1. Programme Outline
Materials are the physical foundation upon which human survival depends, and materials science and engineering form the basis of all industries.It builds the development foundation of many scientific research and industries, such as new energy, sustainable development, bio-science, health and medicine, information technology, and intelligent manufacturing. As a popular programme for undergraduates,Materials Science and Engineering in Queen Mary University of London (hereinafter as QMUL) covers metals, ceramics, polymers, and composite with the involvement of chemistry, materials and engineering. It is one of the most influential and distinct programmes in QMUL. We provide elite education and professional training for students with a thorough grounding in the structure of materials, the properties of materials, the performance of materials, the manufacturing processes and design, shaping and applications. It has been rated as 5-star programme by the British government for many times. A survey conducted by the National Union of Students in 2011 showed that it ranked top 1 in the UK. In the first three rounds of discipline evaluation conducted by the Ministry of Education of China, the Materials discipline at Northwestern Polytechnical University (NPU) was ranked 9th, 6th, and 3rd respectively. In the fourth round, it received an 'A' rating, and in the fifth round, it achieved a significant breakthrough, positioning itself at the forefront of the top tier. It was selected twice, in 2017 and 2022, for inclusion in the national "Double First Class" initiative for discipline development, with its ESI discipline ranking entering the top 0.28%. NPU has 6 national-level platforms for scientific research and talent training.
QMES international faculty team comprises 105 teachers in total, with the 18 teachers from QMUL and 87 from NPU. Among the 18 teachers from QMUL, there is 1 professor, 3 associate professors, 6 senior lecturers, and 8 lecturers. Within the 87 teachers from NPU, there are 34 professors, 1 senior engineer, 48 associate professors/associate researchers, and 4 lecturers. Among them, there are 9 national-level talents and 3 provincial/ministerial-level talents. Out of all teachers, 85 have experience of studying or working abroad. The teaching staff are involved in 29 various educational reform projects, with 2 receiving the Baosteel Outstanding Teacher Award and 7 others receiving awards for educational excellence from Queen Mary University of London, including special awards from the principal. There are 3 national-level leading talents, 3 national-level young talents, 3 elected as fellows of the UK Institute of Materials, Minerals and Mining, and 1 elected as a fellow of the Higher Education Academy in the UK.
In order to learn from the advanced concept and model of training innovative undergraduate talents in British higher education and provide Chinese students with an authentic British-style higher education in their homeland, NPU and QMUL have launched a joint educational institution named Queen Mary University of London Engineering School, Northwestern Polytechnical University (hereinafter referred to as QMES), which was approved by the Ministry of Education of China. QMES, builds on the acknowledged expertise and experience of the two universities and their complementary research strengths in materials science, engineering, chemical and fully uses educational resource advantages and high-level international cooperation platforms of both universities to provide a high quality degree level education in the programme of Materials Science and Engineering (080401H). We draw on the academic expertise of both institutions and adopt an international teaching mode with curriculum system, teaching materials, and assessment methods from the UK. We aim to cultivate interdisciplinary leading talents who possess an international perspective and recognition of international rules in the field of engineering. With advanced materials and their preparation technology as the core, our programme integrates with the international frontiers of materials science and chemical engineering disciplines. We aim to nurture individuals with patriotism and social responsibility, as well as solid foundations in natural sciences, materials science and engineering, and humanities. Our graduates have strong professional competitiveness, high comprehensive competence, innovative consciousness and capabilities, and lifelong learning abilities.
2. Aims of the Programme
Focused on the international academic forefront of materials science, committed to the progress of human civilization and the development of the materials science discipline, this programme aims to cultivate interdisciplinary leading talents with a strong sense of national pride and social responsibility, possessing a solid foundation in natural science, materials scienceand engineering, and humanities, and possessing the abilities of innovation and lifelong learning. We aim to develop interdisciplinary leading talents who can engage in design and development, manufacturing, engineering management, and scientific research in fields such as mechanical manufacturing, electronic information, telecommunications, computing, and biopharmaceuticals related to materials and chemical engineering. Students who have completed their studies will be able to pursue higher degrees and research within universities in China and internationally or careers in world famous enterprises and international organization.
