Sheng Hsiung Chang | Experimental methods | Best Researcher Award

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Prof. Sheng Hsiung Chang | Experimental methods | Best Researcher Award

Professor at National Taiwan Ocean University | Taiwan

Dr. Sheng Hsiung Chang is a Professor at the National Taiwan Ocean University. His extensive career in academia and research is marked by significant roles in leading institutions such as Chung Yuan Christian University (CYCU) and National Central University. Dr. Chang’s work has spanned across several pivotal research areas, particularly in semiconductor physics, optical physics, and perovskite optoelectronic devices. His achievements not only demonstrate his technical expertise but also highlight his commitment to academic leadership, mentorship, and advancing scientific knowledge.

👨‍🎓Profile

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Early Academic Pursuits 🎓

Dr. Chang’s academic journey began with his postdoctoral research roles, first at Academia Sinica (2008-2010) and later at National Central University (2010-2012), where he gained foundational experience in semiconductor and optical physics. During these early years, he developed a strong interest in light-material interactions and functional thin films, fields that would shape his future research directions. His foundational work in nanotechnology and optoelectronics established the groundwork for his later academic and research career.

Professional Endeavors 🌍

Dr. Chang has held pivotal roles in academia, including Associate Professor and Professor at CYCU, where he also served as the Director of the Career Service Center (2020-2021). These positions reflect his commitment to fostering both the research and professional development of students. Additionally, he has contributed to the scientific community as an Editorial Board Member for journals such as Nanotechnology and Physics Bimonthly.

He has also demonstrated leadership in academic societies, serving as Vice Chairman (2021-2024) and Secretary General (2019-2020) of the Taiwan Vacuum Society. This involvement shows his dedication not only to research but also to promoting collaboration and innovation within the scientific community.

Contributions and Research Focus 🔬

Dr. Chang’s research is centered around perovskite optoelectronic devices, light-material interactions, plasmonic devices, nonlinear optics, and functional thin films. He is currently the Principal Investigator for various research projects funded by the National Science and Technology Council (NSTC) and the Ministry of Science and Technology (MOST). His groundbreaking work on perovskite thin films and their applications in photovoltaic cells is pushing the boundaries of renewable energy technologies. Through projects that explore optical coupling, material interfaces, and energy harvesting, Dr. Chang’s research is expected to revolutionize the optoelectronics field.

Impact and Influence 🌍

Dr. Chang’s contributions to the scientific community have had far-reaching implications, particularly in the area of perovskite solar cells. His work on improving photovoltaic performance and investigating interfacial contacts between organic and inorganic materials has the potential to enhance solar cell efficiency and sustainability. He is a key player in advancing technologies related to energy conversion, helping to foster sustainable solutions to global energy challenges. His leadership roles in academic societies have also expanded his influence and outreach in the scientific community.

Academic Citations 📈

Dr. Chang has an impressive publication record, with recent articles in high-impact journals such as Nanotechnology, Synthetic Metals, and Materials Science in Semiconductor Processing. His work is frequently cited by fellow researchers in the field of optoelectronics, particularly his studies on perovskite materials and their optical properties. These citations underscore the significance and influence of his research in both academia and industry.

Research Skills 🧑‍🔬

Dr. Chang possesses an extensive skill set in semiconductor physics, optical physics experiments, and theoretical computations. His research involves complex techniques such as material synthesis, thin film fabrication, and optical characterization. He has a deep understanding of light-matter interactions and their application to next-generation devices like solar cells and plasmonic devices. Additionally, his ability to bridge experimental techniques with theoretical models allows him to tackle complex challenges in material design and optoelectronic applications.

Teaching Experience 🏫

In his roles as a Professor and Associate Professor, Dr. Chang has mentored numerous graduate and postgraduate students in their research pursuits. His teaching approach is centered around encouraging critical thinking, innovation, and hands-on experimentation. His experience in guiding students and fostering academic growth aligns with his belief in the importance of collaboration and mentorship within academic settings. He also plays an active role in career development, helping students transition into the professional world with a strong foundation in research and industry-related skills.

Awards and Honors 🏆

Throughout his career, Dr. Chang has been the recipient of several prestigious awards and honors, recognizing his contributions to the fields of optical physics, semiconductor research, and perovskite optoelectronics. His ongoing recognition as a leader in nanotechnology and materials science reflects his consistent pursuit of excellence in both academic research and scientific innovation.

