FUNCTIONAL MATERIALS

The field of Functional Materials is a promising and highly potential field, offering numerous career opportunities in the future. If you are passionate about technology, possess creative thinking, and want to participate in developing high-tech products, Functional Materials is an ideal choice for you. Let’s explore the academic opportunities and career prospects that this field offers.

Major Introduction

The Functional Materials major was established in response to the rapid development of interdisciplinary technologies, particularly in biomedical engineering, tissue engineering, and drug delivery systems, and the urgent need for professional talent in these areas. This program is an interdisciplinary field that combines materials science, biology, and medicine, with core subjects including polymer materials science and engineering and biomedical engineering. The focus is on teaching and researching biomaterials and biomedical engineering.

Students are required to study basic knowledge, principles, and experimental skills in inorganic and analytical chemistry, organic chemistry, physical chemistry, polymer chemistry, polymer physics, material synthesis and applications, material analysis and testing techniques, as well as polymer synthesis principles and process technology. They will also familiarize themselves with national policies and regulations regarding science and technology, material preparation, and application, intellectual property, etc. 

Students will receive specialized training in functional material preparation and processing, mastering the use of modern information technology to gather relevant information. They will develop skills in experimental design, data analysis, report writing, and academic exchanges, and acquire knowledge related to engineering technology, product development, and testing, with the ability to solve practical production problems.

Training Objectives

The training of talents in the Functional Materials major is primarily based on the needs of national strategic emerging industries and the development trends of the discipline. Following the principle of broadening the basic and professional knowledge, students will be trained in the comprehensive development of ethics, intellect, physical fitness, aesthetics, and labor. The goal is to equip students with the basic theories and knowledge of functional materials and related devices. 

They will receive rigorous training in scientific experiments and research, preparing them to design and develop new materials, new products, new technologies, and new processes, and to engage in teaching, research, management, and business in an applied and innovative manner. Specific goals include:

• Master the basic theory of materials science and professional knowledge and skills in material synthesis, preparation, and testing.

• Develop a strong sense of social responsibility, understand and adhere to professional ethical standards, and comply with industry standards and regulations in the materials field.

• Cultivate teamwork spirit, effective communication skills, and some engineering project management capabilities, enabling students to effectively contribute as key members of a technical team.

• Familiarize with specialized technical fields in materials science, understand the cutting-edge trends of the discipline, possess some technical innovation abilities, and be able to apply modern tools to engage in new product development, technological research, process design, and technological improvement.

• Develop a good command of foreign languages, self-learning abilities, an innovative spirit, and awareness of serving local economies and societal development, including awareness of serving ethnic minority areas.

Graduation Requirements

• Be able to apply mathematics, natural sciences, engineering fundamentals, and professional knowledge to solve complex engineering problems in the production process of functional materials.

• Be able to apply the basic principles of mathematics, natural sciences, and engineering to identify, express, and analyze complex engineering problems related to functional materials through literature research to obtain effective conclusions.

• Be able to design solutions for complex engineering problems related to functional materials, design materials and manufacturing processes that meet specific needs, develop solutions, and incorporate innovation in the design phase, considering social, health, safety, legal, cultural, and environmental factors.

• Be able to study complex engineering problems related to functional materials based on scientific principles, using scientific methods to design experiments, analyze and interpret data, and draw reasonable and effective conclusions through information integration.

• Be able to develop, select, and use appropriate technologies, resources, modern engineering tools, and information technology tools for solving complex functional material-related engineering problems, including forecasting and simulating engineering issues, while understanding their limitations.

• Be able to analyze and evaluate the impact of engineering practices and solutions for complex functional materials-related problems on society, health, safety, law, and culture, understanding the responsibilities involved.

• Be able to understand and evaluate the impact of engineering practices on the environment and social sustainability.

• Develop humanities and social science literacy, social responsibility, and be able to understand and adhere to professional ethics and standards in the engineering practice of functional materials.

• Be able to assume individual, team member, and leadership roles within a multidisciplinary team.