(1) Humanistic Literacy
Graduates can accurately understand China's characteristics and compare them internationally, developing a comprehensive and objective understanding of modern China while engaging globally. They are familiar with international norms and have a broad global perspective. Graduates should possess good literacy in humanities, professional ethics, social responsibility, and environmental awareness, as well as a concept of sustainable development. They should be capable of handling their positions competently and actively serving their industries and society, becoming qualified constructors of socialist undertakings and reliable successors.
(2) Professional Competence
Graduates should possess the ability to proficiently apply specialized knowledge in their disciplines and utilize modern tools. They should demonstrate innovative spirit, with the capability to conduct scientific research, design, and development of new materials, technologies, and processes. Additionally, they should have engineering skills for equipment transformation and upgrading. They should be able to comprehensively analyze and research complex engineering problems in the field of advanced materials science and engineering, and propose solutions.
(3) Career Orientation
Graduates should be familiar with the current status and trends of industry development, and capable of participating in or independently engaging in material research, process design, technological development, market expansion, development planning, production, and business management in the field of advanced materials science and engineering. Graduates have the capability to pursue further studies at world-renowned universities or to work for globally renowned companies and international organizations.
(4) Social Skills
Graduates should have a high level of English proficiency, capable of proficiently reading professional English materials, engaging in professional writing, and technical communication in English. Graduates should have excellent communication skills, interpersonal skills, and teamwork abilities. They are able to effectively collaborate in cross-cultural and interdisciplinary teams, playing a pivotal role as technical backbone or primary leaders.
(5) Self-development
Graduates should have innovative thinking, awareness, and capabilities, equipped with the ability to identify, analyse, and solve problems. They possess strong lifelong learning abilities, capable of continuously learning, adapting, and creating new ideas, methods, and products in ever-changing environments. In both learning and practice, they are brave in exploration and daring in innovation, driving technological innovation and social development.
3. Ideological Education
Implement the fundamental task of establishing virtues and educating people, use the thought of socialism with Chinese characteristics in the new era to shape the soul and educate people, and strive to cultivate students to become chief engineers who embody patriotism, humility, pragmatism, inclusiveness, steady accumulation, and vigorous development, all while serving the nation. By making full use of the wide application and strong practical characteristics of materials science and engineering, bridge the module knowledge to national major projects and personage deed through in-class and extracurricular diversified teaching methods, as well as new media carriers to strengthen the guidance of value and foster the ideological and political education through the whole process of teaching. It is necessary to not only make the teaching vivid, but also to make the process of ideological and political moral education concrete so as to convince people with reasonable facts. Guide teachers to align with human development and social progress, national strategies, and technological frontiers, delve into the education elements within the curriculum, and achieve a deep integration of education with professional teaching. Guide students to establish patriotism while teaching them solid professional knowledge in order to improve students' ideological and moral sentiments, enhance their sense of social responsibility and mission to serve the country and the people, as well as to improve their understanding of the relationship between individuals and society, individuals and nature, and to grasp the concepts and implications of engineering ethics and sustainable development.
4. Graduation Requirements (Core Abilities of Students)
4.1 Engineering Knowledge:students will master mathematics, natural science, engineering fundamentals, and professional knowledge required for Materials science and Engineering. Students will have the ability to apply that knowledge to solve complex engineering problems in the design, synthesis, processing, and application of materials.
(1) Students will have the ability to use the terminology of mathematics, natural science, and engineering science to express complex engineering problems in the field of materials science and engineering.
(2) Students will have the ability to establish and solve mathematical models for specific processes related to the preparation, processing, and application in the field of materials science and engineering.
(3) Students will have the ability to apply mathematics, natural science, engineering fundamentals, and professional knowledge to derive and analyse complex engineering problems in the field of materials science and engineering.
(4) Students will have the ability tocompare and synthesize engineering fundamentals and professional knowledge with mathematical modeling methods for solutions to complex engineering problems in the field of materials science and engineering.
4.2 Problem Analysis: students will have the ability to use the basic principles of mathematics, natural sciences and engineering sciences to identify and express complex engineering problems of material composition, structure, production processes and related equipment of materials and their products, obtaining effective conclusions through literature research and analysis.
(1) Students will have the ability in utilizing relevant scientific principles to identify and judge key issues in the synthesis, modification, moulding and processing, performance testing and engineering applications of materials.
(2) Students will have the ability in refining and modelling complex engineering problems in the synthesis, modification, moulding and processing, performance testing and engineering applications of materials, clarifying key stages and parameters.
