S1: Frontiers in Advanced Structural Ceramics and composites: From Daily Use to Extreme Heat

Modern structural ceramics and composites are engineering marvels that thrive in both ordinary and extreme conditions. At room temperature, these materials are becoming indispensable in the industries for semiconductor, healthcare, cutting tools etc. When temperatures soar beyond 1,500°C, such as in jet engines or spacecraft heat shields, advanced ceramics truly shine. New ultra-high-temperature ceramics (UHTCs) like ZrB2 composites can withstand blistering heat while fending off oxidation-a critical feature for reusable rockets. Scientists are also mimicking nature to boost performance: nacre-inspired ceramic-based laminates, layered like seashells, combine strength and flexibility to avoid sudden fractures under stress. For thermal insulation, "graded" ceramic coatings 3D-printed with microscopic cooling channels are protecting turbine blades, doubling their lifespan under extreme thermal cycling. In composites, next-generation ceramic matrix composites (CMCs), such as SiC/SiC systems with tailored fiber-matrix interfaces, achieve unprecedented thermomechanical performance through advanced coating technologies like rare-earth oxide layers. Additive manufacturing now allows intricate geometries with graded microstructures, optimizing heat dissipation and load distribution in turbine blades and hypersonic vehicle components.
We are delighted to announce the Session on Frontiers in Advanced Structural Ceramics and composites: From Daily Use to Extreme Heat as part of the upcoming CICC-14 conference. This session aims to provide a platform for researchers, scientists, and engineers to present and discuss the latest advancements, challenges, and innovations in the field of all kinds of structural ceramics and composites.

Session Scope & Themes
This session will spotlight cutting-edge innovations across four critical domains:
1.Ubiquitous Engineering Solutions
Breakthroughs in room-temperature applications (semiconductor manufacturing, biomedical implants, precision cutting tools) leveraging ceramics wear resistance, biocompatibility, and chemical stability.
2.Ultra-High-Temperature Frontiers
Advances in ultra-high-temperature ceramics (UHTCs) for aerospace thermal protection, reusable rocket nozzles, and hypersonic vehicle shielding, emphasizing oxidation resistance beyond 2,000°C.
3.Bioinspired & Additively Engineered Architectures
Nature-mimetic designs (nacre-like laminates, hierarchical microstructures) and 3D-printed graded coatings with embedded cooling channels, revolutionizing thermal management in turbine blades and nuclear reactors.
4.Next-Generation Composites
Ceramic matrix composites (CMCs) with engineered fiber-matrix interfaces (SiC/SiC, oxide-Oxide systems), rare-earth oxide coatings, and AI-optimized additive manufacturing for hypersonic propulsion and energy systems.

Organizers: 
Ji Zou, Wuhan University of Technology, China 
William G, Missouri University of Science and Technology, USA
Jon Binner, University of Birmingham, UK
Bai Cui, University of Nebraska-Lincoln, USA (to be confirmed)
Laura Silvestroni, Institute of Science and Technology of Ceramics-CNR, Italy
Guanghua Liu, Tsinghua University, China
Qiaodan Hu, Shanghai Jiaotong University, China
Fang He, Tianjin University, China
Kan Zhang, Jilin University, China
Yongsheng Liu, Northwestern Polytechnical University, China
Yujin Wang, Harbin Institute of Technology, China

Point of Contact:
Prof Ji Zou Wuhan University of Technology, ji.zou@whut.edu.cn

S2:Nano-laminated Carbides, Nitrides and Borides and Their 2D Counterparts (MAX/MAB phases and MXenes/MBenes)

Ternary nano-laminated carbides and nitrides are generally named as MAX phases, where M represents a transition metal, A is an A-group element, and X denotes carbon and/or nitrogen. Ternary borides with similar laminated structure are named as MAB phases. These materials exhibit a unique combination of metallic and ceramic properties, such as high electrical and thermal conductivity, excellent mechanical strength, and resistance to high temperatures, which can have diverse potential applications. By introducing various elements into the MAX phase structure, solid solutions can be formed, allowing for the fine-tuning of material properties. Recent studies have successfully synthesized numerous MAX phase solid solutions, further expanding the diversity of this material family.
In recent years, researchers have discovered that selective removal of certain atomic layers from MAX phases can yield two-dimensional materials known as MXenes. Despite their relatively recent discovery, MXenes have garnered significant attention due to their outstanding performance, surface functionalization capabilities, and tunable properties. They hold potential applications in energy storage, catalysis, lubrication, electromagnetic interference shielding, sensors, and water purification.
This symposium will focus on the latest advancements in the design, processing, and understanding of structure-property relationships of these novel nano-laminated compounds in both their two-dimensional and three-dimensional forms. Topics of interest include their thermal, electrical, optoelectronic, solid lubrication, mechanical properties, oxidation resistance, stability, and potential applications. We also welcome exploratory research on related areas.
We cordially invite experts and scholars engaged in research on MAX and MAB phases and their 2D counterparts of MXenes and MBenes to join us in discussing the latest developments and future applications of these cutting-edge materials.

The symposium will delve into the following specialized topics:
1. Design and Synthesis of Novel MAX, MAB, MXenes, and MBenes: Innovative approaches to creating new compositions and structures.
2. Microstructure and properties: Investigations into the internal architectures and long-term durability of these materials, resistance to oxidation and corrosion.
3. Intrinsic Properties: Detailed studies on thermal, electrical, mechanical, optical and chemical characteristics.
4. Composite Fabrication and Performance: Development and assessment of composites incorporating these phases.
5. Applications: Exploration of current and potential uses across various industries.

Organizers:
Yanchun Zhou, Zhengzhou University
Surojit Gupta, University of North Dakota, USA
Chong Min Koo, Sungkyunkwan University, Republic of Korea
Aiguo Zhou, Henan Polytechnic University
Chunfeng Hu, Southwest Jiaotong University
Shibo Li, Beijing Jiaotong University
Yuelei Bai, Harbin Institute of Technology
Peigei Zhang, Southeast Univeristy
Kun Liang, Ningbo Institute of Materials Technology & Engineering, CAS
Yi Liu, Shaanxi University of Technology

Point of Contact:
Aiguo Zhou, Henan Polytechnic University, zhouag@hpu.edu.cn

S3. Polymer-Derived Ceramics

Polymer-derived ceramics (PDCs), which are synthesized by decomposition of preceramic polymers through chemical and/or heat treatments or non-thermal methods, have attracted great attention for their superior thermal-mechanical properties and multi-functionalities in high temperature & harsh environments leading to a broad range of applications going from civil to military fields. As examples, Li-ion batteries, MEMS/micro sensors, ceramic fibers and composites can be prepared due to the flexible near-net shape fabrication capabilities of the starting polymeric precursors (photolithography, microcasting, 3D printing, foaming, fiber drawing,…). Therefore, understanding the composition-structure-property relationships, developing innovative novel forming techniques producing ceramics with improved properties and performance could promote PDCs going from laboratory to factory and explore a wider range of applications.

