International Conference on Advanced Battery Technologies(ICABT 2025)
国际先进电池技术学术会议(ICABT 2025)
Call for Papers
Theme
Next-Generation Battery Technologies and Sustainable Energy Systems
下一代电池技术与可持续能源系统
Conference Goals
To promote the study and development of advanced battery technologies; to introduce recent progress in energy storage research; to discuss key scientific and industrial issues in the battery field; to provide opportunities for international communication and collaboration; to promote the understanding of cross-disciplinary approaches; and to explore future cooperation possibilities among global researchers and institutions.
促进先进电池技术的研究与发展;介绍储能研究的最新进展;讨论电池领域的重要科学与产业问题;提供国际交流与合作机会;增进跨学科研究的理解;探索全球研究机构和学者之间未来合作的可能性。
Topics to be Discussed
Papers are solicited on theoretical issues, experimental advances, and applications related to battery science and energy systems. Suggested topics include but are not limited to:
征集与电池科学及能源系统相关的理论、实验及应用方面的论文。讨论主题包括但不限于:
- Novel materials and design for advanced batteries
先进电池的新材料及设计 - Battery recycling and sustainable energy strategies
电池回收与可持续能源策略 - Integration of batteries in renewable energy and electric vehicle systems
电池在可再生能源与电动汽车系统中的应用与集成
Date / 日期: October 22, 2025(2025年10月22日)
Venue / 地点: Jilin University, China(中国吉林大学)
Papers and Submissions
Authors are invited to submit full papers, up to six pages, with the authors’ names and affiliations, complete address (including email, fax and phone number of the corresponding author), before April 10, 2025, by email to info@icabt2025.org (Conference Secretariat).
论文作者请提交完整稿件(不超过六页),注明作者姓名、单位及通讯地址(包括通讯作者邮箱、传真及电话),请于2025年4月10日前通过电子邮件发送至 info@icabt2025.org(会议秘书处)。
The language of submission may be English or Chinese. All papers will be reviewed by the program committee based on content, presentation, and suitability for the conference.
论文语言可为中文或英文。所有论文将由大会程序委员会根据内容、表达及会议适配性进行评审。
Manuscripts must be prepared in MS Word or LaTeX format (A4, single space; Songti, 10 points if in Chinese, or Times New Roman, 12 points if in English).
论文请以 MS Word 或 LaTeX 格式提交(A4纸、单倍行距;中文宋体10号,英文Times New Roman 12号)。
More detailed information will be available on the web page:
更多详细信息请见会议网站:
http://www.icabt2025.org
Organizing Institution
Jilin University, China
Organizing Committee
Chair
Miao Lu, Jilin University, China
Committee
Baisong Qing, Jilin University, China
Jinlei Gao, Jilin University, China
Qianxing Wang, Jilin University, China
Xiunan Zhang, Jilin University, China
Zhijian Bai, Jilin University, China
Contact Information
Conference Secretariat:
International Conference on Advanced Battery Technologies (ICABT 2025)
国际先进电池技术学术会议(ICABT 2025)
Email / 邮箱: info@icabt2025.org
Tel / 电话: (+86) ??????
Fax / 传真: (+86) ??????
Opening Speech
Distinguished Delegates and Guests, Ladies and Gentlemen,
Good morning! I am 卢淼 from Jilin University, China. It is a great pleasure for me to serve as the chair of this session. On behalf of the Organizing Committee of the International Conference on Advanced Battery Technologies (ICABT 2025), I would like to declare the opening of this session.
This year’s conference is themed “Next-Generation Battery Technologies and Sustainable Energy Systems.”
The theme reflects our shared commitment to advancing battery innovation, enhancing energy efficiency, and addressing the urgent global challenge of sustainable development.
As energy systems rapidly evolve, breakthroughs in battery materials, design, and integration will play a crucial role in enabling the transition to clean, renewable energy and a carbon-neutral future.