(3) Students will have the ability in refining, analyzing and evaluate complex engineering problems in the field of materials, rationalizing, optimizing and improving solutions.
(4) Students will have the ability to search and analyze literature, and apply effective information to solve complex engineering problems in the preparation, processing and application of materials.
4.3 Design/Development of Solutions: students will have the ability to propose solutions to complex engineering problems in the production and processing of materials and the regulation of their properties, developing designs for processes and advanced material products to meet specific needs, demonstrating innovation in the design process and considering social, health, safety, legal, cultural and environmental factors.
(1) Students will master relevant design/development principles, methods and techniques in the field of materials, and understand factors affecting design objectives and technical solutions.
(2) Students will have the ability to design and develop solutions to complex problems in the field of materials and select appropriate processing and equipment for specific needs.
(3) Students will have the ability to systematically integrate relevant processes in the preparation, processing and application of materials, demonstrating a sense of innovation in solutions to complex engineering problems, and figuring out solutions under various constraints.
(4) Students will have the ability of taking safety, health, legal, cultural and environmental constraints into consideration during the design, development and solving of complex engineering problems in materials.
4.4 Research: students will have the ability to conduct research based on scientific principles and using scientific methods on complex engineering problems in the process of research and development, production and processing of materials, with abilities in experimental design, implementation, product testing, data analysis, and synthesizing relevant information to reach reasonable and effective conclusions.
(1) Students will have the ability to research and analyze complex engineering problems in the R&D and production of materials using scientific methods based on fundamental principles and professional knowledge in natural sciences and materials fields, combined with literature review.
(2) Students will have knowledge in basic synthesis, characterization, moulding processing and performance testing methods and experimental operation skills, with the ability in choosing research methods and designing experimental programmes.
(3) Students will have the ability to build an experimental set-up or experimental platform, carrying out experiments safely, and collecting experimental data correctly according to the research programme and methods.
(4) Students will have the ability to analyze and interpret experimental results and synthesize information to reach reasonable and valid conclusions, and engage in interdisciplinary and cutting-edge research exploration.
4.5 Use of Modern Tools: Students will have the ability to develop, select and use appropriate technologies, resources, modern information technology tools and engineering tools for complex engineering problems in the design, synthesis, moulding and processing of materials, predicting and simulating relevant complex engineering problems and understanding their limitations.
(1) Students will understand the working principles and methods of modern instruments, engineering tools, IT tools and simulation software commonly used in materials science and engineering field, understanding their application areas.
(2) Students will have the ability to select and use appropriate techniques, methods and modern tools to analyse, calculate and design the structure and properties of materials, solving complex engineering problems in the preparation, processing and application of materials.
(3) Students will have the ability to develop or select modern tools for the simulation and prediction of complex engineering problems in the preparation, processing and moulding, as well as in the structure and properties of materials and their products, controlling parameters and regulating performance, understanding their limitations.
4.6 Engineering and Society: students will understand the laws and regulations related to the preparation, production and moulding processing of materials, will have the ability in analyzing engineering practice scenarios based on a background knowledge of engineering related to materials, evaluating the social, health, safety, legal, and cultural impacts of materials science and engineering practice and solutions to complex engineering problems, and understanding the responsibilities involved.
(1) Students will have basic knowledge of technical standards, intellectual property rights, environmental safety, laws and regulations in the preparation, production and moulding process of materials, and have the initial ability to deal with crises and emergencies.
(2) Students will have experiences in engineering and social practices related to materials, and the ability in analyzing and evaluating the social, health, safety, legal and cultural impacts of materials science and engineering practices and solutions to complex engineering problems, as well as understanding the responsibilities to be assumed.
4.7 Environment and sustainable development: Have a strong awareness of environmental protection and sustainable development based on the characteristics of materials, and be able to understand and evaluate the influences of engineering practices on complex material engineering problems to the environment and sustainable development of society.
(1) Know and understand the concept and connotation of environmental protection and sustainable development, understand policies and legal regulations related to environmental protection at the national and various levels; be capable of understanding and evaluating the impact of engineering practices on complex material engineering problems on the environment.
(2) Have strong sense of sustainable development, being aware of the national strategy of sustainable development. Correctly understand and evaluate the impact of engineering practices on complex engineering problems in the field of materials on the sustainable development of society.