• Be able to communicate effectively with industry peers and the general public about complex engineering problems, including writing reports, design documentation, giving presentations, and clearly expressing or responding to instructions. Students will also possess a global perspective and be able to communicate and interact in a cross-cultural context.

• Be able to understand and apply engineering management principles and economic decision-making methods in a multidisciplinary environment.

• Develop the awareness of autonomous learning and lifelong learning, with the ability to continually learn and adapt to new developments.

Core Courses

• Inorganic Chemistry

• Analytical Chemistry

• Organic Chemistry

• Physical Chemistry

• Structural Chemistry

• Polymer Chemistry

• Polymer Physics

• Polymer Processing and Molding

• Fundamentals of Materials Science

• Principles and Methods of Material Characterization

Research Directions of Functional Materials

Graduates of the Functional Materials major have wide career development opportunities in fields such as materials science and engineering, electronics, renewable energy, biomedical applications, aerospace, and more. Typical career directions include:

• Materials Engineer: Engaged in the research, process design, and product development of functional materials.

• Research Scientist: Conducts basic research and technology development in functional materials in research institutions or companies.

• Product Manager: Responsible for market analysis, product design, and promotion of functional materials products.

• Quality Control Engineer: Engaged in performance testing and quality control of functional materials.

• Technical Support Engineer: Provides technical support and solutions for the application of functional materials.

Degrees Awarded

Bachelor degree

Career Development

Graduates from this major have broad employment prospects, mainly engaging in the following positions:

• New Materials Enterprises: Research and development, production, and application of functional materials.

• Research Institutions: Basic research and applied research on functional materials.

• Higher Education Institutions: Teaching and research work.

• Electronics and Information Enterprises: R&D and production of electronic components, semiconductor materials, etc.

• Automotive Manufacturing Enterprises: R&D in automotive lightweight materials, battery materials, etc.

• Medical Device Enterprises: Research and development and production of biomedical materials.

Related Majors

• Materials Science and Engineering

• Materials Physics

• Materials Chemistry

• Metallurgical Engineering

• Metal Materials Engineering

• Inorganic Non-metallic Materials Engineering

• Polymer Materials and Engineering

• Composite Materials and Engineering

• Powder Materials Science and Engineering

• Gem and Materials Technology

• Welding Technology and Engineering

• Nanomaterials and Technology

• New Energy Materials and Devices

• Materials Design Science and Engineering

• Composite Materials Molding Engineering

• Smart Materials and Structures

• Optoelectronic Information Materials and Devices

• Biomaterials

• Materials Intelligent Technology

• Electronic Information Materials

• Soft Matter Science and Engineering

• Rare Earth Materials Science and Engineering

Ranking of Functional Materials Schools

1. Tianjin University

2. South China University of Technology

3. Donghua University

4. Dalian University of Technology

5. Beijing University of Chemical Technology

6. Suzhou University

7. Anhui University

8. Lanzhou University

9. Xi'an University of Architecture and Technology

10. Kunming University of Science and Technology

11. China Jiliang University

12. Tianjin University of Technology

13. Qingdao University of Science and Technology

14. Henan University of Science and Technology

15. Henan Normal University

16. Southwest University of Science and Technology

17. Jiangsu University of Science and Technology

18. Lanzhou University of Technology

19. Suzhou University of Science and Technology

20. Beijing Technology and Business University

21. Changchun University of Science and Technology

22. Shenyang University of Technology

23. Qilu University of Technology

24. Shenyang Architecture University

25. Shijiazhuang Railway University

26. Nanjing Engineering Institute

27. Changsha University

28. Inner Mongolia University of Technology

29. Dalian Polytechnic University

30. Taiyuan University of Technology

This introduction provides a comprehensive overview of the Functional Materials undergraduate program. If you are passionate about materials science and looking for an opportunity to make an impact in various industries such as electronics, renewable energy, biomedical fields, and aerospace, this program will offer numerous career and academic development opportunities.