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Professor Lili Zhao’s academic journey began with a strong foundation in materials science and electrical engineering. From her early academic pursuits, she demonstrated an aptitude for innovation in functional materials, focusing especially on dielectrics and energy storage systems. Through rigorous academic training and research engagements, she cultivated a deep interest in polymer-based composites and ceramic filler designs, which later became the cornerstone of her scholarly contributions.

💼 Professional Endeavors

Prof. Zhao has established herself as a pioneering figure in the domain of dielectrics and energy storage materials. Currently leading research initiatives at the frontier of flexible capacitor technology, her professional endeavors are focused on engineering advanced dielectric materials with high energy density and mechanical flexibility. Her expertise spans composite film synthesis, interface engineering, and structural innovation, as seen in her introduction of the egg-like ceramic filler Ba₀.₃₄Sr₀.₅₁Ca₀.₁₅Zr₀.₁Ti₀.₉O₃-Y@Ba₀.₃₄Sr₀.₅₁Ca₀.₁₅Zr₀.₁Ti₀.₉O₃-Mn@ZrO₂ (BSCZT-Y@BSCZT-Mn@ZrO₂). Her work not only contributes to academic knowledge but also addresses practical challenges in miniaturizing flexible electronic devices.

🔬 Contributions and Research Focus

Prof. Zhao’s contributions are groundbreaking, particularly in designing high-performance flexible dielectrics. Her latest research introduces a novel multilayered ceramic filler architecture, mimicking an “egg effect,” to significantly enhance effective polarization (ΔP) and discharged energy storage density in PVDF-based composites. By leveraging the synergy between donor-rich cores, acceptor-rich shells, and wide bandgap oxide “eggshells,” she achieved an ultrahigh discharged energy density of 33.2 J/cm³, a ΔP of 28.5 μC/cm², and exceptional bending endurance. Her research focus lies in reducing leakage currents through deep electron traps and promoting α-to-β phase transitions in PVDF, all contributing to superior dielectric performance.

🌍 Impact and Influence

The impact of Prof. Zhao's work in dielectrics has been widely recognized within the global materials science and electronics communities. Her novel ceramic filler strategy sets new standards for the development of flexible capacitors, paving the way for low-power wearable and flexible electronic devices. The demonstrated ability of her composite films to retain over 92% capacitance after 600 full bends signifies a remarkable advancement in both durability and performance. Her interdisciplinary influence spans electronic engineering, materials chemistry, and applied physics.

🏆Academic Cites

Prof. Lili Zhao’s publications have attracted significant academic attention, being cited extensively in journals related to materials science, electronics, and dielectrics. Her development of deep electron traps and core-shell doping mechanisms in dielectric composites has become a reference point for ongoing research in flexible energy storage. The high citation frequency underscores the academic value and technical originality of her work, particularly in the context of improving energy density without compromising mechanical flexibility.

🌟 Legacy and Future Contributions

Prof. Zhao’s legacy is being shaped by her strategic vision and technical ingenuity in the realm of flexible dielectrics. Looking forward, she is poised to expand her research to multifunctional composites, smart sensors, and scalable capacitor devices. Her future contributions will likely integrate artificial intelligence-driven design and green materials, reinforcing her leadership in advancing sustainable, high-performance electronic components. Her continued mentorship and collaborations will nurture the next generation of researchers in dielectric materials science.

📝Dielectrics

Prof. Lili Zhao’s pioneering work in dielectrics has redefined the potential of ceramic-polymer composites for flexible electronics. Her breakthrough in multilayer ceramic filler design has positioned dielectrics at the forefront of high-performance capacitor research. By combining innovation, endurance, and scalability, she continues to set benchmarks in the field of dielectrics, enabling a future of smarter, smaller, and more flexible electronic devices.

Notable Publication

📝Natural Mechanical Energy-Induced Porous PANI/(Ba₀.₈₅Ca₀.₁₅)(Zr₀.₁Ti₀.₉)O₃/PVDF Excellent Piezoelectric-Catalyzed Degradation of Dyes

Authors: Caiming Wang, Yue Jia, Huiyan Zhou, Han Zhang, Lili Zhao

Journal: Chemical Engineering Journal

Year: 2025

📝Nonequilibrium Surface Oxygen Vacancy in MgTiO₃ Inducing Fast Optical Transformation Under Laser Irradiation

Authors: Yuang Chen, Yang Zou, Lili Zhao, Zijian Lei, Lixin Song

Journal: Ceramics International

Year: 2025

📝Preparation of Two–Dimensional Gradient Fillers Reinforced Polymer Nanocomposites for High–Performance Energy Storage of Dielectric Capacitors

Authors: Yan Wang, Wenhui Zhao, Lili Zhao, Dengwei Hu, Bin Cui

Journal: Journal of Energy Storage

Year: 2024

📝Ricci Curvature of Strongly Convex Kähler-Finsler Metrics

Authors: Bin Chen, Siwei Liu, Lili Zhao

Journal: Scientia Sinica Mathematica

Year: 2024

📝ZEROECG: Zero-Sensation ECG Monitoring by Exploring RFID MOSFET

Authors: Wenli Jiao, Ju Wang, Xinzhuo Gao, Dingyi Fang, Xiaojiang Chen

Publication Type: Conference Paper

Year: Not specified (presumed 2024 or 2025)

📝Improved Energy Storage Density of Sr₀.₇Bi₀.₂TiO₃-Based Relaxor Ferroelectric Ceramics via a Core-Shell-Structural Optimization Strategy

Authors: Ruicong Chen, Yan Wang, Wenhui Zhao, Lili Zhao, Bin Cui

Journal: Journal of Materials Science: Materials in Electronics

Year: 2024

Lili Zhao – Dielectrics – Best Researcher Award 

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