4.8 Professional ethics: Possess a sense of patriotism, humanities and social science literacy, and social responsibility. Capable of understanding and adhering to engineering professional ethics and standards in materials science and engineering practices, and also fulfilling responsibilities.
(1) Have a correct world view, outlook on life and values, possessing a sense of patriotism, humanistic knowledge, scientific literacy, and social responsibility.
(2) Understand the engineering professional ethics and norms of honesty, fairness andintegrity, and consciously abide them in engineering practices. Understand the responsibility of materials science and engineering professional engineers to the public's safety, health and welfare, and the ecological environment, and consciously fulfill duties in engineering practice.
4.9 Individual and team: Possess team collaboration abilities, understand the significance and role of teams in a multidisciplinary context ,and the positioning and responsibilities of each role in the team, capable of taking on the roles of an individual, team member, and leader within a team.
(1) Possess team spirit, understand the significance and role of team collaboration under multidisciplinary integration. Capable of effectively communicating with members of other disciplines within the team. Capable of working independently or in cooperation within the team.
(2) Understand the positioning and responsibilities of each role in the materials research and development team, and production team.Actively take on the roles of an individual, team member, and leader within the team, collaborate with team members to complete tasks, possessing the ability to organise and manage a team.
4.10 Communication: Capable of effectively communicating and exchanging views on issues related to materials science and engineering with peers both domestically and internationally and with the general public, including writing reports, making statements, clearly expressing or responding to instructions, and possessing a certain international outlook and cross-cultural background learning, communication, and exchange abilities.
(1) Capable of accurately describing and clearly expressing complex engineering problems related to materials science and engineering through drawings, reports, design manuscripts, speeches, and defences in both written and oral forms, understanding the differences in communication and exchange on complex engineering problems with industry peers and the general public.
(2) Possess strong language expression abilities and foreign language listening, speaking, reading, and writing abilities, capable of basic communication, exchange, and cooperation on the research, development, design, and application of materials in a cross-cultural context, understanding domestic and international development trends, research hotspots in the field, understanding and respecting the differences and diversity of cultures around the world.
4.11 Project management: Understand and master the principles of engineering management and economic decision-making methods, have engineering practice experience, and apply them in solving complex synthesis, processing, and engineering application problems of materials in a multidisciplinary environment.
(1) Have engineering practice learning experiences, understand and master important engineering management principles and economic decision-making methods involved in materials science engineering activities.
(2) Capable of applying related engineering management principles and economic decision-making methods in engineering activities in a multidisciplinary environment, using engineering management and economic decision-making methods in the process of designing and developing solutions in the field of materials science and engineering.
4.12 Lifelong learning: Possess the awareness of self-learning and lifelong learning, with the ability to continuously learn and adapt to development.
(1) Have good mental and physical health, Capable of recognising the necessity and importance of continuous learning, possessing the awareness of self-learning and lifelong learning.
(2) Capable of continuously learning and adapting to the needs of personal and industry development, including the ability to understand complex engineering problems, analyse, summarise, and pose questions in the field of materials science and engineering.
5. Qualification and Degree Certificate
Official length of the programme: 4+0 years’ study in accordance with the credit management system, the maximum length of study shall not exceed 6 years.
Qualification and certificate: After students have successfully passed all modules and meet the graduation requirements of two universities, they will be awarded diploma by NPU, BEng degree by NPU, and BEng degree by QMUL.
