Nuclear Engineering and Technology

Nuclear Physics

        Nuclear Physics is a foundational course for nuclear-related majors, which explores the fundamental properties and structures of atomic nuclei, as well as nuclear decay and reactions. This course builds on classical physics and connects to quantum mechanics, falling within the realm of modern physics. The goal of this course is to provide students in nuclear-related majors with a systematic understanding of the theoretical knowledge framework of atomic and nuclear physics, laying a solid physical foundation for other related courses in the nuclear field. Nuclear Radiation Detection is a compulsory professional foundation course of Nuclear Engineering and Technology. It serves as both a core compulsory course for the major and a lead course for innovation and practical activities, making it a crucial component in the training of professionals in nuclear engineering and technology. Through the study of this course, students can master the principles and common methods of nuclear radiation detection, and have an in-depth understanding of common nuclear radiation detectors and their working principles, and have better professional quality, fostering strong professional qualities. This course lays a solid foundation for engaging in nuclear engineering and nuclear technology related work after graduation.

Fundamentals of Reactor Physics

        Fundamentals of Reactor Physics is a crucial compulsory course of Nuclear Engineering and Technology. The main content covers nuclear physics related to reactor physics, including the slowing down and diffusion of neutrons in media, critical theory of nuclear reactors, design, burnup, reactivity feedback, control of non-uniform reactors, and reactor dynamics. This course serves as the physical foundation for students' subsequent study of courses such as Nuclear Fuel Cycle and Nuclear Materials, Nuclear Power Systems and Equipment, etc. The course allows students to grasp the fundamental theoretical aspects of neutron physics related to nuclear fission reactors, as well as key physical phenomena and associated analytical and computational methods involved in reactor design, operation, and control.

Fundamentals of Radiation Protection

       Fundamentals of Radiation Protection is pivotal in nurturing talents in the field of Nuclear Engineering and Technology. Students will acquire the basic concepts, principles, and methods of radiation protection, understand the essential technologies, tools, and national standards required in radiation protection, and be equipped with fundamental skills in radiation detection, dose calculation, shielding design, safety analysis, and environmental assessment.

Electronic Nuclear Physics

        Electronic Nuclear Physics systematically introduces the basic theory and circuit design technology of electronic nuclear physics. It focuses on the signal characteristics of different types of nuclear radiation detectors and the characteristics of different nuclear radiation measurement methods. This course enables students to familiar with and master various nuclear signal processing technologies, as well as experimental and testing methods. The course's objectives include understanding the application scenarios of nuclear radiation measurement, the differences in radiation detectors and electronic aspects corresponding to different application scenarios, and the impact of the rapidly developing electronic technology on measurement accuracy.

Methods of Nuclear Data Processing

       Methods of Nuclear Data Processing can enable students to master the basic theories, knowledge, and software tools in the field of nuclear data processing. The course aims to cultivate students' comprehensive and practical abilities to analyze, interpret, and process nuclear data. Specific content covered in this course includes fundamental theories of nuclear spectroscopy, preprocessing methods for spectral data, qualitative methods for spectral data, quantitative methods for spectral data, and error analysis methods for spectral data.

Monte Carlo Numerical Simulation Methods

        Monte Carlo Numerical Simulation Methods aims to provide students with an understanding of the applications of Monte Carlo simulation in nuclear technology, complementing and cross-verifying with nuclear experiments. It will help students grasp the methods of using simulation to replace part of nuclear experiments, laying the foundation for students in this major to engage in nuclear science-related work using simulation methods in the future, and cultivating students' analytical and problems-solving abilities.

Nuclear Analysis

        Nuclear Analysis Methods is to cultivate students' practical engineering abilities, including the design, organization, and implementation of engineering experiments, as well as data processing. The course focuses on providing systematic training in areas such as neutron activation analysis, Mössbauer spectroscopy, and X-ray fluorescence analysis. It aims to enable students to master the handling of scientific experimental problems and research methods, acquire basic operational skills in typical nuclear analysis experiments, understand the fundamental principles of scientific experiment design, and grasp the principles for selecting parameters and organizing processes for scientific experiments. The course seeks to foster students' rigorous scientific attitude and engineering concepts, enhance their ability to analyze and solve problems, and improve their capacity for independent thinking and innovation.