The symposium will address the latest developments in PDCs, from polymeric precursor synthesis to structure-composition design and characterization, from advanced polymer-to-ceramic conversion techniques via innovative shaping methods and novel properties to engineering applications. Particular emphasis will be placed on structural and functional properties of PDCs for applications in high temperature and harsh environments, in energy and environmental sectors. Detailed knowledge of composition-structure-property correlation of PDCs as well as developments in advanced processing methods will provide both, fundamental scientific knowledge and engineering paths for industrial applications of PDCs.

1. Design and synthesis of novel preceramic polymers

2. Microstructure characterization and modeling of polymer-derived ceramics

3. Advanced polymer-to-ceramic conversion methods and shaping techniques

4. Functional properties and devices

5. Structural properties and composites

6. Porous polymer-derived ceramics and applications

7. Polymer-derived ceramic fibers and coatings

8. Polymer-derived ceramics for clean energy applications

9. Polymer-derived ceramics for structural and functional applications

Zhaoju Yu (Points of Contact), Xiamen University, China. zhaojuyu@xmu.edu.cn

Ralf Riedel (Points of Contact), TU Darmstadt, Germany. ralf.riedel@tu-darmstadt.de

Paolo Colombo, University of Padova, Italy

Philippe Miele, Universite de Montpellier, France

Samuel Bernard, IRCER Limoges, France

Günter Motz, University of Bayreuth, Germany

Yuji Iwamoto, Nagoya Institute of Technology, Japan

Yoshi Sugahara, Waseda University, Japan

Dong-Pyo Kim, POSTECH, Korea

Gurpreet Singh,Kansas State University,USA

Jie Kong, Northwestern Polytechnical University, China

Gang Shao, Zhengzhou University, China

Xingang Luan, Northwestern Polytechnical University, China

Qingbo Wen, Central South University, China

Yujie Song, NIMTE, China

S4: Advances in Ceramic Matrix Composites

Ceramic Matrix Composites (CMCs) are endowed with excellent combination properties, which make them leading candidates for extremely environmental applications, such as aerospace, nuclear industries, transportation, optical systems and chemical industries, etc. In the past few years, extensive research has been conducted and significant progress has been made in the selection and design, fabrication and processing, properties and performance evaluation, and applications etc. pertaining to CMCs. However, challenges remain with regard to increasing the penetration degree of CMCs into the marketplace, which depends on consistent development of CMCs with improved performance, thus providing solutions for engineering conditions with specific requirements.
The purpose of this symposium is to provide a broader forum for scientists and engineers from all over the world to present and discuss their recent advances and developments in the areas of design, processing, characterization, and applications of Ceramic Matrix Composites. This symposium will focus on the fundamental issues and engineering application challenges to advance our understanding and the utilization of CMCs.

Focused topics:
(1) Fiber, preform, interface/interphase, matrix and coating of CMCs
(2) Innovative processing routes and methods for CMCs
(3) Processing-microstructure-mechanical properties correlation of CMCs
(4) Corrosion, oxidation, ablation and irradiation behaviors of CMCs
(5) Damage evaluations and failure mechanisms of CMCs
(6) Advanced modeling & simulation for CMCs

Co-organizers:
Guo-Jun Zhang, Donghua University, Shanghai, China
William G. (Bill) Fahrenholtz, Missouri University of Science and Technology, USA
Frederic Tullio Monteverde, CNR, Institute of Science and Technology of Ceramics-CNR, Italy
Ralf Riedel, Technical University of Darmstadt,Germany
Sea-Hoon Lee, Korea Institute of Materials Science, Korea
Xinghong Zhang, Harbin Institute of Technology, Harbin, China
Xiang Xiong, Central South University, Changsha, China
Yongsheng Liu, Northwestern Polytechnical University, Xian, China
Qingsong Ma, National University of Defense Technology, Changsha, China
De-Wei Ni, Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai, China
Yi Zeng, Central South University, Changsha, China
Duan Li, National University of Defense Technology Changsha, China
Ji-Xuan Liu, Donghua University, Shanghai, China
Yuan Cheng, Harbin Institute of Technology, Harbin, China

Point of Contact:
Guo-Jun Zhang
Donghua University, Shanghai, China
Tel: 021-67874093
E-mail: gjzhang@dhu.edu.cn
De-Wei Ni
Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai, China
Tel: 021-69906033
E-mail: deweini@mail.sic.ac.cn

S5: Porous Ceramics and Their Applications in Energy and Environment

Porous ceramics with different pore size and pore distribution can be utilized in wide range of energy and environmental applications including membranes, filtrations, insulations, catalysts, catalyst supports, absorbers, sensors and light weight structural components, often together with hierarchical pore structures. To fully take advantage of the vast potential of porous ceramics, oxide and non-oxides types, the manufacturing routes, which can be coupled with numerical approaches, used to design such components play a key role. Therefore, this symposium will include the recent progresses in the design, characterization, properties and modeling of porous ceramic, carbon, glass and glass-ceramic components. These materials contain pore sizes from the nanometers to millimeters, and can have textured to random porosity or hierarchical porosity and are based on various pore architectures, such as foams, honeycombs, fiber networks, bio-inspired structures. This symposium will be the ideal showcase for the recent research interests and activities, covering the areas from inorganic chemistry to material science, modeling and simulation, artificial intelligence (AI) for porous ceramics. Engineering applications can include energy and environmental related technologies such as energy generating, energy conversion and/or saving, environmental protection technologies, sensors, catalytic supports, gas filtration, application engineering and mass separation.

1.Novel processing technologies of porous ceramics

2.Microstructural and morphological control of porous ceramics

3.Additive manufacturing of porous ceramics

4.Ceramic membranes

5.Micro-porous and meso-porous ceramics

6.Characterization, simulation, and modeling of porous ceramics

7.Engineering applications of porous ceramics for environmental protection and energy related applications

8.Porous ceramics for thermal management, functional, biological, and lightweight structural applications

9.Computational Techniques, Machine Learning (ML) and Artificial Intelligence (AI) for Porous Ceramics

Prof. Yu-Ping Zeng, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China, yuping-zeng@mail.sic.ac.cn

Prof. Chan-An Wang, School of Materials Science And Engineering, Tsinghua University, wangca@tsinghua.edu.cn

Dr. Manabu Fukushima, National Institute of Advanced Industrial Science and Technology (AIST), Japan, manabu-fukushima@aist.go.jp

Prof. Paolo Colombo, Università di Padova, Italy, paolo.colombo@unipd.it

Prof. Young-Wook Kim, University of Seoul, Republic of Korea, ywkim@uos.ac.kr

Prof. Hongjie Wang,  Xian Jiaotong University, China, yang155@mail.xjtu.edu.cn

Dr. Tobias Fey, Universität Erlangen-Nürnberg, Germany, tobias.fey@fau.de

Dr. Dongxu Yao, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China, dongxyao@mail.sic.ac.cn

Prof. In-Hyuck Song, Engineering Ceramics Department, Korea Institute of Materials Science, sih1654@kims.re.kr

Prof. Haijun Zhang, Wuhan University of Science and Technology, China, zhanghaijun@wust.edu.cn

S6: Advanced Refractories and Traditional Ceramics

Advanced Refractories and Traditional Ceramics, essential for high-temperature industrial applications such as metallurgy, energy, and construction, are evolving to meet demands for enhanced thermal resistance, durability, and environmental sustainability. Research highlights include the development of composites, lightweight materials, and eco-friendly refractories. This theme emphasizes the intersection of refractory and ceramic materials, exploring synergies in material design, processing techniques, and performance optimization. By fostering interdisciplinary collaboration, the theme aims to drive innovation and sustainable solutions for industrial and technological challenges.