Legacy and Future Contributions 🔮

Dr. Chang’s work is poised to leave a lasting impact on the scientific community, particularly in the field of renewable energy and optoelectronics. As the principal investigator of major research projects, he is advancing the efficiency and sustainability of perovskite-based technologies, paving the way for affordable and efficient solar energy solutions. Dr. Chang’s future contributions to nanomaterials and functional thin films will likely continue to inspire scientific innovation, technological advancements, and environmental sustainability for years to come.

Publications Top Notes

Long room-temperature valley lifetimes of localized excitons in MoS2 quantum dots

  • Authors: H. Wang, Y. Chen, T.Y. Pan, Y. Lee, J. Shen
    Journal: Optics Express
    Year: 2024

Structural and excitonic properties of the polycrystalline FAPbI3 thin films, and their photovoltaic responses

  • Authors: Y. Huang, I.J. Yen, C. Tseng, A. Chandel, S.H. Chang
    Journal: Nanotechnology
    Year: 2024

Observations of two-dimensional electron gases in AlGaN/GaN high-electron-mobility transistors using up-converted photoluminescence excitation

  • Authors: Y. Chen, L. Chen, C.B. Wu, Y.J. Lee, J. Shen
    Journal: Optics Express
    Year: 2024

Efficient Optical Coupling between Dielectric Strip Waveguides and a Plasmonic Trench Waveguide

  • Authors: J. Wu, A. Chandel, C. Chuang, S.H. Chang
    Journal: Photonics
    Year: 2024

Enhancing the photovoltaic responses of MAPbI3 poly-crystalline perovskite films via adjusting the properties of PEDOT:PSS hole transport material with a low-polarity solvent treatment process

  • Authors: C. Tsai, S.N. Manjunatha, M. Sharma, L.B. Chang, C. Chang
    Journal: Materials Science in Semiconductor Processing
    Year: 2024

 

Sanjiv Kane | Experimental methods | Best Innovation Award

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Mr. Sanjiv Kane | Experimental methods | Best Innovation Award

Scientific Officer at Raja Ramanna Centre for Advanced Technology | India

A Distinguished Scientific Officer in Applied Physics and Synchrotron Radiation

Sanjiv R. Kane is an experienced Scientific Officer with over 25 years of expertise in applied physics, particularly in synchrotron radiation and advanced instrumentation. He is currently pursuing a Ph.D. in Applied Physics at the Maharaja Sayajirao University of Baroda (2023–Present), focusing on advancing the fields of control systems, data acquisition software, and beamline technology. His proven experience spans across several prominent research facilities, including the Indus Synchrotron Facility and CERN, where he has contributed immensely to both research and technology development.

👨‍🎓Profile

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📚 Early Academic Pursuits

Sanjiv started his academic journey by earning a Bachelor of Science in Physics with minors in Mathematics and Statistics from the University of Poona (1984–1987). He further pursued his Master of Science in Applied Physics at the University of Poona (1987–1989), where he laid the foundation for his extensive career in applied physics and instrumentation design.

💼 Professional Endeavors

 Since June 1999, Sanjiv has served as a Scientific Officer at the Indus Synchrotron Facility, Raja Ramanna Centre for Advanced Technology, Indore, India, where he has worked on numerous high-profile projects. His notable contributions include the development of VME-based control systems, PLC safety interlocks, and the automation of beamline operations. His efforts in designing and deploying data acquisition systems using National Instruments LabVIEW® have been crucial in advancing the synchrotron facility’s capabilities. Additionally, he has been instrumental in designing FPGA-based DAQ systems and PXI system deployments for beamline control.

🔬 Contributions and Research Focus

Sanjiv’s research is centered on synchrotron radiation, particularly in the design and development of control systems for X-ray beamlines and instrumentation. His work on extended X-ray absorption fine structure (EXAFS), soft X-ray reflectivity, and nonlinear behavior of piezoceramic actuators has gained significant attention in the field. He has co-authored several important publications, contributing to the advancement of both material characterization and synchrotron beamline technology.

