Thiyagarajan M | Experimental methods | Best Researcher Award

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Dr. Thiyagarajan M | Experimental methods | Best Researcher Award

JNN Institute of Engineering | India

Dr. Thiyagarajan M. is an accomplished physicist with a strong foundation in material synthesis and crystal growth. He holds a Ph.D. in Physics from Vellore Institute of Technology (VIT) and has been recognized as a Research Supervisor by Anna University. His academic journey and professional career reflect his deep commitment to research and education, focusing on nonlinear optical applications and the development of advanced materials. He is currently an Assistant Professor in the Department of Physics at JNN Institute of Engineering, Chennai.

👨‍🎓Profile

Scopus

Early Academic Pursuits 🎓

Dr. Thiyagarajan’s academic journey began with a Bachelor of Science (B.Sc.) in Physics from Sri Vidya Mandir Arts & Science College (2011), where he excelled with a 76.2%. His passion for physics led him to pursue a Master of Science (M.Sc.) in Physics from Periyar University, achieving a 70.7%. His academic brilliance culminated in a Ph.D. in Physics, awarded by VIT-Chennai in July 2024, under the guidance of Dr. G. Vinitha.

Professional Endeavors 💼

Dr. Thiyagarajan’s professional career reflects a balance between teaching and research. He is dedicated to fostering a progressive and competitive work culture in academia. As an Assistant Professor at JNN Institute of Engineering since September 2024, he strives to bring innovative approaches to teaching physics while guiding students in research projects. His efforts have earned him recognition for his outstanding communication skills and his ability to inspire students to reach their academic potential.

Contributions and Research Focus 🔬

Dr. Thiyagarajan’s primary research focus is on the synthesis, growth, and characterization of novel materials, particularly those with applications in optoelectronics and nonlinear optics (NLO). His research on morpholinium-based crystals has paved the way for significant contributions to material science. He utilizes low-temperature solution growth techniques and the SR method to create organic-based single crystals with enhanced thermal, mechanical, and optical properties. These contributions are critical for advancing technologies in electronic devices, laser applications, and advanced sensors.

Research Skills 🧪

Dr. Thiyagarajan possesses a broad spectrum of research skills, including expertise in X-ray diffraction (XRD), thermogravimetric analysis (TGA), UV-Vis-NIR spectroscopy, and chemical etching. His work with high-purity chemicals, along with his proficiency in laser damage threshold and Z-scan measurements, has enabled him to make cutting-edge contributions in the field of material characterization. His expertise in low-temperature crystal growth and crystal cutting/polishing is instrumental in creating materials with exceptional properties.

Teaching Experience 👨‍🏫

As an Assistant Professor at JNN Institute of Engineering, Dr. Thiyagarajan brings a wealth of teaching experience to the classroom. His passion for teaching physics drives him to use innovative methodologies that encourage active learning and critical thinking. He is known for his ability to simplify complex concepts and make them accessible to students at all levels. His commitment to student development extends beyond the classroom, as he actively mentors students in research projects and guides them through academic challenges.

Awards and Honors 🏆

Dr. Thiyagarajan’s research and teaching excellence have been recognized with several awards and honors:

  • Best Poster Presentation Award at the 21st National Seminar on Crystal Growth and Application (2018)
  • Life Membership in the Indian Association for Crystal Growth (Membership No. 029/2012)
  • Recognition as a Research Supervisor by Anna University
  • Completion of the NPTEL Online Course on Structural Analysis of Nanomaterials with an Elite Grade in August 2024

Legacy and Future Contributions 🔮

Dr. Thiyagarajan is poised to continue making substantial contributions to material science and optoelectronics in the years to come. His innovative work in crystal engineering and nonlinear optical materials lays the foundation for future developments in next-generation optoelectronic devices. With his continuous commitment to research, Dr. Thiyagarajan aims to push the boundaries of material science and contribute to the global scientific community. As his research continues to evolve, his legacy will undoubtedly inspire future generations of scientists and engineers.