Focused topics:
1.Refractories and Ceramics for High-temperature Equipments;
2.Sustainable and Eco-Friendly Refractories and Ceramics ;
3.Additive Manufacturing of Refractories and Ceramics;
4.Industrial Refractories for Harsh Environments;
5.Energy-Related Applications of Refractories and Ceramics;

Organizers:
Hailong Wang (zhengzhou University, China)
Yueming Li (Jingdezhen Ceramic University, China)
Yawei Li (Wuhan University of Science and Technology, China)
Gang Wang (Sinosteel Luoyang Inst. Refractories Res. Co., Ltd., China)
Juntong Huang (Nanchang Hangkong University, China)
Hongfeng Yin (Xian University of Architecture & Technology, China)
Jianfeng Zhu (Shangxi University of Science and Technology, China)
Xudong Luo (Liaoning University of Science and Technology, China)
Jingkun Yu (Northeastern University, China)
Xinhong Liu (Zhengzhou University, China)
Weidong Li（Shanghai Institute of Ceramics,Chinese academy of Science, China）
Jianqing Wu（South China University of Technology, China）

Point of Contact:
Hailong Wang, Zhengzhou University, email: 119whl@zzu.edu.cn
Yueming Li, Jingdezhen Ceramic University, email: lym6329@163.com

S7: Transparent ceramics and luminescent materials

Transparent ceramics have a wide range of practical and emerging applications in the fields of high discharge lighting; windows for UV to IR detection, and for visible protection. Luminescent materials in the form of powders or bulk are widely used in solid-state lasers, scintillators, solid-state lighting, emissive displays,sensing and bioimaging. The aim of this symposium is to provide a platform to exchange research ideas about the state-of-the-art of the preparation, microstructure, properties and applications of transparent ceramics and luminescent materials.

Following topics will be included but not limited in this symposium:
1.Fabrication technologies for powders and transparent ceramics
2.Spectroscopic properties of luminescent materials
3.Transparent ceramics for lasers, X-CT, Magnet-Opt and Electro-Opt and fluorescent applications
4.Transparent ceramics for window, dome, and armor applications
5.Phosphors for solid-state lighting
6.Up-conversion phosphors and their applications
7.Quantum dots and emissive displays
8.Near-infrared phosphors and their applications
9.Theory and computations of phosphors

Invited/Keynote Speakers (Transparent ceramics)
1. Akio Ikesue (Keynote), World lab Company, Japan
2. Jian Zhang (Keynote) Shanghai Institute of Ceramics, CAS
3. Hao Wang (Keynote) Wuhan University of Technology
3. Xiaodong Li,Northeast University
4. Jianqi Qi,Sichuan University, China
5. Jianqiang Li,Beijing University of Science and Technology
6. Jiang Li,Shanghai Institute of Ceramics, CAS
7. Ying Shi,Shanghai University, China
8. Le Zhang,Jiangsu Normal University, China
9. Youfu Zhou,Fujian Institute of Research on the Structure of Matter, CAS
10 Yinchun Shan,Dalian Maritime University
11 Yiquan Wu (Alfred University)
12 Jiguang Li,National Institute for Materials Science,Japan

Invited/Keynote Speakers (Luminescent materials)
1.Rong-Jun Xie (Keynote), Xiamen Univ.
2.Yuansheng Wang (Keynote), Fujian Institute of Matter and Structure, CAS
3.Yongfu Liu (invited), Ningbo Institute of Engineering and Technology Materials
4. Jing Wang (invited), Sun Yat-sen University
5. Jiahua Zhang (Keynote),Changchun Institute of Optics, Fine Mechanics and Physics
6. Shuxing Li (invited), Xiamen Univ.
7. Qiangqiang Zhu (invited), China Jiliang Univ.
8. Zhiguo Xia (Keynote), South China Univ. of Science and Techology
9. Yizheng Jin (Keynote), Zhejiang Univ.
10. Tongtong Xuan (invited), Xiamen Univ.
11. Haizheng Zhong (keynote), Beijing Univ. of Science and Technology
12. Weidong Xiang (invited), Wenzhou Univ.
13. Dawei Di (Keynote), Zhejiang University
14. Dengfeng Peng (invited), Shenzhen University
15. Tingzhu Wu (invited), Xiamen University
16. Yiming Wu (invited), Xiamen University
17. Yixi Zhuang (invited), Xiamen University
18. Zhanhua Wei (keynote), Huaqiao University
19. Zhenwen Yang (invited), Kunming University of Technology
20. Juncheng Zhang (invited), Shandong University

Organizers:
Shiwei Wang, Shanghai Institute for Ceramics, CAS
Rong-Jun Xie, Xiamen University
Yiquan Wu, Alfred University, USA
Jiang Li, Shanghai Institute for Ceramics
Hao Wang Wuhan University of Technology
Le Wang, China Jiliang University
W. B. Im, Hanyang University
Jiguang Li, National Institute for Materials Science, Japan

Point of Contact
Dan HAN, Shanghai Institute of Ceramics, CAS

S8: Novel Ceramic Coatings and Technology

Research and development in the field of novel ceramic coatings systems is a key to current and future technologies. This symposium focuses on the latest advances in ceramic - coating technologies, which can give surfaces new or markedly improved functions onto materials surfaces in terms of physical, mechanical, thermal, chemical, optical, electrical, electronic, magnetic properties, extending the important and emerging applications in the fields of gas turbine, aerospace, reusable spacecraft or hypersonic vehicles, defense protection, ships, automobiles, electronic devices, mechanical parts, renewable energy, etc. Simultaneously, new ceramic - coating, surface nanoengineering, innovative processing technologies, advanced characterization methods, multi - scale modeling and experimental validations are particularly emphasized. This symposium will identify current key issues, effective approaches, and future outlook for ceramic - coating technologies and applications through comprehensive discussion on the following proposed topics.

