1.  Polymer Materials and Engineering

Polymer Chemistry

The main contents of this course include stepwise polymerization, free radical polymerization, free radical copolymerization, polymerization implementation methods, ionic polymerization, coordination polymerization, ring-opening polymerization, and chemical reactions of polymers, etc. The course focuses on the two reaction mechanisms of chain polymerization and stepwise polymerization, systematically introduces the important reactions of synthesis of polymer compounds from small molecule monomers and their reaction mechanisms, reaction kinetics, reaction thermodynamics, and polymer synthesis methods, and combines the learning of theoretical knowledge with some typical polymerization reaction examples and common polymer products.

Polymer Physics

Polymer physics is an important professional core course of polymer science, based on mathematics, physics, organic chemistry and physical chemistry, with molecular motion as a bridge, to study the internal relationship between the structure and properties of polymers and a discipline of laws. Its main task is to enable students to master the basic concepts, basic theories and basic research methods of the multi-level structure, molecular motion and main physical and mechanical properties of polymers, and establish the relationship between the structure and properties of polymers.

Polymer Materials

The main contents include: plastics, rubber, fibers, coatings and adhesives, functional polymers and their composite materials. Through the course learning, students can understand the basic concepts and laws, research methods and development trends of polymer materials science, expand students’ knowledge and vision, and cultivate students' interest in polymer materials science.

Fundamentals of Materials Science

Based on the electronic structure in atoms and the atom-to-atom interactions, this course is taught in the order of microscopic to macroscopic, from internal to surface, from static to dynamic, from single component to multi-component, from commonality to individual characteristics, and from external factors to macroscopic properties. The common laws and individual characteristics of various materials such as metallic materials, inorganic non-metallic materials, polymer materials, and composite materials are taught in detail.  

Polymer Chemistry Experiment

Polymer chemistry experiment is a compulsory course for polymer materials and engineering, which is a professional practice course carried out on the basis of the theoretical course of polymer materials to cultivate students’ hands-on ability and experimental skills, so that students can gradually have certain thinking methods and experimental ability to engage in scientific research.  

Polymer Physics Experiment

Polymer physics experiment provides students with systematic training in the characterization of physical properties of polymers and the experimental skills of processing. To enable students to learn the use of polymer-related instruments and equipment; Master the testing and characterization methods of the basic physical properties of polymers and the important processing methods of polymer molding; Cultivate students' ability to flexibly use theoretical knowledge to solve practical problems and a rigorous scientific attitude.

Polymer Processing Engineering

Through the study of this course, students have mastered the basic theory of polymer material processing, have a comprehensive understanding of common processing equipment and technology, deepen their understanding of polymer physics and polymer chemistry related theoretical knowledge, and have the basic ability to solve practical engineering problems in the process of polymer material processing.

Polymer Reaction Engineering

On the basis of learning and mastering the theory of Polymer Chemistry, this course systematically expounds the basic theoretical basis of polymerization and synthesis methods and related production processes of synthetic resins and plastics, as well as synthetic rubber. The Synthetic Resins and Plastics section focuses on the basic uses and properties of general-purpose plastics, engineering plastics, heat-resistant and high-performance polymers, synthetic fibers, and water-soluble polymers. The synthetic rubber part mainly introduces the basic knowledge of general rubber, special rubber and powder rubber and the characteristics of synthetic production process.

2. Material Science and Engineering

Material Surface Technology

This course teaches the basic principles, process methods and related equipment of common material surface technology, enabling students to apply various surface technologies to prevent and control metal corrosion failure problems.

Metal Corrosion Theory and Corrosion Control

This course introduces the essence, mechanism and influencing factors of metal corrosion, as well as various means and measures of  corrosion control in the materials, chemical and mechanical industries, especially the principle and engineering application of protection technologies such as cathodic protection, anode protection, corrosion inhibitors and coating.

 Corrosion-Resistant Non-metallic Material

This course introduces the types, principles, synthesis principles and processes of commonly used corrosion-resistant polymer materials and corrosion-resistant nonmetallic materials, guiding the selection or design of corrosion-resistant nonmetallic materials.

 Anti-corrosion Engineering

This course introduces the basic knowledge of common materials used in anti-corrosion engineering and the basic preparation technology of composite materials used in anti-corrosion engineering.