Publications Top Notes

Simulation analysis on furnace pressure for reducing the impurities concentrations distribution during the growth of mc-Si ingot by DS process: Solar cell applications

  • Authors: Sekar, S., Maadhu, T., Gurusamy, A., Gandhiraj, V., Perumalsamy, R.
    Journal: Chemical Physics
    Year: 2024

Novel Metal-Organic Framework and Crystal Engineering of Bismorpholinium Mercury(II) Tribromo Chloride (BMMC) for Optoelectronic Applications

  • Authors: Maadhu, T., Jauhar, R.M., Raja, A., Gandhiraj, V., Senthil Pandian, M.
    Journal: Crystal Growth and Design
    Year: 2024, 24(4), pp. 1632–1647

Enhancement of optical, electrical, mechanical and thermal properties with Hirshfeld surface analysis of organic piperazine para-nitrophenol crystals: An effective material for NLO device fabrication

  • Authors: Kannan, V., Maadhu, T., Periyasamy, P., Gandhiraj, V., Periyasamy, P.
    Journal: Journal of Solid State Chemistry
    Year: 2024, 330, 124457

Synthesis, experimental and theoretical studies of morpholinium bromide single crystal for NLO application

  • Authors: Maadhu, T., Jauhar, R.O.M., Raja, A., Pandian, M.S., Periyasamy, P.
    Journal: Journal of Molecular Structure
    Year: 2023, 1294, 136522

Design, crystal growth and characterizations of novel bis morpholinium zinc bromide single crystals for optoelectronic applications

  • Authors: Maadhu, T., Gandhiraj, V.
    Journal: Optical Materials
    Year: 2023, 138, 113694

Growth, structural, optical, thermal and mechanical properties of morpholinium 3,5-Dinitrosalicylate single crystals for nonlinear optical applications

  • Authors: Maadhu, T., Vinitha, G.
    Journal: Journal of Materials Science: Materials in Electronics
    Year: 2022, 33(26), pp. 20911–20928

 

 

 

Duyang Zang | Experimental methods | Best Researcher Award

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Prof. Duyang Zang | Experimental methods | Best Researcher Award

Northwestern Polytechnical University | China

Duyang Zang is a professor in the School of Physical Science and Technology at Northwestern Polytechnical University, China. He holds a PhD in Physics from Paris-Sud University (2010) and has since become a leading figure in soft matter physics. His research spans topics such as capillary phenomena, interfacial rheology, and the dynamics of droplets and bubbles, with a particular focus on acoustic levitation. With a remarkable academic record, Zang has authored over 90 peer-reviewed journal papers and two books.

👨‍🎓 Profile

Scopus

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🎓 Early Academic Pursuits

Duyang Zang’s academic journey began with a deep interest in physics, leading him to earn his PhD in 2010 from Paris-Sud University. During his doctoral studies, he focused on complex systems and their physical behaviors at the interfaces, an area that would become central to his later research career. His foundational work laid the groundwork for his specialization in soft matter physics.

💼 Professional Endeavors

Currently, Zang is a professor at Northwestern Polytechnical University, where he continues to lead cutting-edge research in soft matter dynamics. Over the past decade, Zang has managed and contributed to over 10 major scientific projects funded by the National Natural Science Foundation of China and the Ministry of Education. His research is not limited to traditional soft matter studies but also explores the innovative application of acoustic levitation to manipulate soft matter systems.

🔬 Contributions and Research Focus

Zang’s work is at the forefront of soft matter physics, focusing on the physics and dynamics of interfaces in complex and soft matter systems. His key research areas include:

  • Capillary phenomena: Understanding how liquids interact with surfaces at a microscopic level.
  • Interfacial rheology: Investigating how soft materials behave under stress and deformation.
  • Droplet and bubble dynamics: Studying the movement, stability, and behavior of droplets and bubbles in various systems.
  • Phase behaviors: Exploring how materials transition between different phases, such as from liquid to gas or solid to liquid.

A particularly innovative aspect of his research is the exploration of combining soft matter physics with acoustic levitation, which enables novel ways of manipulating matter without physical contact.

📈 Academic Cites

Zang’s extensive body of work is reflected in his impressive citation count of more than 2,700 citations, with an h-index of 30 (as per Scopus). This demonstrates his significant and sustained influence in the scientific community, with numerous researchers building upon his findings to explore new areas of study.

🧠 Research Skills

Zang is recognized for his strong analytical and experimental research skills, which have enabled him to conduct groundbreaking work on interfacial phenomena and phase transitions. His ability to integrate theoretical models with experimental observations has made him a leader in both fundamental and applied research in soft matter physics. Additionally, his work in acoustic levitation showcases his ability to merge innovative technologies with classical research areas.

🏫 Teaching Experience

As a professor, Zang is deeply committed to the education and mentorship of the next generation of physicists. He has taught various courses, including those on soft matter physics and complex systems. His teaching extends beyond formal classrooms as he also participates in academic panels, conferences, and research guidance, offering valuable mentorship to graduate students and young researchers.