Electronic Information

         Fundamentals of Circuit Analysis

         Fundamentals of Circuit Analysis is the first professional foundation course for electrical undergraduates. It aims to cultivate students' mastery of the basic concepts, principles and analysis methods of circuits, laying a solid foundation for their subsequent studies in courses such as analogue circuits, digital circuits, high-frequency circuits and other courses, etc.

      Analogue Electronics

      Analogue Electronics emphasizes practicality and engineering, serving as a basic introductory course for the cultivation of hardware capabilities of advanced engineering and technical professionals. Specific content includes: semiconductor devices, basic amplifier circuits, frequency response of amplifier circuits, field effect tube amplifier circuits, integrated operational amplifier circuits, negative feedback amplifier circuits, integrated operational amplifier circuits, etc.

        Digital Electronics

       Digital Electronics is an introductory technical foundation course in the field of electronic technology. Through the study of common electronic devices, digital circuits and their systems’ analysis and design, this course provides students with basic knowledge, basic theories and basic skills in digital electronics, laying the groundwork for further study and application in the profession. The key topics include basic logic algebra, gate circuits, combinational logic circuits, flip-flops, sequential logic circuits, semiconductor memories, analysis and design of digital systems, etc.Signals and Systems provides an initial understanding of how to establish mathematical models for signals and systems. The main contents include time-domain analysis of continuous signals and systems, transform-domain analysis of signals and systems, time-domain analysis of discrete signals and systems, and state variable analysis of signals and systems.

         Principle & Application of Microcomputer

        Principle & Application of Microcomputer aims to establish a comprehensive concept of microcomputer systems, enabling students to have fundamental knowledge and skills in applying modern microcomputer technology for software and hardware design and development. The course includes basic knowledge of microcomputers, microprocessor architecture, instruction systems, assembly language programming, memory systems, data transfer between microcomputers and peripherals, programmable I/O interface circuits, and typical chips.

         Digital Signal Processing

        Digital Signal Processing extract the information carried in the signals, and reveal the intrinsic laws of signals and systems using mathematical tools such as calculus and difference equations. It primarily focuses on the basic theory and methods for analyzing and processing discrete-time signals. This course includes fundamental concepts of digital signal processing, time-domain discrete signals and systems, discrete Fourier transform, and the design of infinite impulse response digital filters.High-frequency Electronic Circuit contains the high-frequency circuit basics, high-frequency small-signal amplifiers, high-frequency power amplifiers, sinusoidal oscillators, amplitude modulation and demodulation and mixing circuits. Students will systematically master the basic concepts and working principles of the analysis and design methods of high-frequency electronic circuit.

Information Theory and Coding

       Information Theory and Coding is the fundamental theory studying the transmission and processing of information. It involves the measurement, encoding, and decoding of information, as well as how to effectively transmit and store information. In communication systems, encoding is the process of converting information into a transmittable signal, while decoding is the process of restoring the received signal to the original information. The course covers theoretical knowledge and implementation principles in channel capacity, rate-distortion function, as well as distortion-free source coding, limited distortion source coding, channel coding, and cryptography.

Principles of Communication

       Principles of Communication helps students study the fundamental principles of information transmission and the performance analysis methods of communication systems, enabling the ability to analyze and solve engineering practice problems in communication system design. Specific content includes channels, analog modulation techniques, digital baseband transmission, digital frequency band transmission, optimal reception of digital signals, synchronization, and digital demultiplexing.

        Applied Physics

       Mathematical Physics Methods

       Mathematical Physics Methods have extremely broad applications in the natural sciences and engineering. It is an important bridge between pure mathematics and various branches of natural sciences, as well as engineering and technology. It will help students acquire basic knowledge in complex analysis, Laplace transforms, Fourier integral transforms, and the establishment and solution of three types of partial differential equations. The course aims to cultivate students' ability to solve physics problems using mathematical physics methods, develop their rigorous logic and deduction skills, and provide preliminary training in abstract modeling of practical problems. It also lays a solid mathematical foundation for students to study subsequent courses such as quantum mechanics, electrodynamics, and solid-state physics, etc.

