课程基本信息（Course Information）

课程代码

（Course Code）

*学时

（Credit Hours）

32

*学分

（Credits）

2

*课程名称

（Course Name）

（中文）氢能基础与应用

（英文）Fundamentals and Applications of Hydrogen Energy

课程性质

(Course Type)

专业课基础课 Program Core Courses

授课语言

(Language of Instruction)

英语

*开课院系

（School）

中英国际低碳学院

先修课程

（Prerequisite）

无

授课教师

（Teacher）

龙霞

课程网址

(Course Webpage)

*课程简介

在全球能源转型与碳中和目标推动下，氢能作为清洁、高效、可持续的能源载体，已成为未来能源体系的核心组成部分。本课程《氢能基础与应用》面向高校研究生，系统介绍氢能全产业链的关键技术、科学原理及发展趋势，旨在培养具备扎实理论基础和实践能力的高层次氢能专业人才。

课程从氢经济与全球战略出发，分析各国氢能政策与市场格局，探讨氢能在能源体系中的战略意义。随后深入讲解氢的基本物理化学性质，包括氢燃料的热力学特性与能量转换机制。在制氢技术模块，课程涵盖化石燃料制氢（如蒸汽甲烷重整）、碱性电解水（ALK）、固体氧化物电解池（SOEC）、质子交换膜电解（PEMEC）和阴离子交换膜电解（AEMEC）等不同技术路线，并对比其效率、成本及适用场景。

储氢技术部分重点介绍物理法（高压气态、低温液态）和化学法（金属氢化物、液态有机储氢载体）的优缺点及最新研究进展。在氢燃料电池专题中，课程详细解析燃料电池的工作原理、关键材料（如交换膜与催化剂）及系统集成（单电池与电堆设计）。此外，课程还涵盖氢安全工程，包括泄漏检测、防爆措施及风险评估，以及技术经济分析，探讨氢能项目的成本核算与商业化路径。

本课程采用“理论+案例+研讨”的教学模式，结合实验仿真（如燃料电池性能测试、储氢材料表征）和行业前沿动态，帮助学生掌握氢能技术的核心知识，并培养解决实际工程问题的能力。课程最终以期末考试综合评估学习成果，为未来从事氢能科研、产业或政策研究奠定坚实基础。

通过本课程的学习，学生将全面了解氢能技术的最新进展，具备氢能系统设计与优化的能力，并能在能源转型背景下推动氢能的创新应用。

* Description

Against the backdrop of global energy transition and carbon neutrality goals, hydrogen energy has emerged as a clean, efficient, and sustainable energy carrier, playing a pivotal role in future energy systems. The course Fundamentals and Applications of Hydrogen Energy is designed for graduate students, providing a systematic introduction to the key technologies, scientific principles, and development trends across the hydrogen energy value chain. The course aims to cultivate high-level professionals with solid theoretical foundations and practical competencies in hydrogen energy.

The course begins with an exploration of the hydrogen economy and global strategies, analyzing national hydrogen policies and market dynamics while discussing hydrogen’s strategic role in energy systems. It then delves into the fundamental physicochemical properties of hydrogen, including its thermodynamic characteristics and energy conversion mechanisms. The hydrogen production module covers various technological pathways, such as fossil fuel-based methods (e.g., steam methane reforming), alkaline water electrolysis (ALK), solid oxide electrolysis cells (SOEC), proton exchange membrane electrolysis (PEMEC), and anion exchange membrane electrolysis (AEMEC), comparing their efficiency, cost, and application scenarios.

The hydrogen storage section focuses on physical methods (high-pressure gaseous and cryogenic liquid storage) and chemical methods (metal hydrides, liquid organic hydrogen carriers), highlighting their advantages, limitations, and recent research advancements. In the fuel cell module, the course provides an in-depth analysis of working principles, critical materials (e.g., membranes and catalysts), and system integration (single-cell and stack design). Additionally, the course addresses hydrogen safety engineering, covering leakage detection, explosion prevention, and risk assessment, as well as techno-economic analysis, examining cost evaluation and commercialization strategies for hydrogen projects.

Adopting a "theory + case studies + seminars" teaching approach, the course incorporates experimental simulations (e.g., fuel cell performance testing, hydrogen storage material characterization) and industry trends to help students master core hydrogen technologies and develop problem-solving skills for real-world engineering challenges. The course concludes with a final examination to assess learning outcomes, laying a solid foundation for future careers in hydrogen-related research, industry, or policy-making.

Upon completing this course, students will gain a comprehensive understanding of the latest advancements in hydrogen energy, acquire the ability to design and optimize hydrogen systems, and contribute to innovative applications of hydrogen in the context of global energy transition.

课程教学大纲（Course Syllabus）

*学习目标

(Learning Outcomes)

通过本课程学习，学生将全面掌握氢能基础知识与关键技术，包括制氢、储运和应用全产业链的核心原理与最新进展。课程注重理论与实践相结合，通过案例研讨和模拟训练，使学生具备解决氢能领域实际问题的专业素养，为未来从事氢能科研或产业工作奠定坚实基础。

*教学内容、进度安排及要求

(Class Schedule

& Requirements)

*考核方式

(Grading)

出勤与课堂讨论占总分20%。

1次报告形式的课堂讨论，占总分40%；其中报告占70%，讨论占30%；

1次期末考试，占总分的40%。

*教材或参考资料

(Textbooks & Other Materials)

氢与氢能，李星国，机械工业出版社，2012

氢燃料电池，衣宝廉等，化学工业出版社, 2021

Hydrogen as a Future Energy Carrier, Andreas Züttel, Andreas Borgschulte, and Louis Schlapbach, WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim, 2008

Web of Science

其它

（More）

无

备注

（Notes）

无