🏅 Awards and Honors

Duyang Zang’s work has earned him prestigious recognitions such as:

  • Top 10 Emerging Scientists Award of China (2018)
  • IAAM Scientist Medal (2021)
  • Fellow of the International Association of Advanced Materials (IAAM)
    His achievements are further underscored by his role on the editorial boards of leading journals like European Physical Journal E, Frontiers in Soft Matter, and Soft Matter.

🌟 Legacy and Future Contributions

Zang’s contributions have set the stage for continued advances in soft matter physics, especially in its application to new technologies and innovative materials. As a thought leader, he is likely to continue influencing the field by addressing complex challenges, such as dynamic interfaces and material design. Zang’s work, particularly in acoustic levitation, could open new frontiers in areas like biotechnology, nanotechnology, and advanced manufacturing.

  Publications Top Notes

Anisotropic growth dynamics of liquid bridge during droplet coalescence under acoustic levitation

  • Authors: Hongyue Chen, Xianyu Nong, Bokun Zhao, Wenxuan Zhong, Kangqi Liu, Zhen Chen, Duyang Zang
    Journal: Physical Review Fluids
    Year: 2025

Atomization by Acoustic Levitation Facilitates Contactless Microdroplet Reactions

  • Authors: Xiaoxu Li, Xianyu Nong, Chenghui Zhu, Xufeng Gao, Huan Chen, Xu Yuan, Dong Xing, Lu Liu, Chiyu Liang, Duyang Zang et al.
    Journal: Journal of the American Chemical Society
    Year: 2024

Ultrasound induced grain refinement of crystallization in evaporative saline droplets

  • Authors: Xiaoqiang Zhang, Hongyue Chen, Yuhan Wang, Xin Gao, Zhijun Wang, Nan Wang, Duyang Zang
    Journal: Ultrasonics Sonochemistry
    Year: 2024

Extraordinary stability of surfactant‐free bubbles suspended in ultrasound

  • Authors: Xiaoliang Ji, Wenxuan Zhong, Kangqi Liu, Yichen Jiang, Hongyue Chen, Wei Zhao, Duyang Zang
    Journal: Droplet
    Year: 2024

Toward Enhanced Aerosol Particle Adsorption in Never‐Bursting Bubble via Acoustic Levitation and Controlled Liquid Compensation

  • uthors: Xiaoliang Ji, Pingsong Jiang, Yichen Jiang, Hongyue Chen, Weiming Wang, Wenxuan Zhong, Xiaoqiang Zhang, Wei Zhao, Duyang Zang
    Journal: Advanced Science
    Year: 2023

 

Ziyao Jie | Experimental methods | Best Researcher Award

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Dr. Ziyao Jie | Experimental methods | Best Researcher Award

Postdoc at State Grid Jibei Electric Power Co., Ltd. Research Institute in China

Ziyao Jie is a postdoctoral researcher at the State Grid Jibei Electric Power Research Institute. He holds a Ph.D. in Electrical Engineering from Tsinghua University, where his research centered on the microwave plasma-based synthesis of nanomaterials for lithium-ion battery applications. Throughout his academic career, Ziyao has made notable contributions to sustainable energy and plasma science, with a focus on improving energy storage technologies. His work on graphene-coated silicon nanomaterials addresses critical issues in battery performance, such as energy capacity and cycling stability. Ziyao’s research has been widely recognized, with multiple patents and publications in high-impact journals.

Profile:

Education:

Ziyao Jie earned his Ph.D. in Electrical Engineering from Tsinghua University, where he specialized in plasma science and nanomaterials synthesis under the guidance of Professor Guixin Zhang. His doctoral thesis focused on the development of microwave plasma methods for producing graphene-coated silicon nanoparticles, designed to enhance lithium-ion battery performance. During his studies, Ziyao gained a comprehensive understanding of high-voltage technologies, nanomaterial properties, and energy storage solutions, which equipped him to tackle real-world challenges in sustainable energy. His academic excellence is reflected in his deep knowledge of plasma diagnostics and high-temperature material synthesis.

Professional Experience:

Ziyao Jie has amassed significant experience in plasma science and energy storage. Following his doctoral research at Tsinghua University, where he developed innovative methods for synthesizing advanced materials for batteries, he continued as a postdoctoral researcher at the State Grid Jibei Electric Power Research Institute. His current work focuses on high-voltage and energy storage systems, contributing to the development of large-scale, sustainable energy solutions. Ziyao has collaborated on key projects such as the Beijing Science and Technology Planning Project, and his expertise spans the areas of nanomaterial synthesis, waste treatment with plasma, and renewable energy applications.

