Jiangbin Su | Electrochromic Technology | Best Researcher Award

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Prof Dr.Jiangbin Su | Electrochromic Technology | Best Researcher Award

Innovation and Patents:
  • Dr. Su has applied for 20 invention patents, showcasing his innovative contributions to technology development. His work in electrochromic materials and nanotechnology has practical applications, especially in energy-efficient devices, which align with contemporary technological needs.
Prof Dr. Jiangbin Su , Xinyu University, China

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🏛️Early Academic Pursuits

  • Jiangbin Su, PhD, embarked on his academic journey with a focus on materials science, nanotechnology, and physics. His early work laid the foundation for his specialization in electrochromic materials and devices, energy storage technologies, and nanophysics. Throughout his academic career, Su demonstrated a strong commitment to research excellence, publishing nearly 100 academic papers in SCI and EI journals. His dedication to understanding material behavior at the nanoscale has been a key driver in his academic development.

👨‍🔬 PROFESSIONAL ENDEAVORS

  • Su currently serves as a faculty member at Xinyu University, his research output speaks volumes about his leadership in the field. He has applied for 20 invention patents and has played a pivotal role in both national and provincial-level natural science foundation projects, leading or contributing to five major initiatives. Additionally, Su has taken on various editorial roles, including being a member of the editorial board for the Journal of Electronics and Telecommunication Engineering, the Journal of Liaocheng University (Natural Science Edition), and serving as a review editor for Frontiers in Physics.

🏆 CONTRIBUTIONS AND RESEARCH FOCUS

  • Su’s research spans electrochromic materials and devices, energy storage batteries, and nanotechnology and nanophysics. He is especially noted for developing the concepts of the “nanocurvature effect” and the “non-thermal activation effect,” which have advanced the understanding of material behavior at the nanoscale. His work in the preparation and optimization of electrochromic thin films has been crucial in improving their performance, particularly in applications like smart windows and energy-efficient devices. His innovations have helped push the boundaries of electrochromic technology, blending both theoretical exploration and practical application.

đź“Š IMPACT AND INFLUENCE

  • Su’s contributions have had a lasting impact on the scientific community, as evidenced by his extensive publication record of 93 papers in prestigious SCI and Scopus-indexed journals. His work has been cited 2,174 times in the SCI database, underscoring his influence on peers in the fields of material science, energy storage, and nanotechnology. Furthermore, his involvement in one industry project reflects the practical relevance of his research, bridging the gap between academia and real-world applications.

🏅ACADEMIC CITES

  • Su’s impressive h-index of 27 highlights the significance of his contributions to the academic world. His work is widely recognized, particularly for his theoretical advancements and innovative approach to nanotechnology and energy-efficient devices. He continues to contribute to the scientific community as a member of the Chinese Society for Imaging Science and Technology, the Chinese Physical Society, and the expert committee of the China Optoelectronics Industry Platform and Optoelectronic Materials and Devices Network.

🚀LEGACY AND FUTURE CONTRIBUTIONS

  • Jiangbin Su’s work has laid the groundwork for future research in the fields of nanophysics, energy storage, and smart material devices. His research not only enhances current technological capabilities but also paves the way for future advancements in electrochromic technology and sustainable energy solutions. Su’s commitment to innovation and research excellence ensures that his legacy will continue to shape these fields for years to come.

đź“„Publications

  • Actively Tunable and Switchable Terahertz Metamaterials with Multi-Band Perfect Absorption and Polarization Conversion
    Authors: Ying Zhu, Zhiyu Huang, Jiangbin Su, Bin Tang
    Journal: Physical Chemistry Chemical Physics (2024)
  • Recent Review on Self-Supported One-Dimensional Core/Shell Nanostructures Based on WO3 for Enhanced Electrochromism
    Authors: Jiangbin Su, Longlong Chen, Chunyan Xu, Yu Liu, Long Shen, Zuming He
    Journal: Journal of Materials Chemistry A (2024)
  • Switchable Asymmetric Transmission with Broadband Polarization Conversion in Vanadium Dioxide-Assisted Terahertz Metamaterials
    Authors: Zhichao Liu, Tianle Zhou, Gui Jin, Jiangbin Su, Bin Tang
    Journal: Physical Chemistry Chemical Physics (2024)
  •  Oxygen-Content-Regulated Nanocrystalline InON Thin Films with Ultrafast Electrochromic Response and Excellent Stability
    Authors: Xiangming Zeng, Jiangbin Su, Chunyan Xu, Jiahao Chen, Xuemei Ji, Zuming He
    Journal: ACS Sustainable Chemistry & Engineering (2024-10-14)
  •  Electrochromic Properties of InON Thin Films Prepared by DC Magnetron Sputtering
    Authors: Jiahao Chen, Xuemei Ji, Jiangbin Su, Zuming He, Bin Tang
    Journal: Applied Physics A (2024-03)
  • Optimization of Optical Modulation in Amorphous WO3 Thin Films
    Authors: Jiangbin Su, Xiumei Zhu, Longlong Chen, Yu Liu, Hao Qi, Zuming He, Bin Tang
    Journal: Electronic Materials Letters (2024-03)