Focused topics:
1.Thermal/environmental barrier coatings for CMC, intermetallics, and superalloys
2.Ceramic coatings for protection against high - temperature, oxidation, CMAS, corrosion, diffusion, wear, erosion, fretting, tribological loadings, flame
3.Processing of ceramic - derived coatings (Thermal spray, cold spray, polymer - derived/suspension/solution precursor spray, aerosol deposition, sintering, halide activated pack cementation (HAPC), PVD, CVD, etc.)
4.Wet chemical and electrochemical processes of ceramic coatings (Sol - gel coating, anodization, microarc oxidation (MAO or PEO), chemical conversion coating, etc.)
5.Ceramic coatings for new functional applications - multi - functional, composite/hybrid, graded, nanostructured and multilayers coatings
6.Interface phenomena, adhesion, and other fundamentals of ceramic coatings
7.Technical issues and potential solutions of surface - related properties and processes in industries
8.Next generation production methods for ceramic coatings
9.Multi - scale modeling of ceramic coating properties and life predictions
10.Ceramic coatings database and artificial intelligence - based approach
11.Advanced destructive and non - destructive evaluation methodologies for ceramic coatings

Organizers:
Guanjun Yang, Xian Jiaotong University, China, ygj@xjtu.edu.cn
Chunlei Wan, Tsinghua University, China, wancl@mail.tsinghua.edu.cn
Zhixue Qu, Beijing University of Technology, China, quzhixue@bjut.edu.cn
Rong Tu, Wuhan University of Technology, China, turong@whut.edu.cn
Zhen Wu, Institute of Metal Research, Chinese Academy of Sciences, China, zwu@imr.ac.cn

Contact:
Meijun Liu, Xian Jiaotong University, China, liumjun@xjtu.edu.cn

S9: Advanced powder processing and sintering

Originated from traditional firing processes for structural and functional components, modern sintering technology arises as an advanced and essential tool for a variety of applications. In recent years, two trends have been witnessed in this old and new research field. One is the perusing of high efficiency in sintering, for which external fields such as electricity or stress are usually exploited. The other one is realization of sintering at low temperature, for which reaction process during densification are typically involved.
Accordingly, novel technologies such as flash sintering, cold sintering and bioinspired densification (mineralization) are under rapid development in ceramic community. Moreover, as the properties of raw powders significantly affect sintering kinetics and quality, advances in powder processing is of great interest from both scientific and industrial point of view. Finally, the novel sintering processing could result in distinct microstructure of ceramics, and thus directly affects the mechanical and functional properties.
This symposium seeks to provide a platform for global researchers to share the latest developments in sintering science and technology, as well as microstructural evolution for powder-based materials. The topics will include but not limit to fundamentals of sintering, development of novel sintering techniques, sintering-enabled novel properties, and industrial applications. Special attention will also be paid to the design of complex and multifunctional materials with specific microstructures and properties.

Focused topics:
1.Powder processing for sintering
2.Fundamentals of sintering
3.Modeling and simulation of sintering
4.Novel sintering techniques
5.Sintering in additive manufacturing
6.Sintering for industrial applications

Organizers:
Yuchi Fan (Donghua University)
Yanhao Dong (Tsinghua University)
Jing Guo (Xian Jiaotong University)
Jiang Li (Shanghai Institute of Ceramics, CAS)
Jinling Liu (Southwest Jiaotong University)
Zhulin Huang (Institute of Solid State Physics, CAS)
Wei Ji (Whuhan University of Technology)
Wei Luo (Donghua University)
Rujie He (Beijing Institute of Technology)

Point of Contact:
Yuchi Fan (Donghua University) Email: yuchifan@dhu.edu.cn
Yanhao Dong (Tsinghua University) Email: dongyanhao@tsinghua.edu.cn

S11: Thermoelectric Materials and Devices

Thermoelectric materials and devices remain a pivotal challenge in science and technology, driven by advances in theory, materials design, measurements, modules/devices, and most recently, machine learning. This symposium explores cutting-edge developments in heat-to-electricity conversion, emphasizing novel materials, advanced characterization, modules, and device integration. It highlights innovative approaches and ideas from the theoretical studies on electrical and thermal transport, fabrications of novel materials, all the way to the system and industrial applications.

1. Thermoelectric Materials

2. Theory and Machine Learning

3. New Transport Phenomena

4. Measurements & Characterization

5. Thermoelectric Modules

6. Systems & Industrial Applications

Wenqing Zhang (Point of Contact), Southern University of Science and Technology, zhangwq@sustech.edu.cn

Xun Shi, Shanghai Institute of Ceramics, Chinese Academy of Sciences

Lei Miao, Guangxi University

Jiong Yang, Shanghai University

Ting Zhang, Institute of Engineering Thermophysics, Chinese Academy of Sciences

Michitaka OHTAKI, Kyushu University

Franck Gascoin, CRISMAT Laboratory

Chenguang Fu, Zhejiang University

Zhigang Chen, Queensland University of Technology

S12: Ferroelectric and Piezoelectric Ceramics

1.Fundamentals of ferroelectrics and piezoelectrics

2.High-performance lead-free ferroelectric/piezoelectric ceramics

3.Ferroelectric/piezoelectric films and composites

4.Ferroelectric/piezoelectric devices

5.Emerging applications of ferroelectric and piezoelectric materials

6.New Frontiers in ferroelectric and piezoelectric researches;

1.Jianguo Zhu (Point of Contact), Sichuan University, China, nic0400@scu.edu.cn

2.Yiping Guo (Point of Contact), Shanghai Jiatong University, China, ypguo@sjtu.edu.cn