We are honored to have with us today many distinguished scientists, engineers, and researchers from all over the world, who are at the forefront of battery research and sustainable energy innovation. Their contributions continue to shape the future of clean energy technologies and global sustainability.
Let me introduce our first speaker — Ms. 张秀楠 from Jilin University, China. Ms. Zhang has been actively engaged in research on solid-state batteries and high-performance energy storage materials. Her work focuses on the design of novel interfaces and the improvement of battery safety and efficiency.
Ms. 张秀楠 will present a talk entitled “Recent Advances in Solid-State Battery Technologies.”
Please join me in welcoming Ms. 张秀楠!
大家早上好!我是来自中国吉林大学的卢淼。非常荣幸能够担任本次会议的主持人。谨代表国际先进电池技术学术会议(ICABT 2025)组委会,宣布本次会议正式开幕。
今年会议的主题是“下一代电池技术与可持续能源系统”。
这一主题体现了我们共同致力于推动电池创新、提升能源效率,并积极应对全球可持续发展的紧迫挑战的决心。
随着能源系统的快速演进,电池材料、设计与集成领域的突破,将在实现清洁、可再生能源转型与碳中和未来的进程中发挥关键作用。
我们非常荣幸地邀请到来自世界各地的杰出科学家、工程师和研究人员,他们都活跃在电池研究与可持续能源创新的前沿。他们的杰出贡献正在持续塑造清洁能源技术的未来,并推动全球可持续发展。
下面,我很高兴地介绍今天的第一位报告人——来自中国吉林大学的张秀楠女士。
张女士长期从事固态电池与高性能储能材料研究,主要关注新型界面设计以及电池安全性与能效的提升。
她今天的报告题目是:《先进固态电池技术的最新进展》。
让我们以热烈的掌声欢迎张秀楠女士!
Presentation
Distinguished Delegates, Fellow Colleagues, Ladies and Gentlemen, 尊敬的各位代表、各位同仁、女士们、先生们:
Good morning! First, I would like to thank the Chair for the kind introduction. I am very glad to have this opportunity to share with you our recent research and views on the development of solid-state batteries. I would like to divide my presentation into two parts. 大家上午好!首先,我要感谢主席的盛情介绍。我非常高兴有这个机会与大家分享我们关于固态电池发展的最新研究和观点。我想将我的报告分为两个部分。
In the first part, I will talk about sulfide-based solid-state batteries. 在第一部分,我将重点介绍硫化物固态电池。
As you know, energy storage is a critical component for the widespread adoption of clean energy technologies. The current benchmark for safety and cost in the market is the Lithium Iron Phosphate (LFP) battery. While LFP is praised for its low cost, long cycle life, and inherent safety, its main limitation is low energy density, which restricts the driving range and increases the weight of electric vehicles. 众所周知,储能技术是清洁能源广泛应用的关键组成部分。目前市场上安全性和成本的基准是磷酸铁锂(LFP)电池。LFP以其低成本、长寿命和本质安全而闻名,但其主要限制是能量密度较低,这限制了电动汽车的续航里程并增加了重量。
Sulfide solid-state electrolytes are viewed as the high-performance solution to LFP’s energy density challenge. They promise significantly higher energy density, allowing for lighter battery packs and longer driving ranges, and the potential for very fast charging compared to LFP. However, sulfide electrolytes are highly sensitive to moisture and air, making manufacturing complex and costly today. Current research focuses on developing air-stable sulfide electrolytes and optimizing low-cost fabrication techniques. Several companies and research institutes, including Toyota, Samsung, and Solid Power, are actively working to advance these materials toward practical applications. 硫化物固态电解质被视为解决LFP能量密度挑战的高性能解决方案。与LFP相比,它们承诺显着更高的能量密度,从而实现更轻的电池组和更长的续航里程,并具有极快的充电潜力。然而,硫化物电解质目前对湿气和空气高度敏感,使得制造过程复杂且成本高昂。目前的研究重点是开发耐空气的硫化物电解质,并优化低成本的制造技术。包括丰田、三星和Solid Power在内的多家公司和研究机构正在积极努力,推动这些材料走向实际应用。