Theoretical Mechanics

        Theoretical Mechanics is the first theoretical physics course that students encounter during their undergraduate studies and serves as the foundation, bridge, and link for studying subsequent theoretical physics courses. It mainly includes Newtonian mechanics and analytical mechanics. Compared to the general physics course Mechanics, Theoretical Mechanics has a higher level of theoretical abstraction and difficulty in problem-solving. It allows students to receive preliminary training in the research methods of theoretical physics, and helps to cultivate students' abilities in rigorous logical reasoning, abstract thinking, generalization from specificity to generality, making students more deeply aware of the close relationship between mathematics and physics.

        Thermodynamics and Statistical Physics

       Thermodynamics and Statistical Physics constitutes the classical core content of physics at the university level, along with Classical Mechanics, Electrodynamics and Quantum Mechanics. This course ensures that students not only grasp the basic concepts, principles, and theoretical methods but also understand the research frontiers and hot topics in related fields, and the connections with other branches of natural sciences. It emphasis on fostering scientific thinking methods, innovative consciousness, and the ability to solve specific problems, laying a solid foundation for the study of subsequent courses and future research. These skills align with the requirements for talent development in the twenty-first century.

Quantum Mechanics

       Quantum Mechanics is one of the fundamental theories in physics, focusing on microscopic objects, and is considered as the two pillars of modern physics together with Relativity. This theory reflects the laws governing the motion of microscopic particles such as electrons, atoms, nuclei, and elementary particles. Quantum Mechanics serves as the theoretical foundation for various disciplines, including atomic physics, condensed matter physics, nuclear physics, particle physics, astrophysics, as well as cutting-edge scientific fields in chemistry, biology, and materials science. Students will graduate with the fundamental principles and concepts of quantum mechanics, laying a solid theoretical foundation for further studies in related courses.

Electrodynamics

        Electrodynamics, along with Theoretical Mechanics, Statistical Physics, and Quantum Mechanics, are known as the four major mechanics. Serving as an extension of electromagnetism and optics, this course systematically introduces the basic concepts and methods of electromagnetic field theory. The teaching content primarily covers the fundamental properties and motion laws of electromagnetic fields, interactions between electromagnetic fields and charged objects, as well as knowledge of the spacetime view in special relativity. The course trains students in logical thinking, deductive reasoning, and the integrated application of physical theories. It acquaints students with the latest developments in physics, enhances theoretical proficiency and overall qualities, and cultivates innovation, scientific research in applying physics knowledge to practical issues.

Semiconductor Physics

      Semiconductor Physics primarily elucidates the fundamental properties of semiconductors, exploring the physical processes, laws, and relevant applications of semiconductors in both thermal equilibrium and non-equilibrium states. Students will graduate with the relevant basic theory of semiconductors and semiconductor surface and interface knowledge, a better unserstanding of semiconductor properties as well as the influence of external factors and their changing law. The main topics covered in the course include electronic states in semiconductors, impurities and defect energy levels in semiconductors, statistical distribution of charge carriers, conductivity of semiconductors, non-equilibrium charge carriers, metal-semiconductor contacts, optical properties of semiconductors, and luminescence and photoelectric phenomena.

      Optoelectronic Technology

      Optoelectronic Technology is a technology based on the principles of optoelectronics, primarily focusing on optoelectronic devices. It involves the comprehensive utilization of optics, mechanics, electronics, computer science, and materials science to create practical instruments, devices, or systems with specific functionalities. The course aims to systematically provide the fundamental principles of common optoelectronic devices and systems, as well as the characteristic parameters, physical significance, performance, and applications of these devices and systems. A strong understanding of optoelectronic technology allows students to initiate new and innovative ideas aimed at furthering optoelectronic development.