Assoc. Prof. Dr. Li Xiaobing | Materials Science | Best Researcher Award

Assoc. Prof. Dr. Li Xiaobing, University of Shanghai for Science and Technology, China.

Dr. Xiaobing Li is an Associate Professor at the University of Shanghai for Science and Technology. With a Ph.D. in Materials Science & Engineering from SICCAS, he specializes in ferroelectric single-crystal growth and piezoelectric transducer design 🔬. His work on PMN-PT crystals and 40 MHz miniature ultrasound probes has advanced biomedical imaging 🏥📡. A prolific author in top journals, Dr. Li’s innovations bridge fundamental science and medical applications 🌐🏆. His international collaborations include visiting roles at UNSW and Hallym University 🌏.

Profile

Scopus Profile

🎓 Early Academic Pursuits

Xiaobing Li began his academic journey with a Bachelor’s degree in Physics from Qingdao University (2000–2004), followed by a Master’s degree (2004–2007) and Ph.D. in Materials Science & Engineering from the prestigious Shanghai Institute of Ceramics, Chinese Academy of Sciences (2007–2010). His formative years laid a strong foundation in crystallography, materials science, and advanced ceramics. 🧪📘

💼 Professional Endeavors

Dr. Li currently serves as an Associate Professor at the University of Shanghai for Science and Technology (2019–Present). He held previous academic roles at the Shanghai Institute of Ceramics as Assistant and Associate Professor (2010–2018), and was an academic visitor to Hallym University, Korea, and University of New South Wales, Australia. His global exposure enhanced his research breadth and collaborative strength. 🌏🔬

🔬 Contributions and Research Focus On Materials Science

Dr. Xiaobing Li specializes in single crystal growth, particularly PMN-PT ferroelectric crystals using the Bridgman technique. His pioneering work has unraveled growth defect mechanisms, phase transitions, and point defects using advanced methods such as X-ray diffraction, Raman spectroscopy, neutron scattering, and synchrotron radiation. Moreover, he ventured into ultrasound medical imaging, developing miniature 40 MHz ultrasound transducers for soft tissue visualization. 🧫🧠

🌍 Impact and Influence

Dr. Li’s work bridges materials science and biomedical engineering, contributing to next-gen imaging technologies. His crystals serve as functional components in high-performance sensors and medical devices, reinforcing his impact across disciplines. His collaborations with global institutions demonstrate thought leadership and innovation. 💡🌐

🧠 Research Skills

Dr. Li demonstrates strong expertise in single crystal synthesis, defect analysis, ferroelectric materials, piezoelectric composites, and nanostructure characterization. He is proficient with advanced instrumentation techniques and has contributed to both experimental design and application-based innovations. ⚙️📊

🏅 Awards and Honors

While specific awards are not listed, Xiaobing Li’s prestigious academic postings, international collaborations, and invited publications reflect consistent recognition and trust by the global materials science community. His positions at top Chinese and international institutions speak volumes about his academic stature. 🎖️🌟

🏛️ Legacy and Future Contributions

Dr. Xiaobing Li’s legacy lies in his ability to connect crystal physics with practical biomedical applications. As technology advances, his research on lead-free ferroelectrics and miniaturized imaging transducers will play a crucial role in sustainable and precision healthcare technologies. His mentorship and continued innovation promise a strong future impact. 🔭👨‍🏫

Publications Top Notes

Short‐fiber piezocomposite and its bandwidth enhancement for high‐frequency medical ultrasound transducer
📰 Journal of Materials Science: Materials in Electronics | 🔖 1 citation | 📆 2025
Advances in electrochemical biosensors for the detection of tumor‐derived exosomes (Review, Open Access)
📖 Review article | 🔖 1 citation | 📆 2025
High Frequency Ultrasound Transducer Based on Sm‐Doped Pb(Mg₁/₃Nb₂/₃)O₃-0.28PbTiO₃ Ceramic for Intravascular Ultrasound Imaging
📰 Ultrasonic Imaging | 🔖 1 citation | 📆 2024
Preparation of 1-3 piezoelectric composites based on PMNT ceramics by soft mold method and research of ultrasound transducer
📰 Gongneng Cailiao Journal of Functional Materials | 📆 2024
Ultrasonic Transducer Based on High-Performance Lead-Free (K₀.₅Na₀.₅)NbO₃-Based Ceramics
📰 Yadian Yu Shengguang Piezoelectrics and Acoustooptics | 📆 2023
Deep learning-based classification for benign and malignant breast masses using multimodal ultrasound images
📰 Chinese Journal of Medical Physics | 🔖 1 citation | 📆 2023
Fabrication of 1-3 Piezocomposite and High-Frequency Medical Ultrasonic Transducer Via Soft-Mold Process
📰 Yadian Yu Shengguang Piezoelectrics and Acoustooptics | 📆 2023
High Frequency Ultrasonic Transducer and Scanning Method for Ultrasound Imaging of Skin Cyst
📰 Yadian Yu Shengguang Piezoelectrics and Acoustooptics | 📆 2022
Fabrication of 1–3 piezoelectric composites via modified soft mold process for 40 MHz ultrasonic medical transducers
📰 Ceramics International | 🔖 9 citations | 📆 2022
Investigation of the dielectric relaxation mechanisms for Pb(Fe₁/₂Nb₁/₂)O₃ single crystal based on the universal relaxation law
📰 Physica B: Condensed Matter | 🔖 1 citation | 📆 2022