6. Credits and Hours
Total credits:172+X credits
Includes:
Type of module | Credits |
General education modules | 84 |
Technical discipline modules | 88 |
Total credits | 172 |
Personality Development Modules | 6 |
Extension practices |
7. Curriculum Structure and Credits
The total credits for the Materials Science and Engineering major (080401H) are 172, with a total study time of 2974 hours. The distribution of credits for the modules is as follows:
Number of modules from QMUL introduced | 21 | Total number of modules | 53 | Percentage | 39.6% |
Number of core modules from QMUL introduced | 18 | Total number of core modules | 25 | Percentage | 72% |
Number of core modules taught by QMUL lecturers | 18 | Total number of modules | 53 | Percentage | 34% |
Hours for core modules taught by QMUL lecturers | 1016 | Total hours for modules | 2974 | Percentage | 34.1% |
(General education modules and technical discipline modules: 172 credits;Personality Development Modules and extension practices : X credits)
7.1 General education modules 84credits
1). General Studies modules
(1) Aesthetics and Art modules 4 credits
Module Code | Module Name | Credit | Hour | Category | Note |
U30G11001 | College aesthetic education | 2 | 32 | Compulsory module |
|
U30G11002 | Art appreciation | 2 | 32 | Elective compulsory | Art history modules |
U30G12001 | The Path of Chinese Aesthetics(Eng) | 2 | 32 |
U30G11020 | Appreciation Course of Classical Poetry and Music | 2 | 32 | Music modules |
U30G11007 | Appreciation of Drama | 2 | 32 | Drama modules |
U30G11008 | Appreciation of Chinese Opera | 2 | 32 |
U30G11022 | Beijing opera | 2 | 32 |
U30G11016 | The beauty of Chinese literature and art | 2 | 32 | Literature modules |
U30G11005 | Film and Television Appreciation | 2 | 32 | Film and television modules |
U30G11018 | Video China-Documentary and Cross-cultural Communication | 2 | 32 |
U30G11021 | Mural Art Workshop | 2 | 32 | Art modules |
see the current semester modules |
| Dance modules |
see the current semester modules |
| Art design modules |
All students should take the compulsory module—college aesthetic education (2 credits) and at least 2 credits in the other eight elective compulsory modules designated by the Ministry of Education.
(2) Civilization and Technology, Innovation and Entrepreneurship, Management and Leadership, Global Perspectives, Ecology and Sustainable Development, Writing and Communication," each module worth 6 credits. Please refer to the module offerings for the current semester for specific details.
Module Code | Module Name | Credit | Hour | Category |
| Civilization and Technology | 6 | 96 | Elective |
Innovation and Entrepreneurship |
Management and Leadership |
Global Vision |
Ecology and Sustainable Development |
Writing and Communication |
Note: Students can choose modules from one or more categories listed above and should take at less 6 credits. The module list in each semester will be published by the University.
2). Public Basic Modules
(1) Ideological and political theory modules 18 credits
Module Code | Module Name | Credit | Hour | Category |
U13G11007 | Marxism General Principle | 2.5 | 40 | Compulsory |
U44G11004 | Fundamental of Mao Ze Dong Thoughts | 2.5 | 40 | Compulsory |
U44G11001 | Essentials of Chinese Modern History | 2.5 | 40 | Compulsory |
U13G11012 | Ethics and Fundamental of Law | 2.5 | 40 | Compulsory |
U44G21001 | Ideological and Political Practice | 2 | 32 | Compulsory |
U44G11013 | Situation and Policy(1) | 0.5 | 8 | Compulsory |
U44G11014 | Situation and Policy(2) | 0.5 | 8 | Compulsory |
U44G11015 | Situation and Policy(3) | 0.5 | 8 | Compulsory |
U44G11016 | Situation and Policy(4) | 0.5 | 8 | Compulsory |
U44G11009 | Outline of Xi Jinping Thought on Socialism with Chinese Characteristics for a New era | 3 | 48 | Compulsory |
U44G11003 | History of the Communist Party of China | 1 | 16 | Elective compulsory |
U44G11012 | History of the People's Republic of China | 1 | 16 |
U44G11005 | History of Reform and Opening Up | 1 | 16 |
U44G11011 | History of the Development of Socialism | 1 | 16 |
Students much take all compulsory modules listed in the above, in total 18 credits. Situation and Policy (1)(2)(3)(4) four modules must be taken in 4 academic years (Semester 1 to Semester 7) respectively with 8 hours (0.5 credit) in each year, in total 32 hours (2 credits). Students must choose to study at least one module from the modules "History of the Communist Party of China", "History of the People's Republic of China", "History of Reform and Opening Up" and "History of the Development of Socialism", and take at least 1 credit.