3.Shujun Zhang, University of Wollongong, Australia

4.Tomoaki Karaki, Toyama Prefecture University, Japan

5.Jiagang Wu, Sichuan University, China

6.Haibo Zhang, Huazhong University of Science and Technology

7.Ke Wang, Tsinghua University, China

8.Jiwei Zhai, Tongji University, China

9.Dou Zhang, South China University

10.Bo-Ping Zhang, University of Science and Technology Beijing, China

11.Satoshi Wada, University of Yamanashi, Japan (to be confirmed), Japan

12.Haosu Luo, Shanghai Institute of Ceramics, China

13. Jing-Feng Li, Tsinghua University, China, jingfeng@mail.tsinghua.edu.cn

1.Jing-Feng Li, Tsinghua University, China

2.Shujun Zhang, University of Wollongong, Australia

3.Dou Zhang, South China University

4.Jae-Ho Jeon, Korea Institute of Materials Science, Korea

5.Satoshi Wada, University of Yamanashi, Japan

6.Haosu Luo, Shanghai Institute of Ceramics, China

7.Zuoguang Ye, Simon Fraser University, Canada

8.Yun Liu, University of Sydney, Australia

9.Chul Hong Park, Pusan National University, Korean

10.Xiaoning Jiang, North Carolina State University, USA

11.Xiaoshi Qian, Shanghai Jiaotong University, China

12.Xiangming Chen, Zhejiang University,China

13.Xiaoguang Li, University of Science and Technology of China

14.Fei Li, Xian Jiaotong University, China

15.He Tian, Zhejiang University, China

1.Yohachi Yamashita, Toyama Prefectural University, Japan

2.Bo-Ping Zhang, University of Science and Technology Beijing, China

3.Tomoaki Karaki, Toyama Prefecture University, Japan

4.Jiwei Zhai, Tongji University, China

5.Dae Yong JEONG, Inha University, Korean

6.Dengfeng Peng, Shenzhen University, China

7.John G. Fisher, Chonnam National University, Korean

8.Sheng-Guo Lu,Guangdong University of Technology, China

9.Jiagang Wu, Sichuan University, China

10.Haibo Zhang, Huazhong University of Science and Technology, China

11. Soonil Lee, Changwon National University, Korean

12.Ho-Yong Lee, Sun Moon University, Korean

13.Jianguo Zhu, Sichuan University, China

14.Yiping Guo, Shanghai Jiaotong University

15.Ke Wang, Tsinghua University, China

16.Wook Jo, Ulsan National Institute of Science and Technology, Korean

17.Yang Bai, University of Science and Technology Beijing, China

18.Guorong Li, Shanghai Institute of Ceramics, China

19.Xiaohui Wang, Tsinghua University, China

20.Yunfei Chang, Harbin Institute of Technology, China

S13: Ferroelectric and Multiferroic thin films

Ferroelectric and multiferroic thin films play important roles in modern microelectronic devices, such as piezo-MEMS, electrical tunable devices, non-volatile memories, film capacitors and novel logic devices. With recent synergistic efforts from physicists, material scientists, chemists, and mechanical/electrical engineers, ferroelectric and multiferroic thin films are continuing to provide exciting opportunities for scientific research and technological advancements.

Focused topics
1. Fundamentals of ferroelectric and multiferroic films (physics, mechanics, chemistry, modeling and simulation)
2. Ferroelectric-film based devices (memories, film capacitors, piezo-MEMS, electrocalorics/pyroelectric devices, etc.)
3. Multiferroic-film based devices
4. New Frontiers in single-phase ferroelectric and multiferroic films
5. Magnetoelectric and multiferroic thin films and nanostructures

Organizers:
Jun Ouyang (Qilu University of Technology)
Jinxing Zhang (Beijing Normal University)
Houbing Huang (Beijing Institute of Technology)
Chengliang Lu (Huazhong University of Science and Technology)
Jing Ma (Tsinghua University)
Lisha Liu (Nanjing University of Science and Technology)

Point of Contact:
Jun Ouyang, Qilu University of Technology, ouyangjun@qlu.edu.cn
Jing Ma, Tsinghua University, ma-jing@tsinghua.edu.cn

S14:Advanced Dielectrics for Energy Storage Applications

Dielectric capacitors, based on electric-field-induced polarization of dielectrics for energy storage, have attracted extensive attention worldwide in recent years, as they are essentially promising candidates in the areas including power electronics, high speed energy converting or buffering, back-up power sources, and hybrid electrical energy technologies. The dielectric material inside of a capacitor is critically responsible for its energy storage performance. The ongoing progress of capacitors requires the dielectrics to have some merits, e.g., high energy storage density and efficiency, good temperature stability, and long fatigue resistance, etc. Thanks to the continuous investment of researchers, great progresses have been achieved in recent years.
This symposium will address the latest progress of dielectric materials for energy storage applications, including discovery of new dielectric category (ferroelectrics, antiferroelectrics, relaxors, superparaelectrics, and a combination/mixture of them), development of novel structure, proposal of new designing concept, as well as the studies on various dimensions (bulk ceramic, film, and MLCC). The emerging methods for improving energy storage properties, from processing, characterization, to modeling and simulation are also included.

Focused topics:
1.New Ferroelectric/Antiferroelectric Materials for Energy Storage applications
2.Film/bulk/composite Ceramics for Energy Storage applications
3.MLCC for Energy Storage applications
4.Novel Processing Technologies of Dielectric Materials
5.Designing, Characterization, Modeling and Simulation of Dielectric Materials

Organizers:
Guorong Li, Shanghai Institute of Ceramics, CAS, China
Nengneng Luo, Guangxi University, China
Ruzhong Zuo, Hefei University Technology, China
Shujun Zhang, University of Wollongong, Australia
Xiaojie Lou, Xian Jiaotong University, China
Yang Shen, Tsinghua University, China
Fei Li, Xian Jiaotong University, China
Yu Huan, Jinan University, China
Jiangtao Zeng, Shanghai Institute of Ceramics, China
Gengshui Wang, Shanghai Institute of Ceramics, China
Jing-Feng Li, Tsinghua University, China
Xiaohui Wang, Tsinghua University, China
Dawei Wang, University of Sheffield, UK
Zhenxiang Cheng, Wollongong University, Australia
Haibo Zhang, Huazhong University of Science and Technology, China
Guangzu Zhang, Huazhong University of Science and Technology, China
Dou Zhang, South China University, China
Jungho Ryu, Yeungnam University, Republic of Korea
Barbara.Malic, Jožef Stefan Institute, Slovenia,
Zorica Branković, University of Belgrade, Serbia
He Qi, Hainan University, China

Point of Contact:
Nengneng Luo, Guangxi University, luonn1234@163.com

S15: Emerging Photovoltaic Materials and Devices

Photovoltaic materials and devices are driving transformative innovations in renewable energy technologies, offering unprecedented opportunities for high-efficiency, cost-effective, and sustainable solar energy conversion. Over the past decade, groundbreaking advancements in novel photovoltaic materials have reshaped the landscape of solar energy research, pushing the boundaries of efficiency, stability, and application versatility. This session will highlight the latest breakthroughs in emerging photovoltaic technologies, emphasizing interdisciplinary approaches to address challenges in materials design, device engineering, and scalability.

Focused Topics:
1.Perovskite Solar Cells: Advances in perovskite materials for enhanced stability, efficiency, and scalable manufacturing; hybrid perovskite systems and interface engineering.
2.Organic Solar Cells: Innovations in polymer and small-molecule photovoltaics, including flexible, lightweight designs and applications in wearable electronics.
3.Chalcogenide-based Solar Cells: Emerging chalcogenide-based materials for high-performance, stable thin-film photovoltaics.
4.Quantum Dot Solar Cells: Quantum-confined nanostructures, tunable bandgap engineering, and multiple exciton generation for next-generation photovoltaics.
5.Dye-Sensitized Solar Cells (DSSCs): Novel dye materials, redox mediators, and nanostructured electrodes for low-cost and transparent solar applications.
6.Tandem and Multi-Junction Architectures: Integration of complementary photovoltaic materials (e.g., perovskite/Si, perovskite/perovskite, perovskite/organic etc.) to surpass efficiency limits.
7.Novel Materials and Hybrid Systems: Exploration of 2D materials, carbon-based photovoltaics, bio-inspired designs, and organic-inorganic hybrids.
8.Device Engineering and Characterization: Advanced fabrication techniques, interfacial optimization, and in-situ/operando characterization methods.
9.Sustainability and Scalability: Eco-friendly material synthesis, recycling strategies, and pathways to industrial-scale production.