🌍 Impact and Influence

 Sanjiv’s contributions have made a significant impact on synchrotron radiation research, particularly in beamline automation and data acquisition systems. His international collaborations at CERN and Indus Synchrotron Facility have helped improve the performance of synchrotron radiation facilities, making them more efficient and accessible to researchers worldwide. His papers and conference presentations continue to influence the direction of research in synchrotron instrumentation and applied physics.

📚 Academic Cites

Sanjiv’s work has been widely cited in notable academic journals and has been presented at prestigious international conferences. His publications in journals such as Nuclear Instruments and Methods in Physics Research, Rev. Sci. Instrum., and Mechanics of Advanced Materials and Structures have contributed significantly to the development of synchrotron radiation technologies. Notable works include:

  1. “Extended X-ray Absorption Fine Structure (EXAFS) measurement of Cu metal foil using thermal wave detector: A comparative study.”
  2. “A versatile beamline for soft x-ray reflectivity, absorption, and fluorescence measurements at Indus-2 synchrotron source.”
  3. “Electric field-induced nonlinear behavior of lead zirconate titanate piezoceramic actuators in bending mode.”

🔧 Research Skills

Sanjiv’s technical expertise spans several areas including:

  • Instrumentation & Control: VME systems, PLC programming (Siemens Step 7), microcontroller-based systems (ARM, 8051).
  • Programming Languages: Proficient in LabVIEW®, C/C++, Python, Visual Basic, and VEEPRO.
  • Design & Simulation: Expertise in Altium Designer, Protel, ISE (FPGA design), NI Multisim, and Electronic Workbench.
  • Data Acquisition & Analysis: In-depth experience in developing FPGA-based DAQ systems, PXI systems, and database management using Microsoft Access.

👨‍🏫 Teaching Experience

Sanjiv has extensive experience in training and mentoring junior researchers and scientists in the areas of control systems and instrumentation for synchrotron radiation. His involvement in numerous workshops, symposia, and conferences allows him to share his expertise with others in the field.

🌱 Legacy and Future Contributions

Sanjiv’s legacy lies in his contributions to synchrotron radiation research, particularly in improving beamline automation and X-ray measurement systems. As he continues his Ph.D. journey, his future contributions will likely focus on advanced control systems and enhancements to synchrotron facilities. His ongoing work promises to make lasting improvements in the development of synchrotron instrumentation that will support the scientific community in material science, biotechnology, and physics research.

Publications Top Notes

Characterizing Pyroelectric Detectors for Quantitative Synchrotron Radiation Measurements

  • Authors: SR Kane, RW Whatmore, MN Singh, S Satapathy, PK Jha, PK Mehta
    Journal: Sensors and Actuators A: Physical
    Year: 2025

Development of Piezo-actuated X-ray Deformable Mirror for Vertical Focusing of Synchrotron Radiation at Indus-2

  • Authors: HSK Jha, AK Biswas, MK Swami, A Sagdeo, C Mukherjee, SR Kane, …
    Journal: Nuclear Instruments and Methods in Physics Research Section A: Accelerators
    Year: 2024

Green Protocol For Synthesis of Cu2O@g‐C3N4 Photocatalysts For 1, 4 Radical Oxidative Addition of Trans Crotonaldehyde Under Visible Light Condition

  • Authors: BA Maru, VJ Rao, S Kane, UK Goutam, CK Modi
    Journal: ChemPhotoChem
    Year: 2024

Development and Initial Results of X-ray Magnetic Circular Dichroism Beamline at Indus-2 Synchrotron Source

  • Authors: B Kiran, SR Garg, CK Garg, S Lal, SK Nath, R Jangir, SR Kane, …
    Journal: Proceedings of the Theme Meeting on Spectroscopy Using Indus Synchrotron
    Year: 2023

Facile Single-pot Synthesis of Fe-doped Nitrogen-rich Graphitic Carbon Nitride (Fe2O3/g-C3N4) Bifunctional Photocatalysts Derived from Urea for White LED-mediated Aldol Condensation Reaction

  • Authors: BA Maru, R Joshi, VJ Rao, SR Kane, CK Modi
    Journal: Inorganic Chemistry Communications
    Year: 2025

 

Yue Song | Experimental methods | Best Researcher Award

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Assoc. Prof. Dr. Yue Song | Experimental methods | Best Researcher Award

Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences | China

Dr. Song Yue is an Associate Researcher at the Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, specializing in high-power semiconductor lasers and the failure mechanisms of these lasers. With a PhD from the University of Chinese Academy of Sciences, she has made significant contributions to the field, including proposing new models on defect evolution and indium atom migration in semiconductor materials.