(2) Military modules 4 credits
Module Code | Module Name | Credit | Hour | Category |
U34G11005 | Military Theory | 2 | 32 | Compulsory |
U34P41002 | Military Training | 2 | 32 | Compulsory |
(3) Sports and Mental health modules 6 credits
Module Code | Module Name | Credit | Hour | Category |
U34G11004 | Students Mental Health Education | 2 | 32 | Compulsory |
| For specific programme modules, see the current semester modules offered by the Physical Education Department | 4 | 128 | Elective compulsory |
Students can freely choose different modules according to their majors, physical conditions, interests and physical basis. Students must meet the 421X standard of school physical education qualification upon graduation, that is, complete 4 credits; students should be proficient in 2 sports skills and obtain a skill certificate (one of which is swimming); during the undergraduate period, students can study physical quality development module according to their personal interests and obtain X credits. Students are suggested to choose sports modules during first 4 semesters.
(4) National Security Education 1 credit
National security education is a compulsory public fundamental module with the requirements of attending no less than 1 credit (2 hours) in one academic year. The module list in each semester will be published by the University.
(5) Language modules 8 credits
Module Code | Module Name | Credit | Hour | Category |
UQMG12211/QXU3103 | English for Science and Engineering | 4 | 64 | Compulsory |
QXU3104 | Communication in Science and Engineering | 4 | 64 | Compulsory |
(6) Mathematics and Natural Science 37 credits
Module Code | Module Name | Credit | Hour | Category |
NXC3000 | Advanced Math 1 | 5.5 | 88 | Compulsory |
NXC3004 | Advanced Math 2 | 5.5 | 88 | Compulsory |
NXC3002 | Linear Algebra | 3 | 48 | Compulsory |
NXC3005 | Mathematical Modelling and Computing | 4 | 64 | Compulsory |
NXC3001 | General Physics | 5 | 82 | Compulsory |
QXU4004 | Engineering Chemistry | 3.5 | 56 | Compulsory |
NXC4012 | Mechanical Modelling | 3.5 | 56 | Compulsory |
NXC4022 | Thermodynamics and Phase Transformations | 3.5 | 56 | Compulsory |
QXU5010 | Surfaces and Interfaces | 3.5 | 56 | Compulsory |
7.2 Technical discipline Modules 88 credits
(1) Interdisciplinary Platform Modules 10.5 credits
Module Code | Module Name | Credit | Hour | Category |
QXU3112 | Academic and Professional Engineering Skills | 3.5 | 56 | Compulsory |
UQMM12220/QXU4112 | Developing Professional Engineering Skills | 3.5 | 56 | Compulsory |
UQMM12230/QXU5112 | Business and Professional Skills in Engineering | 3.5 | 56 | Compulsory |
(2) Discipline Elementary Modules 14 credits
Module Code | Module Name | Credit | Hour | Category |
QXU4016 | Engineering Design Methods | 3.5 | 56 | Compulsory |
QXU4015 | Engineering Materials | 3.5 | 56 | Compulsory |
QXU4000 | Materials Science 1-structure and properties | 3.5 | 56 | Compulsory |
QXU4006 | Materials Science 2-processing and applications | 3.5 | 56 | Compulsory |
(3) Discipline Core Modules 29 credits
Module Code | Module Name | Credit | Hour | Category |
QXU4002 | Chemistry for Materials | 4 | 64 | Compulsory |
NXC5015 | Structural Characterisation | 3.5 | 56 | Compulsory |
NXC5026 | Metals I-Deformation and Strengthening | 3.5 | 56 | Compulsory |
QXU5030 | Composite Materials | 3.5 | 56 | Compulsory |
QXU5032 | Physical Properties of Polymers | 4 | 64 | Compulsory |
NXC5036 | Metals II-Alloy Systems and Heat Treatment | 3.5 | 56 | Compulsory |
QXU6004 | Materials Selection in Engineering Design | 3.5 | 56 | Compulsory |
QXU6008 | Materials and Sustainability | 3.5 | 56 | Compulsory |
(4) Discipline Elective Module 14.5 credits
Module Code | Module Name | Credit | Hour | Category |
QXU6032 | Advanced Ceramic and Glass Materials | 3.5 | 56 | Elective compulsory |
NXC6029 | Fracture, Fatigue and Creep | 4 | 64 | Elective compulsory |
NXC6025 | Manufacturing Processes | 4 | 64 | Elective compulsory |
QXU6027 | Renewable Energy Technology | 3 | 48 | Elective compulsory |
(5) Comprehensive Practice 10 credits
Students can participate in a variety forms of scientific research training including innovation and entrepreneurship programme and experiment, academic competition, and scientific research project. Students are also encouraged to participate in a variety forms of practice such as overseas practice, international internship, winter and summer schools. Education on labour replies on industrial practice (10 hours) and summer school (6 hours).