Organizers:
Hong Lin (Points of Contact)
School of Materials Science and Engineering
Tsinghua University, China
hong-lin@tsinghua.edu.cn
Xiaojing Hao（Points of Contact）
School of Photovoltaic and Renewable Energy Engineering
University of New South Wales, Australia
xj.hao@unsw.edu.au
Edgardo Saucedo（Points of Contact）
Universitat Politècnica de Catalunya, Spain
edgardo.saucedo@upc.edu
Lydia Helena Wong, Nanyang Technological University, Singapore, LydiaWong@ntu.edu.sg
Tsutomu Miyasaka, Toin University of Yokohama, Japan
Tingli Ma, Kyushu University, Japan
Wei Chen, Huazhong University of Science and Technology, China
Zhanhua Wei, Huaqiao University, China
Ying Xin, Nanjing University of Post and Telecommunication, China
Xinhua Zhong, South China Agricultural University, China
Zonghao Liu, Huazhong University of Science and Technology, China

Keynote Speakers:
Tsutomu Miyasaka, Toin University of Yokohama, Japan
Mohammad khaja Nazeeruddin, ?cole Polytechnique Fédérale de Lausanne, Switzerland
Xiaojing Hao, University of New South Wales, Australia
Baoming Xu, Southern University of Science and Technologh, China
Jingbi You, Chinese Akademy of Sciences, China

Invited Speakers:
Edgardo Saucedo, Universitat Politècnica de Catalunya, Spain
Feng Gao, Linkoping University, Sweden
Satoshi Uchida, The University of Tokyo, Japan
Tingli Ma, Kyushu University, Japan
Lydia Helena Wong, Nanyang Technological University, Singapore
Yi Hou, National University of Singapore, Singapore
Lianzhou Wang, University of Queensland, Australia
Heping Shen, Australia National University, Australia
Pavel A. Troshin, Zhengzhou Research Institute, Harbin Institute of Technology/ Federal Research Center for Problems of Chemical Physics and Medicinal Chemistry of RAS, Russia
Atsushi Wakamiya, Kyoto University, Japan
Shuaifeng Hu, Oxford University, UK
Yongzhen Wu, East China University of Science and Technology, China
Jianxian Xu, University of Science and Technology of China, China
Wei Chen, Huazhong University of Science and Technology, China
Zhanhua Wei, Huaqiao University, China
Ying Xin, Nanjing University of Post and Telecommunication, China
Xinhua Zhong, South China Agricultural University, China
Yingping Zou, Central South University, China
Zonghao Liu, Huazhong University of Science and Technology, China
Zhiping Wang, Wuhan University, China
Zhubing He, Southern University of Science and Technology, China
Dongqin Bi, Sun Yat-Sen University, China
Xin Li, Xiamen University, China
Feng Hao, University of Electronic Science and Technology of China, China
ShanShan Zhang, Xinjiang Technical lnstitute of Physics and Chemistry, Chinese Academy of Sciences, China
Luozheng Zhang, Yangzhou University, China
Wangnan Li, Hubei University of Arts and Science, China
Jianhua Han, Civil Aviation University of China

S16: High-Entropy Ceramics: Innovations in Design, Processing, and Applications for Extreme Environments

High-entropy ceramics, encompassing a diverse range of materials such as high-entropy oxides, carbides, borides, nitrides, silicides, carbonitrides, and borocarbonitrides, have emerged as a revolutionary class of materials with transformative potential in both structural and functional applications. These materials are characterized by their unique multi-component compositions, which impart exceptional mechanical, thermal, and functional properties, enabling them to thrive in extreme environments. For instance, high-entropy carbides and borides exhibit unparalleled hardness and oxidation resistance, making them ideal for cutting tools and thermal protection systems in aerospace applications, where temperatures can exceed 2,000°C. In energy storage, high-entropy oxides are being explored for their superior electrochemical performance in batteries and supercapacitors, offering enhanced stability and energy density. Meanwhile, high-entropy nitrides and carbonitrides are gaining attention for their exceptional wear resistance and thermal conductivity, making them suitable for advanced coatings and thermal management systems.
We are delighted to announce the Session on High-Entropy Ceramics: Innovations in Design, Processing, and Applications for Extreme Environments as part of the upcoming CICC-14 conference. This session will serve as a premier platform for researchers to showcase and discuss the latest advancements, challenges, and future directions in the field of high-entropy ceramics. It will delve into the design, modeling, processing, and applications of these materials, with a particular emphasis on their mechanical, thermal, and functional properties, applications in energy and environmental technologies, and transformative potential in aerospace, defense, and cutting-edge industries. technologies.

Session Scope & Themes
The core agenda of this session encompasses the following pivotal topics:
1.Design and Modeling of High-Entropy Ceramics
Novel design rules and computational modeling approaches for high-entropy ceramics, leveraging machine learning for high-throughput design and optimization to advance material discovery.
2.Advanced Processing Techniques
Advanced synthesis and processing techniques, address scalability and microstructure control through improved powder synthesis, sintering, and process optimization, overcoming phase segregation and density challenges to enhance high-entropy ceramics performance for extreme environments and advanced applications.
3.Mechanical, Thermal, and Functional Properties
Outstanding thermomechanical behavior, fracture toughness, wear resistance, and high-temperature stability for extreme environments, alongside unique electrical, magnetic, and optical properties, enabling multifunctional applications in advanced technologies.
4.High-Entropy Ceramics for Energy and Environmental Applications
Energy storage and conversion in batteries, supercapacitors, and fuel cells, providing thermal management through barrier coatings and insulation, and offering catalytic properties with environmental durability.
5.High-Entropy Ceramics in Aerospace, Defense, and Cutting-Edge Technologies
Ultra-high-temperature applications, mechanical performance enhancements, and extreme environment durability of high-entropy ceramics, leveraging oxidation resistance, thermal stability, and reliability to advance aerospace, defense, and nuclear technologies.
6.Future Directions, Challenges, and Industrial Adoption
Future directions in high-entropy ceramics focus on emerging compositional spaces, scalable synthesis, industrial integration, sustainability, advanced characterization, and collaborative innovation to address challenges in reliability, performance, and environmental impact while driving breakthroughs and commercialization across aerospace, energy, and defense sectors.