Zhi-Qiang Tao | Mechanical Engineering| Best Researcher Award

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Dr .Zhi-Qiang Tao | Mechanical Engineering| Best Researcher Award

Research Contributions:
  • With over 20 peer-reviewed technical papers published in international journals and conference proceedings, Dr. Tao has significantly contributed to the understanding and advancement of his specialized research areas. His publications reflect the breadth of his knowledge and dedication to his field.
 Dr . Zhi-Qiang Tao, Zhejiang Ocean University, China

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🎓Early Academic Pursuits

  • Zhi-Qiang Tao received his Ph.D. in Mechanical Engineering from Beijing University of Technology in 2018. During his doctoral studies, Tao focused on mechanical dynamics and fatigue-related phenomena, laying the foundation for his future research in fatigue mechanisms, particularly in multiaxial and very high cycle fatigue.

đź’ĽProfessional Endeavors

  • After completing his Ph.D., Zhi-Qiang Tao became a Research Assistant at the Robotics College of Beijing Union University. Here, he collaborated with colleagues on cutting-edge research in robotics and mechanical engineering, contributing significantly to the development of fatigue analysis tools and technologies. His role also involved mentoring students and assisting in various research projects.

🔬 CONTRIBUTIONS AND RESEARCH FOCUS

  • Zhi-Qiang Tao has focused extensively on:
    • Mechanical Dynamics
    • Multiaxial Fatigue
    • Very High Cycle Fatigue (VHCF)

    His research investigates how materials respond under extreme conditions over extended periods, helping industries understand material durability and mechanical resilience. His work has applications across sectors such as automotive, aerospace, and robotics, providing critical insights into the longevity and safety of components.

🏆IMPACT AND INFLUENCE

  • Tao’s research on very high cycle fatigue is of particular importance, as it addresses the need for understanding how materials behave under more than one million cycles of loading. His work helps improve the design of mechanical systems to avoid failures, thus enhancing safety and reliability in critical infrastructures. With over 20 peer-reviewed technical papers published in international journals and conference proceedings, his work has been widely cited and recognized. His contributions serve as a foundation for ongoing studies in fatigue failure mechanisms.

🏅ACADEMIC CITES

  • Zhi-Qiang Tao has received numerous citations in the fields of mechanical dynamics and fatigue studies, underscoring his impact on the academic community. His contributions have been referenced in studies related to material resilience, fatigue life prediction, and failure analysis, emphasizing his role in advancing the understanding of fatigue phenomena in engineering materials.

đź”®LEGACY AND FUTURE CONTRIBUTIONS

  • Zhi-Qiang Tao’s legacy in the field of mechanical engineering is one of persistence and innovation. His future contributions are expected to continue influencing how industries approach material fatigue and structural design. As fatigue becomes an increasingly crucial aspect of robotic systems, Tao’s work will play a pivotal role in ensuring mechanical components can withstand extreme conditions and prolonged use. Through his research, he has not only contributed to academia but also provided valuable insights for industry applications that focus on extending the life cycle of mechanical components, enhancing both safety and performance.

đź“°PUBLICATIONS

  • A new probabilistic control volume scheme to interpret specimen size effect on fatigue life of additively manufactured titanium alloys
    Authors: Tao, Z.-Q., Wang, Z., Pan, X., Qian, G., Hong, Y.
    Journal: International Journal of Fatigue, 2024, 183, 108262
  •  Surface roughness prediction and roughness reliability evaluation of CNC milling based on surface topography simulation
    Authors: Zhang, Z., Lv, X., Qi, B., Zhang, M., Tao, Z.
    Journal: Eksploatacja i Niezawodnosc, 2024, 26(2), 183558
  •  Life prediction method based on damage mechanism for titanium alloy TC4 under multiaxial thermo-mechanical fatigue loading
    Authors: Li, D.-H., Shang, D.-G., Mao, Z.-Y., Cong, L.-H., Tao, Z.-Q.
    Journal: Engineering Fracture Mechanics, 2023, 282, 109206
  • Multiaxial fatigue life estimation based on weight-averaged maximum damage plane under variable amplitude loading
    Authors: Tao, Z.-Q., Qian, G., Li, X., Zhang, Z.-L., Li, D.-H.
    Journal: Journal of Materials Research and Technology, 2023, 23, pp. 2557–2575
  •  Multiaxial fatigue life prediction by equivalent energy-based critical plane damage parameter under variable amplitude loading
    Authors: Tao, Z.-Q., Qian, G., Sun, J., Zhang, Z.-L., Hong, Y.
    Journal: Fatigue and Fracture of Engineering Materials and Structures, 2022, 45(12), pp. 3640–3657