👨‍🎓Profile

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Early Academic Pursuits 📚

Dr. Song completed her PhD at the University of Chinese Academy of Sciences, where she gained deep knowledge in semiconductor lasers and the mechanisms affecting their efficiency and longevity. Her academic path was characterized by an early focus on understanding the complex behaviors of semiconductor materials under various operational conditions. Her research foundation laid the groundwork for her future innovations.

Professional Endeavors 💼

Dr. Song is an Associate Researcher at the Changchun Institute of Optics, Fine Mechanics and Physics. In this role, she has led numerous research projects, most notably focusing on high-power semiconductor lasers. She has been an integral part of key national research initiatives, including projects funded by the National Natural Science Foundation of China and the National Key Research and Development Program of China. These efforts have not only advanced her field but also brought significant funding and resources into her research domain.

Contributions and Research Focus 🔬

Dr. Song’s research is primarily focused on the development and efficiency enhancement of semiconductor lasers. Her contributions include the thermal defect evolution models for quantum wells in AlGaInAs and introducing a strained compensation layer in superlattice structures. These innovations are aimed at improving the performance and reliability of gain chips, which are central to high-power laser technology. She also proposed a novel approach to understanding indium atom migration in semiconductor materials using the dark state model, shedding light on failure mechanisms that affect the lifespan and stability of these lasers.

Impact and Influence 🌍

Dr. Song’s research has had a profound impact on the semiconductor laser industry, particularly by improving the efficiency and reliability of gain chips. Her findings are widely cited, and her work on thermal effects and indium atom migration has set new standards in the industry. Additionally, her involvement in developing group standards for the China Association of Automobile Manufacturers has led to practical applications of her research in the automotive sector.

Academic Cites 📑

Dr. Song has authored over 30 academic papers, including 14 SCI core papers as the first or corresponding author. Her work is frequently cited in the scientific community, particularly in the domains of semiconductor lasers and optical materials. She has also coauthored a monograph, expanding the breadth of her influence in the academic world.

Research Skills 🔧

Dr. Song is skilled in the theoretical modeling of semiconductor materials and laser systems. Her ability to develop defect models, atom migration theories, and structure enhancements demonstrates her expertise in both computational and experimental research. Her work is deeply rooted in quantum mechanics, material science, and optical engineering, making her a well-rounded researcher in the field.

Awards and Honors 🏅

Dr. Song has received multiple accolades recognizing her contributions, including:

  • High-level D Talents of Jilin Province
  • Dawn Talent title
  • Membership in the Changbai Mountain Leading Team
  • Changchun Institute of Optics Excellent Achievement Award
  • Institute’s Special Youth Reward Plan C-level award
  • Institute’s Innovation Practice Project Special Award
  • Recognition in the Wiley China Excellent Author Program

These honors reflect her outstanding contributions to both her field of research and the broader scientific community.

Legacy and Future Contributions 🌟

Dr. Song is poised to continue making groundbreaking contributions to semiconductor laser technology. Her work already impacts both academic research and industry applications, particularly in fields requiring high-efficiency lasers such as telecommunications, automotive technologies, and defense systems. As her research evolves, she is likely to contribute to advancements in quantum computing and photonic devices, leaving a lasting legacy in the world of optics and laser technology.

Publications Top Notes

High-power and ultra-wide-tunable fiber-type external-cavity diode lasers

  • Authors: Q. Cui, Y. Lei, C. Yang, L. Qin, L. Wang
    Journal: Optics and Laser Technology
    Year: 2025

Integrated Light Sources Based on Micro-Ring Resonators for Chip-Based LiDAR

  • Authors: L. Huang, C. Yang, L. Liang, Y. Ding, L. Wang
    Journal: Laser and Photonics Reviews
    Year: 2025

Recent Advances in Tunable External Cavity Diode Lasers

  • Authors: Y. Wang, Y. Song
    Journal: Applied Sciences (Switzerland)
    Year: 2025

Noise characteristics of semiconductor lasers with narrow linewidth

  • Authors: H. Wang, Y. Lei, Q. Cui, L. Qin, L. Wang
    Journal: Heliyon
    Year: 2024