Organizers:
Yujin Wang, Harbin Institute of Technology, China
Yanchun Zhou, Zhengzhou University, China
Guo-Jun Zhang, Donghua University, China
W.G. Fahrenholtz, Missouri University of Science and Technology, USA
Jian Luo, University of California, San Diego, USA
Nita Dragoe, University Paris-Saclay, France
Hailong Wang, Zhengzhou University, China
Ji Zou, Wuhan University of Technology, Wuhan, China

Point of Contact:
Prof. Yujin Wang, Harbin Institute of Technology, wangyuj@hit.edu.cn

S17: Nanoscale characterizations of ceramic materials

The nanoscale properties of ceramics play a crucial role in their functional performance across a wide range of applications, including electronics, energy storage, and biomedical devices. The symposium will cover recent advancements in structure and composition analysis, as well as testing and analysis of mechanical, electrical, and chemical properties for ceramic materials. The rapid advancement of scanning probe microscopy (SPM) techniques has significantly enhanced the nanoscale characterization of ceramics, offering unprecedented insights into their multifunctional properties. Transmission electron microscopy (TEM) techniques provide the capability to observe atomic-scale features, such as grain boundaries, defects, and phase transitions, which are essential for understanding the behavior of ceramics in different environments. These various advanced microscopy techniques offer a comprehensive approach to studying intricate microstructural features in ceramics and composites, enabling a profound understanding of their structure-property relationships. Other advanced characterization methods also include (synchrotron) X-ray and neutron diffraction, imaging and spectroscopy, vibrational spectroscopy (IR/Raman), optical imaging and spectroscopy, and related tools, which further expand the ability to probe ceramic properties at multiple length scales.

This symposium will bring together researchers who utilize and develop advanced characterization techniques to investigate nanoscale phenomena in ceramics. Topics of interest include, but are not limited to:
1.The latest advancements in SPM-based methodologies for characterizing electric, piezoelectric, magnetic, thermal, and optical properties at the nanoscale.
2.Applications of SPM in uncovering the fundamental properties of ceramic materials.
3.Structure analysis by X-ray, neutron, synchrotron and electron diffraction such as X-ray microscopy, tomography and ptychography based on Bragg diffraction, transmission and fluorescence contrast.
4.Development and application of advanced TEM/STEM and 4D-STEM techniques for studying the atomic structure, electronic structure, defect analysis, and grain boundary behavior in ceramics.
5.In situ TEM to study dynamic processes in ceramics, such as phase transitions, crack formation, and ion diffusion.
6.Integration of multi-modal microscopy techniques, including SPM, TEM, and other characterization methods for comprehensive analysis of ceramic materials.
7.Theoretical modeling, atomic-scale simulation, and machine learning approaches that provide deeper insights into nanoscale characterizations of ceramics.

Organizers:
Prof. Tao Li, Xian Jiaotong University, China
Prof. Boyuan Huang, Southern University of Science and Technology, China
Prof. Xiahan Sang, Wuhan University of Technology, China
Prof. Qiang Zheng, National Center for Nanoscience and Technology CAS, China
Prof. Yunseok Kim, Sungkyunkwan University, Korea
Prof. Qian Li, Tsinghua University, China

Point of Contact:
Qian Li, Tsinghua University, qianli_mse@tsinghua.edu.cn

S18: Microwave Dielectric Ceramics and applications

Microwave dielectric ceramics play a key role in the evaluation of wireless communication technology because of their important applications as microwave/millimeter-wave resonators, filters, microwave attenuation and shielding, etc. On the other hand, new devices with superior performance are currently being developed to respond to the requirement of increased channel capacity in ground-based cellular and satellite communications. Device performance is closely related to material properties. In order to meet the needs of present and future microwave systems, improved or new components based on microwave dielectric ceramics and new designs are required. This symposium provides a forum for the worldwide microwave communities from academia and industry to share their vision and insights for microwave dielectric ceramics, to boost the research and development of microwave dielectric ceramics and promote their applications in 5G/6G, V2X, satellite communication/navigation and other information systems.

Proposed sessions :
1. Novel microwave and millimeter-wave dielectric ceramics
2. LTCC/ULTCC materials
3. Microwave absorbing and shielding materials
4. Cold sintering and other novel process for ceramics preparation
5. Components/devices/microsystems based on microwave dielectric ceramics
6. Metamaterials, metasurface and advanced artificial structures
7. Microwave dielectric ceramics and devices design/modeling/simulation/measurements
8. 3D printing /photolithography and other emerging microwave/millimeter wave devices fabrication/integration technologies
9. Microwave circuits package and integration
10. Other microwave dielectric materials related emerging topics

Organizers:
Zhifu Liu, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China, liuzf@mail.sic.ac.cn
Yang Bai, University of Science and Technology Beijing, China, baiy@mater.ustb.edu.cn
Di Zhou, Xian Jiaotong University, China, zhoudi1220@xjtu.edu.cn
Xiaoxiao Huang, Harbin Institute of Technology, China
Lei Li, Zhejiang University, China, zjulilei@zju.edu.cn
Feng Shi, Qilu University of Technology, China, sf751106@qlu.edu.cn

Point of Contact:
Zhifu Liu, Shanghai Institute of Ceramics, Chinese Academy of Sciences, liuzf@mail.sic.ac.cn

S19:Ionic and mixed conducting ceramics

Ceramic materials that are ionic conductors or exhibit simultaneous ionic and electronic conduction have been attracting extensive attention worldwide in the recent years due to their scientific and practical significance in emerging technologies such as solid-state batteries, fuel cells, electrolyzers, and sensors. The chemical functionality of ionic and mixed conducting ceramics originate from equilibrium and non-equilibrium defects in the lattice and at interfaces, and enables unique capabilities for ion/charge/mass transport and electrochemical reactions. These materials offer high promise for future applications, for example, eliminating flammable components in high-energy-density batteries, and harnessing natural hydrocarbon energy resources through efficient environmental friendly methods.

This symposium seeks to cover both scientific fundamentals and technological applications of ionic and mixed conducting ceramics and their composites, thus bridging materials theory, simulations, advanced characterizations, functional properties and real-world applications. It will provide a platform for in-depth discussions and exchange of knowledges among researchers exploring solid state ionics in ceramic-based materials on different contexts and diverse applications.

1.Defects mechanisms and engineering in ionic and mixed conducting ceramics

2.Ionic transport and mechanisms in ionic and mixed conducting ceramics

3.Electrochemical interfaces in solid state ionic devices

4.Nanoionics: mass and charge transport in the nanoscale

5.Ceramics for green energy, hydrogen and fuels - Fuel cells, electrolyzers, membrane reactors

6.Solid state (secondary) batteries for energy storage

7.Chemical and solid state Sensors

8.Applications of novel characterization techniques in ionic and mixed conducting ceramic materials and devices

Zhaoyin Wen, Shanghai Institute of Ceramics, Chinese Academy of Science, China

Minfang Han, Tsinghua University, China

Yunhui Huang, Huazhong University of Science and Technology, China

Qiang Zhang, Tsinghua University, China

Xianwen Mao, National University of Singapore, Singapore

Nobuyuki Imanishi, Mia University, Japan

Sebastian Molin, Gdańsk University of Technology, Poland

Yan Chen, South China University of Technology, China

Qiyang Lu, Westlake University, China

Ji Wu, Queen Mary University of London, UK

Lei Yao, Shenzhen University, China

Wei Liu, ShanghaiTech University, China

Na Ni(Points of Contact), Shanghai Jiao Tong University, China, na.ni@sjtu.edu.cn