Module Code | Module Name | Credit | Hour | Category |
QXU4007 | Experiments in Materials 1 | 3.5 | 56 | Compulsory |
QXU5017 | Experiments in Materials 2 | 3.5 | 56 | Compulsory |
NXC0001 | Scientific Research | 1 | 16 | Compulsory |
NXC0002 | Production Practice | 2 | 32 | Compulsory |
(4)Final project/Thesis for Graduation 10 Credits
Module Code | Module Name | Credit | Hour | Category |
QXU6030 | Materials Project | 10 | 160 | Compulsory |
This project/thesis also supports education on labour with 16 hours to guide students to develop their labor habits and correct labor values.
7.3 Personality Development Modules (6 credits, at least 3 modules)
Students are encouraged to choose the modules taught in English and from the following categories based on their own development and interests.
(1) Comprehensive Literary Module
It is suggested that students should choose the modules taught in English from the following four categories. The module list in each semester will be published by the University.
A. Scientific literacy modules: subjects on natural science such as introduction to aeronautics, astronautics and navigation, environment, biology, etc.
Module Code | Module Name | Credit | Hour | Category |
NXC1004 | Fundamentals of Computer | 1 | 16 | Elective |
NXC1011 | Engineering Literacy-Basic Engineering Practice | 2 | 32 | Elective |
NXC1012 | Engineering Literacy—Teaching and Innovative Practice of Intelligent Robot System | 2 | 32 | Elective |
Details of the above-mentioned modules offered each semester can be found in the course selection handbook for the respective semester. |
B. Modules on economics, management and law: including economy, management, legal education, etc.
C. Humanities modules: including philosophy, ethics, history, culture, language, literature, society, aesthetics, life and development, etc.
Module Code | Module Name | Credit | Hour | Category |
NXC1008 | History of Western Philosophy | 2 | 32 | Elective |
NXC1010 | Scientific English Literature Writing | 1.5 | 24 | Elective |
Details of the above-mentioned modules offered each semester can be found in the course selection handbook for the respective semester. |
D. Art literacy modules:
Module Code | Module Name | Credit | Hour | Category |
UQML21009 | Wine Culture and Tasting Art | 1 | 16 | Elective |
Details of the above-mentioned modules offered each semester can be found in the course selection handbook for the respective semester. |
(2) Discipline Extension Module
Module Code | Module Name | Credit | Hour | Category |
UQML11006 | Biochemistry | 2 | 32 | Elective |
UQML11005 | Analytical Chemistry | 2 | 32 | Elective |
NXC1005 | Inorganic Chemistry | 2 | 32 | Elective |
NXC1006 | Fundamentals of Organic Chemistry | 2 | 32 | Elective |
NXC1007 | Physical Chemistry | 2 | 32 | Elective |
NXC1013 | Introduction to Quantum Mechanics | 2 | 32 | Elective |
NXC1014 | Instrumental Analysis | 2 | 32 | Elective |
Details of the above-mentioned modules offered each semester can be found in the course selection handbook for the respective semester. |
It includes all modules set up by other Schools and major categories.
(3) Advanced Academic Module
It includes general modules offered by the University and postgraduate modules. Credits beyond the ones required by the education plan of the programme can be included in this category.
Module Code | Module Name | Credit | Hour | Category |
NXC1015 | Interpersonal and Communication Skills | 2 | 32 | Elective |
UQML11007 | Introduction of Solid State Physics | 2.5 | 40 | Elective |
UQMM11008 | The Structure and Properties of Polymers | 2 | 32 | Elective |
UQMG11001 | Introduction to Fuel Cell | 1 | 16 | Elective |
UQML11009 | Service Characteristics of Materials Under Extreme Conditions | 2 | 32 | Elective |
UQML21010 | Improving Your Study Skills | 1 | 16 | Elective |
UQMM11001 | Advanced Materials Science and Engineering | 1.5 | 24 | Elective |
7.4 Extension Practices
To encourage students to participate in all kinds of activities linked with ideological education activities, public benefit activities, innovation and entrepreneurship activities, recreational activities, labor Practice, social practice activities. The activities list will be published.
9. Instructive Teaching Plan