The second part is related to oxide-based solid-state batteries. 第二部分是关于氧化物固态电池。
Oxide electrolytes, such as garnet-type materials, are highly chemically stable and safe, even more so than LFP, making them promising for long-term and high-temperature operation. Although their potential energy density is slightly lower than that of sulfides, they are inherently non-flammable and compatible with lithium metal, offering a powerful combination of safety and high performance. 氧化物电解质,如石榴石型材料,具有极高的化学稳定性和安全性,甚至超过LFP,这使它们有望应用于长期和高温操作。虽然它们的潜在能量密度略低于硫化物,但它们本质上是不可燃的,并与锂金属兼容,提供了安全性和高性能的强大结合。
The main challenges with oxide electrolytes lie in their brittleness and poor interfacial contact. Their hard, ceramic-like nature makes it difficult to ensure every solid layer in the battery is perfectly connected, which limits performance. Current research focuses on low-temperature densification techniques and interfacial buffer layers to reduce interfacial impedance. Companies and institutions including QuantumScape, Honda, and Fraunhofer IKTS have developed lab-scale and medium-scale cells based on oxide electrolytes, providing a foundation for future automotive and stationary energy storage applications. 氧化物电解质的主要挑战在于它们的脆性和较差的界面接触。它们坚硬的、类似陶瓷的性质使得确保电池中每个固体层都完美连接变得困难,从而限制了性能。目前的研究重点是低温致密化技术和界面缓冲层,以减少界面阻抗。包括QuantumScape、本田和Fraunhofer IKTS在内的公司和机构已经开发出基于氧化物电解质的实验室级和中试电池,为未来的汽车和固定式储能应用奠定了基础。
To conclude, Distinguished Delegates, Fellow Colleagues, the development of both sulfide and oxide solid-state batteries is essential for advancing high-performance, safe, and sustainable energy storage technologies. Ongoing research and collaborative efforts will help overcome the current challenges, bringing these technologies closer to widespread practical use. 最后,尊敬的各位代表、各位同仁,硫化物和氧化物这两种固态电池技术的发展,对于推进兼具高性能、高安全性和可持续性的下一代储能技术至关重要。持续进行的研究和跨领域的合作将有助于克服当前的技术和制造挑战,使这些革命性技术更接近广泛的实际应用。
Thank you for your attention. 感谢大家的聆听。
Compliments
Thank you, Ms. 张秀楠. Your presentation is very convincing. From your presentation, we know that you distinguish two leading pathways, that is, sulfide-based batteries are targeting the ultimate goal of high energy density and fast charging, while oxide-based batteries prioritize inherent chemical safety and stability. If the research teams are right, the consequences could be profound, and engineers will find new ways of powering electric vehicles and grid storage in the new century. Your speech is indeed very useful, interesting and challengeable. Thank you.
Our conference has successfully concluded. Thank you all for your valuable contributions and active participation. May the ideas shared here inspire future collaboration and innovation.
Wishing everyone continued success — see you at the next conference!
谢谢张秀楠女士,您的报告非常令人信服。通过您的演讲,我们了解到您区分了两条主要的发展路径:硫化物基电池致力于实现高能量密度和快速充电的最终目标,而氧化物基电池则更加注重固有的化学安全性和稳定性。如果研究团队的方向正确,其影响将是深远的,工程师们将在新世纪找到为电动汽车和电网储能提供动力的新途径。您的报告确实非常有价值、有趣且富有挑战性。谢谢您。
本次会议圆满结束。衷心感谢各位的积极参与和宝贵贡献。愿本次会议分享的思想与成果,能够激发未来的合作与创新。
祝大家事业顺利,再会于下一次会议!