid, environmental fluid, geophysical fluid and so on. This course is to introduce the terminology and techniques required in the study of the flows of fluids. The goal is to help students apply the universal physical principles such as conservation of mass, momentum and energy to understand the fundamental equations which govern most of the flow of fluids.

"Electrodynamics" is an fundametally important theory course for undergraduate students majored in physics. The course systematically teachs the basic rules of electromagnetism, properties of electromagnetic field and its interaction with charged matter. The course also includes an introduction to special relativity. The major contents of the course include: The energy momentum tensor of electromagnetic wave, Maxwell equation and Lorentz equation; Variable separable method, mirror-image method in solving static electric and magnetic field, Green`s function method; The concept of gauge transformation and electromagnetic gauge invariance and their physical meaning; Propagation and radiation of electromagnetic field; The interaction between a moving electrically charged particle and elctromagnetic field; Special relativity, it historical background and experimnetal facts, fundamental priciples of special relativity and Lorent transformation, space-time theory of special relativity; The propagation, dispersion and dissipation of electromagnetic field travelling in the medium.

The purpose of this course is to guide students into the fascinating microscopic scales world of quantum physics. We will learn the basic physical principles and basic mathematical tools of non-relativistic quantum mechanics, and this simple basic theory is applied to a variety of interesting physical phenomena. The course content includes: kets and bras from Dirac, Schrodinger equation of motion, the Heisenberg equation of motion, mechanical observables and representation transformation, collapse of measurement and uncertainty principle. Here, we also will learn to solve one-dimensional potential well, harmonic oscillator, hydrogen atom and two-level system, time-independent perturbation theory, variational method, time-dependent perturbation theory.

"This course is set for the students with physics major of the School of Physics, but also can be reference for students with other physics class of majors. On the basis of Calculus (calculus of one variable and several variables, power series and Fourier series, ordinary differential equations, vector analysis, linear algebra), this course focuses on the basic properties of analytic functions and its applications, including the Γ function, integral transform and δ function, and on preparing for the relevant physics theory courses. "

With analytic mechanics, many topics of kinematics and dynamics of mechanical systems are introduced. The course Mainly includes: constraints of motion, generalized coordinates, degrees of freedom, principle of virtual work. For fixed-point motion of rigid body, the Euler angles and Euler Equations of kinematics are introduced; and more, parallel planar motion, fixed-axis motion and general motion of rigid bodies are also presented. The equations of motion in non-inertial reference frame and their application are discussed. Lagrangian and Lagrange equations are introduced, and as their applications, central force motions and small oscillations for multi-degrees of freedom mechanical systems are discussed. Center of mass and reference frame of center of mass for many particle systems are presented. Dynamical laws of the particle groups are discussed, and the laws are used to solve mechanical problems. For rigid body dynamics, the inertia tensor and Euler dynamical equation are introduced. From the Lagrange equations of motion, we deduce the canonical equations of motions, the conservations of some mechanical quantities of mechanical systems are discussed. Finally, we discuss the Poisson brackets and Hamilton`s principle and Hamilton-Jacobi equation.

This course is to let the students study the basic thoretical knowledge, basic experimental methods and techniques of physics by making a series of experiments, to improve their capability of carrying out physics exeriment.

Understand principle and theory of Data Structures and Algorithms, able to design and implement fundamental data structures and algorithms. Covers programming, data structures, algorithms. Topics include the organization and implementation of fundamental data structures such as list, binary tree, tree and forest, and graph; sorting and searching; data abstraction and problem solving.

This two-term general physics course includes mechanics, heat, electromagnetics, optics and modern physics. We have stressed those basic concepts and principles that are common to both classical and quantum physics. To deepen understanding of physics knowledge, we have included numerous applications of physics in engineer, technology, biomedical science, and familiar everyday phenomena. We encourage teachers to select teaching materials to be guided by their own interest and circumstances and some topics in relativistic and quantum physics are always included.

None

The content of the course consists of polynomials, linear spaces and linear transformations. This course will train the students with mathematical thinkings and the preliminary ability for solving practical problems.

The basic concepts, theories and essential methods of the course are an important part of students’ scientific accomplishment and play an important role in improving talented people's scientific quality, which cannot be substituted by other courses.This course enables students to grasp the elementary knowledge of mechanics, thermodynamics, electromagnetism, wave and optics and modern physics. It provides a basis for the work they will do after graduation in the fields of technology, management and scientific research.