 Metal Heat Treatment Principles and Process 

This course is one of the main theoretical courses in the major of Materials Science and Engineering (Metal Materials Direction), mainly introduces the principle of heat treatment and heat treatment process including the law of solid phase transition in the process of heating and cooling of metal, and the basic characteristics of solid phase transition. Base on the course, the basic knowledge of phase change thermodynamics, dynamics should be acquainted, the important role of heat treatment process as theory guidance should be understood, the ability of process design of heat treatment should be established.Mechanical Properties of Materials

Metal Welding Process and Equipment 

This course is one of the main theoretical courses in the major of Materials Science and Engineering (Metal Materials Direction), which introduces the basic principles and techniques of most welding process methods. Based on this course, it's the three aims that should be obtained, which means to a deep understanding of the basic content of welding and arc welding, an acquaintance with the characteristics, working principles, and process equipment of various arc welding methods, a certain understanding of the latest developments in welding process control and welding technology.

Metallic Materials

        This course is a comprehensive professional core course for the metal direction in the major of Materials Science and Engineering. It systematically introduces the basic characteristics of metals, alloying theories, and the principles and methods for the design and application of metals. Based on the course, alloying principles and its application could be grasped, the interest in design and research in metals could be developed, the ability of solving practical problems could be established.

Powder Metallurgy

This course is one of the main theoretical courses in the major of Materials, establishing students' ability to characterize powder properties and design powder metallurgy processes. Based on the course, the ability of problem analysis, professional scheme design and research, and sustainable development could be established.

3. Inorganic non-metallic material engineering       

Modern Analytical Methods of Materials

        This course makes a special effort to focus on principles and applications, leaving lengthy (and usually intimidating to engineering students) derivations and formulations out of its scope, engineering students can concentrate on the basic principles and applications of these modern technologies.

Fundamentals of Thermal Engineering of Materials,

The course is normally required for undergraduates majoring in ceramic engineering. It mainly presents the principles of heat transfer in the preparation of new materials, the cooling of electronic devices and aerospace equipment. The topics of the course include the basic principles of fuel combustion, fluid mechanics, heat transfer, and drying.

Powder Materials Science

This course is a crucial mandatory core course in the field of inorganic non-metallic materials engineering. The curriculum primarily covers the following topics: basic definitions and characteristics of powders; particle geometry; powder statics; powder dynamics; powder fluid systems; granulation and homogenization of powders; separation, classification, and conveying of powders; powder dispersion; surface modification of mineral powders; dust explosions, as well as the latest theoretical achievements and development trends of powders in the fields of new materials and new energy. Through the study of this course, students are expected to acquire fundamental theories, basic knowledge, and essential skills related to powders and their mechanical properties in materials areas such as ceramics and powder metallurgy.

Principles and Equipment of Material Processing

This course is an important core compulsory course for the engineering major of inorganic non-metallic materials. The course will mainly teach the preparation equipment of the powders about advanced materials. The process principle, main structure and application of new inorganic non-metallic materials, new energy materials, and semiconductor materials will be taught. By learning this course, students should have basic theoretical knowledge of advanced inorganic material processing principles and equipment.  They have the basic ability to analyze and solve relevant problems involved in the processing of advanced inorganic materials. And they will be able to lay the foundation for post-process design selection and production management.

Advanced Inorganic Materials Technology

This course is an important professional core course and degree course for undergraduates of inorganic nonmetallic material. Based on essential issues and theories, Advanced Inorganic Materials Technology pays more attention on integrating theory with practice. It is a fundamental, systematic and cutting-edge course. The main content covers traditional ceramics, structural ceramics, functional ceramics, special glass, special inorganic bond materials and environmental protection. In this course, the undergraduates can analyze and solve the complex engineering problems about inorganic material design, preparation and processing.

Physical Properties of Inorganic Materials

This course is one of the core compulsory courses in the major of Inorganic non-metallic materials engineering. The prerequisites are inorganic chemistry, general physics, fundamentals of materials science, engineering mechanics, etc. The course covers mechanics, thermotics, optics, electrics, magnetics properties of inorganic materials.  

Process Design of Ceramic Materials

This course is a practical course to consolidate, deepen and expand the knowledge of inorganic non-metallic materials engineering. Through this practical teaching link, students & apos have ability to consult and correctly use various literature materials. It has the basic quality and ability to comprehensively apply professional basic knowledge and professional knowledge to solve practical engineering problems, and enhance the concept and practical ability of engineers.