S20: Advances in Bioceramics

Bioceramics are a large class of biocompatible ceramic materials specially designed and used for biomedical applications, including repairing and reconstructing diseased or damaged parts of the body, tissue engineering, and targeted drug delivery. Significant advances in bioceramics have been achieved from the 1st generation of bioinert ceramics (zirconia and alumina) and the 2nd generation of biodegradable while bioactive ceramics (hydroxyapatite ceramics) toward the 3rd generation of bioactive ceramics with enhanced regenerative performance. Especially, the degradability allows the successful release of carriers at specific sight to trigger the biological reactions for special applications. The advantages of advanced bioceramic materials in biomedical applications have been widely appreciated, especially in terms of their unique biocompatibility and high performance. The aim of this symposium is to provide an initiative platform for researchers, engineers, clinicians, and students from around the globe to share their scientific findings and applications in the field of bioceramics. The plenary lectures from renowned scientists will bring innovative ideas and strategic expansion for next generation of bioceramics and related industrial applications. The conference will also offer dynamic opportunities for young researchers/students to encourage the development in this informative podium.

1.Emerged bioceramics for biomedical implants, prostheses, prosthetic devices

2.Bioceramics for tissue engineering and regenerative medicine

3.Bioceramics for targeted drug delivery and cancer therapy

4.Bioceramic-based composites and injectable materials

5.Bioceramics with micro/nano hierarchical structures: design and properties (including porous bioceramics)

6.Bioceramic coatings for implants and devices

7.Advanced techniques for synthesis and characterization of bioceramics

8.3D printing in bioceramics: materials and techniques

9.Clinical translation of bioceramics and devices

Haobo Pan, Shenzhen Institute of Advanced Technology, Chinese Academy of Science, China

Chengyun Ning, South China University of Technology, China

Xuanyong Liu, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China

Xiumei Wang, Tsinghua University, China

Wei Xia, Uppsala University, Sweden

Congqin Ning (Point of Contact), Shanghai Normal University, China, cqning@shnu.edu.cn

S21 Data driven and AI for ceramics and composites

As we approach the new area of explosive generation of big data and creative concept of high-throughput modeling and design, artificial intelligence and machine learning, we may envisage a completely different paradigm for advancing new knowledge and discovery of ceramic materials. This symposium will focus on the fronties of computational-experimental advancements on the fundamental understanding and improvement of ceramic performances, the discovery of new ceramic materials, and the design of structural ceramic components. A broader perspective will be discussed on the key challenges and opportunities for AI related science and technology in accelerating materials innovation and creating sustainable development. Key topics include high throughput design and characterization, informatics and machine learning, and modeling of ceramics and composites with different approaches in both computational research and experimental measurements across the length and time scales so as to further optimize their behavior and facilitate the design of new structural and functional ceramics and composites with tailored properties.

1.High-throughput design and characterization

2.Informatics and machine learning

3.Multi-scale modeling of processing, microstructure and performance

4.Modeling of structure and property of ceramics and composites

5.Modeling various defects and amorphous matter at multiple scales

6.Modeling and design of continuous fiber-reinforced ceramic matrix composites

7.Modeling and prediction of ceramic materials properties in local structures, such as interfaces, surfaces and dislocations.

Jingyang Wang, Institute of Metal Research, Chinese Academy of Sciences, China

Bin Liu, Shanghai University, China

Yuelei Bai, Harbin Institute of Technology, China

Gerard L. Vignoles, University of Bordeaux, France

Sergei Manzhos, Tokyo Institute of Technology, Japan

Shuzhou Li, Nanyang Technological University, Singapore

Shijun Zhao, City University of Hong Kong, China

Neng Li, Wuhan University of Technology, China

Liang Wang, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China

Huimin Xiang, Zhengzhou University, China

Weiwei Sun, Southeast University, China

Yiran Li, Shanghai University, China

Jingyang Wang: jywang@imr.ac.cn

Bin Liu: binliu@shu.edu.cn

Yuelei Bai: baiyl@hit.edu.cn

S22: Multifuctional Nanomaterials and Heterostructures for Sensing Devices

Sensitive devices that can convert different physical, chemical or biological stimuli-such as mechanical, thermal, acoustic, gaseous, biological and optical signals-into electrical response, are of great potential for man-made robots to perceive the world in a manner similar to human beings. These devices can also assist individuals in exploring fields that currently inaccessible, enhance everyday life, and provide protection from potential dangers. According to their sensitive features, these materials can be classified into categories such as temperature-sensitive, gas-sensitive, voltage-sensitive, and optical-sensitive materials, among others. Correspondingly, they are developed into devices such as thermistors, gas sensors, varistors, biosensors and optical sensors. Current trends in the development of sensitive materials and devices emphasize high performance through various strategies, including low-dimensional and high-dimensional designs, low-temperature and facile preparation techniques, chip-type integration approaches, and the incorporation of flexible and stretchable features, as well as multi-functional modules. This symposium is dedicated to exploring multifunctional nanomaterials and heterostructures for sensing devices. It covers the application of these advanced materials and structures in the development of high-performance sensing devices, including gas sensors, optical detectors, thermistors, biosensors and pressure sensors. The symposium will delve into the latest research advancements in the design, fabrication, characterization and application of various heterostructures and multifunctional nanomaterials for sensing devices. Research papers on newly emerged sensitive materials, progresses in preparation and characterization techniques, and new applications and of sensitive materials and devices are all welcomed.

Proposed sessions:
1. Thermal sensitive materials and devices
2. Voltage sensitive materials and devices
3. Gas and humidity sensitive materials and sensor
4. Acoustic transducer materials and devices
5. Optical sensitive materials and detectors
6. Pressure sensitive materials and devices
7. Bio-signal sensitive materials and devices
8. Novel sensitive materials and devices
9. Multi-mode and multifunctional sensors integration technology
10. Sensing devices miniaturization and system application
11. AI-enabled sensing materials and devices

Organizers:
Zi-Long Tang, Tsinghua University, China
Qiu-Yun Fu, Huazhong Univ Sci. Technol., China
Wan-Ping Chen, Wuhan University, China
Ge-Yu Lu, Jilin University, China
Wang-Yang Fu, Tsinghua University, China, fwy2018@tsinghua.edu.cn (Point of Contact)
Chen Wang, Tsinghua University, China, chenwang0101@tsinghua.edu.cn (Point of Contact)
Wen Dong, Huazhong University of Science and Technology, China, dongw@hust.edu.cn (Point of Contact)
Daesung Park, Technical University of Denmark, Denmark, daepa@dtu.dk (Points of Contact)
Emad Kiriakous, Queensland University of Technology, Australia, e.kiriakous@qut.edu.au (Points of Contact)
Weiwei Lei, Deakin University, Australia, weiwei.lei@deakin.edu.au (Points of Contact)
Grégory F. Schneider, Leiden University, the Netherlands, g.f.schneider@chem.leidenuniv.nl (Points of Contact)