Dr. Paul Follansbee| Chemistry | Best Researcher Award

Dr Paul Follansbee, Saint Vincent College, United States

Paul S. Follansbee is a renowned materials scientist 🏅 with expertise in deformation kinetics, constitutive behavior, and materials processing. With over 20 years in research, 15 years in technical management, and 12 years in academia, he has significantly contributed to engineering education 📚 at Saint Vincent College. His groundbreaking work in state-variable deformation modeling and numerous publications 📝 continue to influence the field. As a Professor Emeritus, he remains dedicated to mentorship, innovation, and scientific excellence. 🌟

Professional Profile

Scopus Profile

Early Academic Pursuits 🎓

Paul S. Follansbee’s academic journey began with a strong foundation in materials science and engineering. His passion for understanding the fundamental principles of deformation kinetics and constitutive behavior led him to pursue advanced studies in metallurgy. His early academic engagements included a three-month sabbatical at the University of California, San Diego, where he collaborated with Professor Sia Nemat Nasser and presented a seminar series on deformation modeling. This phase of his career set the stage for his future contributions to both research and education.

Professional Endeavors 🏛️

With over 20 years in technical research and development, 15 years in technical management, and 12 years in academia, Dr. Follansbee has played a pivotal role in engineering education. At Saint Vincent College, he developed and taught multiple engineering and materials science courses, initiated an Introduction to Engineering course, and established a Capstone Research Program. His leadership extended to external advisory committees at Carnegie Mellon University, Washington State University, and Saint Francis University.

Contributions and Research Focus On Materials Science 🔬

Dr. Follansbee’s research has centered on dynamic plastic constitutive behavior of metals, deformation modeling, and materials characterization. His work has been instrumental in developing state-variable models to predict material behavior under various conditions. Notably, his 1988 publication in Acta Metallurgica on deformation modeling in copper remains widely cited. His contributions to technical advancements in LANL, General Electric, and Howmet Research Corporation further solidified his status as a thought leader in the field.

Impact and Influence 🌍

His leadership roles at Los Alamos National Laboratory (LANL), where he managed teams of up to 500 engineers and scientists, influenced key projects in materials science, nuclear weapons components, and government-funded R&D. His tenure at GE Corporate Research and Development Center led to innovations in spray forming, niobium-silicide-based alloys, and thermal barrier coatings. Through strategic planning, he ensured the alignment of research programs with business and national interests.

Academic Citations 📚

Dr. Follansbee’s contributions to materials science and deformation modeling have garnered widespread academic recognition. His highly cited 1988 paper continues to influence researchers worldwide. His research has been published in top journals like Metallurgical and Materials Transactions A, ASME Journal of Materials Engineering Technology, and Materials Science and Applications. His 490-page textbook, “Fundamentals of Strength”, encapsulates decades of research and serves as a critical resource for students and professionals.

Awards and Honors 🏆

His outstanding work has earned him accolades such as the Best Paper Award at the TMS Annual Meeting and leadership positions in numerous academic and industrial committees. His efforts in securing laboratory equipment donations and establishing educational programs at Saint Vincent College have left a lasting impact on engineering education.

Legacy and Future Contributions 🔝

Even in retirement, Dr. Follansbee remains engaged in research and mentorship. His dedication to mentoring students, developing laboratory courses, and advancing engineering education ensures that his influence continues to shape future generations of scientists and engineers. His legacy as an innovator, educator, and researcher remains firmly embedded in the field of materials science.

📚Publications Top Notes

📄 Article: Development and Application of an Internal State Variable Constitutive Model for Deformation of Metals

📖 Book Chapter: High-Strain-Rate Deformation of FCC Metals and Alloys

📄 Article: MTS Model Application to Materials Not Starting in the Annealed Condition
🔢 Citations: 2

📖 Book Chapter: A Constitutive Law for Metal Deformation

📖 Book Chapter: Application of MTS Model to Nickel-Base Superalloys
🔢 Citations: 1

📖 Book Chapter: Data Analysis: Deriving MTS Model Parameters

Li Xiaobing | Materials Science | Best Researcher Award