4. New Energy Materials and Devices

New Energy Materials and Devices

The course of new energy materials and devices is a professional course involving the preparation, characterization, performance and application of new energy materials. It covers the design, preparation, performance and application of materials and devices in the field of renewable energy such as solar energy, wind energy, water energy and geothermal energy.The main contents of the course include: the basic concept of new energy materials, physical basis, crystal structure, the relationship between defects and properties, the working principle, manufacturing process and performance optimization of solar cell materials and devices, the principle of wind energy conversion and the design and optimization of wind turbine, the principle of water energy conversion and the design and optimization of hydraulic generator, and geothermal energy development and utilization technology and geothermal energy power plant design and operation. In addition, the course will also introduce some emerging green energy technologies, such as fuel cells, supercapacitors, and lithium-ion batteries.

Semiconductor Physics

As a core compulsory course for the major of new energy materials and devices, this course is closely related to basic knowledge and practical application. This course provides a comprehensive introduction to the basic knowledge of semiconductor physics, including electronic states, impurities and defect energy levels, statistical distribution of carriers, conductivity of semiconductors, non-equilibrium carriers, p-n junctions, optoelectronic and magnetic effects of semiconductors.

Material Synthesis and Preparation Technology

This course introduces the principle and technology of modern material synthesis and preparation. It is an important core professional basic course for all majors of materials science and engineering. Through this course, students will not only be able to master the preparation methods and related technologies of metal materials, single crystal materials, thin film materials, ceramic materials, composite materials and nanomaterials, but also be able to be exposed to the forefront of material preparation technology, which provides solid theoretical and technical support for the follow-up study of various materials professional courses, and can also cultivate students’ innovative ideas and innovative thinking.

Introduction of Principles and Applications of Electrochemistry

Principles and Applications of Electrochemistry is a core and obligatory course for undergraduates majoring in new energy materials and devices. The main contents included electrochemical thermodynamics, structure and properties of electrode/solution interface, dynamics of electron transfer-determining step, electro-catalysts for HER and OER, metal electrodeposition and chemical power supply. The purpose of the course is to learn the thermodynamic and kinetic of electrode reactions, and to use the relevant basic principles of modern electrochemistry to solve engineering problems involved in scientific research and actual production.  

Hydrogen Energy Utilization and Hydrogen Storage Materials

Hydrogen Energy Utilization and Hydrogen Storage Materials is a major elective course in the field of new energy materials and devices. The main content of the course focuses on the basic characteristics of hydrogen energy, various hydrogen production, storage, and utilization technologies, as well as the basic chemical reaction principles, key materials, fuel cell stack structures and application scenarios involved in these technologies. Moreover, the international development trends of hydrogen energy, as well as the problems we faced in the development and utilization of hydrogen energy are the main teaching content.  

Battery Recycling and Resource Utilization

The cascade utilization and recycling technology of power battery has a very important position in the current development of science and technology, and has attracted much attention in the field of supporting social sustainable development and environmental technology. Combined with the development status and trend of battery technology and electric vehicles at home and abroad, this course systematically introduces the cascade utilization and safety assessment technology of retired power batteries, the disruptive cascade utilization technology, the battery pack and monomer pretreatment technology, the power battery recycling and processing technology, the comprehensive utilization of resources and the whole life cycle evaluation.  

Introduction to Carbon Neutralization Technology

It mainly introduces the three carbon reduction fields of energy, resources and information, as well as the carbon emission reduction, carbon zero emission and carbon negative emission technologies of key industries, which are divided into energy, resources, information, industry and decision-making.

Energy Catalytic Materials and Technologies

Energy catalytic materials refer to a class of materials with catalytic effect, which are widely used in the fields of energy conversion, preparation and utilization. These materials have the advantages of high catalytic performance, high stability and low energy loss, and have become one of the hot spots in contemporary chemical materials science. This course explains the application range, types, preparation and modification methods of energy catalytic materials and the future development trend of energy catalytic materials.

New Energy Power Battery Technology

This course introduces in detail the basis of power battery chemistry, battery system development, battery control technology and its testing and verification means. Explain the fundamentals of battery chemistry, including battery overview, battery chemistry, ternary battery, lithium iron battery, solid state battery, advanced battery and battery related concepts and principles.