Research focus:

Ziyao Jie’s research focuses on the intersection of plasma science, nanomaterials, and sustainable energy. His primary area of interest is the synthesis of nanomaterials using microwave plasma technologies, with a particular focus on developing advanced materials for energy storage, such as graphene-coated silicon nanoparticles for lithium-ion batteries. His work aims to address key challenges in energy density, stability, and scalability for future battery technologies. Ziyao is also involved in developing plasma-based waste treatment systems, including medical waste management, using high-temperature plasma torches. His research is distinguished by its potential to revolutionize both energy storage and environmental sustainability.

Awards and Honors:

Ziyao Jie has received numerous accolades for his groundbreaking work in plasma science and nanomaterials. His research on microwave plasma-based synthesis earned him recognition in energy storage circles, particularly for his contributions to improving lithium-ion battery technology. Ziyao was a participant in the Beijing Science and Technology Planning Project, which recognized his innovative work on high-energy and high-voltage technologies. Additionally, his patented inventions, which include advanced methods for medical waste treatment and nanomaterial applications, have further established his reputation as a leading researcher. Ziyao’s contributions have also led to high citation indices, highlighting his influence in the academic community.

Publication Top Notes:

  • Mechanisms of Gas Temperature Variation of the Atmospheric Microwave Plasma Torch
    Z. Jie, C. Liu, S. Huang, G. Zhang
    Journal of Applied Physics, 129 (23), 2021
    Citations: 12
  • Microwave Plasma Torches for Solid Waste Treatment and Vitrification
    Z. Jie, C. Liu, D. Xia, G. Zhang
    Environmental Science and Pollution Research, 30 (12), 32827-32838, 2023
    Citations: 10
  • Imaging Diagnostics and Gas Temperature Measurements of Atmospheric-Microwave-Induced Air Plasma Torch
    S. Huang, C. Liu, Z. Jie, G. Zhang
    IEEE Transactions on Plasma Science, 48 (6), 2153-2162, 2020
    Citations: 10
  • Polymer Dielectrics with Outstanding Dielectric Characteristics via Passivation with Oxygen Atoms through C–F Vacancy Carbonylation
    T.Y. Wang, X.F. Li, Z. Jie, B.X. Liu, G. Zhang, J.B. Liu, Z.M. Dang, Z.L. Wang
    Nano Letters, 23 (18), 8808-8815, 2023
    Citations: 8
  • An Atmospheric Microwave Plasma-Based Distributed System for Medical Waste Treatment
    Z. Jie, C. Liu, D. Xia, G. Zhang
    Environmental Science and Pollution Research, 30 (17), 51314-51326, 2023
    Citations: 6
  • Surface-Wave-Sustained Plasma Synthesis of Graphene@Fe–Si Nanoparticles for Lithium-Ion Battery Anodes
    Z. Jie, Z. Zhang, X. Bai, W. Ma, X. Zhao, Q. Chen, G. Zhang
    Applied Physics Letters, 123 (11), 2023
    Citations: 3
  • Determination of 915-MHz Atmospheric Pressure Air Microwave Plasma Torch (MPT) Parameters
    Z. Jie, C. Liu, D. Xia, Z. Zhang, X. Zhao, G. Zhang
    IEEE Transactions on Plasma Science, 51 (2), 456-465, 2023
    Citations: 2
  • The Treatment of Medical Waste by Atmospheric Microwave Plasma
    D. Xia, C. Liu, Z. Jie, G. Zhang
    2021 IEEE International Conference on Plasma Science (ICOPS), 2021
    Citations: 2
  • Microwave Plasma Torch for Solid Waste Treatment
    Z. Jie, C. Liu, D. Xia, G. Zhang
    IET Digital Library, 2021
    Citations: 2
  • Continuous Batch Synthesis with Atmospheric-Pressure Microwave Plasmas
    Z. Jie, T.Y. Wang, S. Huang, X. Bai, W. Ma, G. Zhang, N. Luo
    iScience, 27 (8), 2024
    Citations: N/A

Conclusion:

Ziyao Jie is a strong candidate for the Best Researcher Award, with his groundbreaking contributions in plasma science and energy storage technologies. His research has direct implications for sustainable energy solutions, positioning him at the forefront of innovations in high-energy physics and computational science. His achievements, particularly his patents and numerous high-impact publications, showcase his potential to make lasting contributions to academia and industry, making him highly suitable for this prestigious award.