Education

Sun Chenyi’s educational journey began with a Bachelor’s degree in Materials Science and Engineering from Shandong University of Science and Technology, where he graduated in July 2020. His coursework included fundamental subjects such as analytical chemistry, physical chemistry, and solid-state physics, laying a strong groundwork for his future studies. Since September 2020, he has been enrolled in a dual Master’s and Ph.D. program at Shandong University, specializing in materials and chemical engineering. His advanced studies encompass modern research methodologies in materials, thermodynamics, and electrochemical kinetics, equipping him with essential theoretical and practical skills. Sun’s academic endeavors have not only deepened his understanding of materials science but also fostered his interest in the electrochemical behavior of materials, particularly in energy storage applications. This rigorous education has shaped him into a competent researcher, ready to tackle complex challenges in the field.

Professional Experience

Sun Chenyi has accumulated valuable professional experience through his ongoing research at Shandong University. He has been actively involved in projects focusing on lithium metal anodes and lithium-sulfur batteries since 2020. His work addresses critical challenges in the commercialization of lithium batteries, such as dendrite growth and volume expansion of lithium metal anodes. Sun has successfully designed and modified current collectors to enhance the stability of lithium metal batteries, resulting in multiple high-impact publications. Additionally, he is engaged in research measuring diffusion coefficients of metallic melts under strong magnetic fields, aiming to improve the understanding of liquid-solid phase transitions. His hands-on experience with cutting-edge research techniques, combined with his leadership as a student council president at his previous university, reflects his capability to lead and collaborate effectively in diverse research settings. Sun’s professional background demonstrates his commitment to advancing materials science and energy technologies.

Research Interests

Sun Chenyi’s research interests primarily focus on the development of advanced materials for energy storage applications, specifically lithium-sulfur (Li-S) batteries and lithium metal anodes. He is particularly interested in addressing the challenges associated with lithium metal batteries, including dendrite formation and polysulfide shuttle effects, which hinder their commercial viability. Sun’s research aims to enhance the electrochemical performance and stability of these batteries through innovative material design and modification techniques. He explores the use of functional materials and structural engineering to optimize electrode configurations, thereby improving charge/discharge efficiency and battery lifespan. Additionally, his work encompasses theoretical calculations related to adsorption energy and electronic properties, utilizing advanced computational tools like VASP and Materials Studio. Sun is keen on expanding his research scope to include other areas of materials science and engineering, aiming to contribute to the development of sustainable energy solutions.

Research Skills

Sun Chenyi possesses a robust set of research skills that make him proficient in the field of materials science. He is well-versed in first-principles calculations and computational modeling, utilizing software tools such as VASP and Materials Studio for electrochemical analyses. His ability to perform independent theoretical calculations allows him to analyze adsorption energies and electronic properties effectively. In addition to his computational expertise, Sun has hands-on experience in experimental techniques related to battery fabrication and characterization. He is skilled in synthesizing novel materials and modifying existing structures to enhance electrochemical performance. Sun’s research also includes a strong understanding of thermodynamic principles and kinetics, which are critical for exploring new battery technologies. Furthermore, his leadership and organizational skills, demonstrated through his experience as a student council president, enhance his ability to collaborate with colleagues and manage research projects efficiently. Together, these skills position Sun as a competent and innovative researcher in the field.

Awards and Honors

Sun Chenyi has received numerous awards and honors throughout his academic career, recognizing his dedication and excellence in research. In 2024, he was awarded the Excellent Academic Achievement Award for his outstanding contributions to the field of materials science, particularly in the area of lithium-sulfur batteries. Additionally, he has earned several academic scholarships from Shandong University, including the First-Class Academic Scholarship in 2021 and the Second-Class Academic Scholarship in 2023, which reflect his consistent academic performance. His commitment to academic excellence was also recognized with the Freshman Scholarship during his initial years at the university in 2020 and 2022. These accolades underscore Sun’s dedication to his research endeavors and his potential for future contributions to the scientific community. As he continues his academic journey, these honors serve as a testament to his capabilities and commitment to advancing materials science.

Publications Top Notes

1. Publication: 3D lithiophilic collector coated by amorphous g-C3N4 enabling Ultra-Stable cycling Li metal batteries
   Authors: Gao, L., Sun, C., Li, X., Bai, Y., Bian, X.
   Year: 2024
2. Publication: Enhanced Al-Storage Performance by Electronic Properties Optimization and Structural Customization in MOF-Derived Heterostructure
   Authors: Kang, R., Du, Y., Zhang, D., Chen, G., Zhang, J.
   Year: 2024
   Citations: 4
3. Publication: Configurational Entropy Strategy Enhanced Structure Stability Achieves Robust Cathode for Aluminum Batteries
   Authors: Kang, R., Zhang, D., Du, Y., Chen, G., Zhang, J.
   Year: 2024
   Citations: 4
4. Publication: Enhanced d-p Orbital Hybridization for Lithium Polysulfide Capturing and Lithium Deposition Inducing of AgVO3 Skeleton Enabling High-Performance Li-Sulfur Batteries
   Authors: Sun, C., Gao, L., Rong, W., Bai, Y., Bian, X.
   Year: 2024
5. Publication: Functional lithiophilic skeleton/evolving lithium sulfide artificial protective layer for dendrite-free Li metal anode
   Authors: Sun, C., Gao, L., Rong, W., Tian, X., Bian, X.
   Year: 2024
   Citations: 3
6. Publication: Modification of 2D materials using MoS2 as a model for investigating the Al-storage properties of diverse crystal facets
   Authors: Kang, R., Du, Y., Zhang, D., Chen, G., Zhang, J.
   Year: 2023
   Citations: 6
7. Publication: Highly stable lithium metal anode enabled by constructing lithiophilic 3D interphase on robust framework
   Authors: Kang, R., Du, Y., Zhou, W., Chen, G., Zhang, J.
   Year: 2023
   Citations: 9
8. Publication: Ultrafast microwave-induced synthesis of lithiophilic oxides modified 3D porous mesh skeleton for high-stability Li-metal anode
   Authors: Sun, C., Gao, L., Yang, Y., Zhang, D., Bian, X.
   Year: 2023
   Citations: 11
9. Publication: Amorphous TiO2-x modified Sb nanowires as a high-performance sodium-ion battery anode
   Authors: Gao, L., Lu, D., Yang, Y., Liu, S., Bian, X.
   Year: 2022
   Citations: 8
10. Publication: Morphology-tunable synthesis of CuO modified with Cu-Zn/Cu-Sn intermetallic compounds as high-performance anode for lithium-ion batteries
    Authors: Zhang, D., Wang, C., Yang, Y., Sun, C., Bian, X.
    Year: 2022
    Citations: 11