Tinggui Chen | Engineering | Research Excellence Award

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Dr. Tinggui Chen | Engineering | Research Excellence Award 

Hefei University of Technology | China

Dr. Tinggui Chen is a highly accomplished researcher and academic in the field of mechanical engineering, with a specialized focus on acoustic metamaterials, phononic crystals, and advanced signal detection techniques. He completed his doctoral studies in mechanical engineering under the supervision of Prof. Dejie Yu at Hunan University, after earning both his bachelor’s degree from Hainan University and master’s degree from Hunan University. During his doctoral tenure, he developed innovative methodologies for enhancing acoustic sensing and signal detection using engineered metamaterials, establishing a strong foundation for his research career. Dr. Chen’s work is characterized by its combination of theoretical insight and experimental rigor, particularly in the design and application of gradient metamaterials, coiling-up structures, and space-time-modulated systems. His research has led to significant advancements in weak signal detection, directional acoustic sensing, and energy amplification in phononic systems. Notably, his studies on multi-frequency signal enhancement via gradient defect phononic crystals and space-time-modulated airborne acoustic circulators demonstrate his ability to bridge fundamental physics with practical engineering applications. He has actively contributed to the international scientific community through his extensive publication record, which includes articles in high-impact journals such as Measurement, Physical Review Applied, IEEE Transactions on Industrial Informatics, Mechanical Systems and Signal Processing, Journal of Sound and Vibration, IEEE Sensors Journal, Journal of Physics D: Applied Physics, and Physical Review B. These publications reflect his sustained focus on acoustic metamaterials, phononic crystal resonators, and novel techniques for signal demodulation and amplification, marking him as a leading expert in his domain. Dr. Chen’s research trajectory has also been enriched by international exposure and collaborative experiences. As a visiting scholar at EPFL under Prof. Romain Fleury, he explored cutting-edge experimental demonstrations in acoustic systems, further strengthening his expertise in wave manipulation and signal processing. Currently, as a postdoctoral researcher at Shanghai Jiao Tong University and an assistant professor at Hefei University of Technology, he continues to advance both fundamental and applied research, integrating computational modeling, experimental acoustics, and material design. His contributions have significant implications for industrial monitoring, structural health assessment, and the development of high-precision acoustic devices. With a strong focus on innovation, interdisciplinary collaboration, and practical application, Dr. Chen exemplifies the integration of scientific research and engineering solutions, positioning him as a rising leader in the field of mechanical engineering and acoustic metamaterials.

Profile: Orcid

Featured Publications

Chen, T., Zhu, M., Li, L., Wei, H., & Xia, B. (2026). Multi-frequency weak signals enhancement detection via gradient defect phononic crystals. Measurement, 261, 119933. https://doi.org/10.1016/j.measurement.2025.119933

Chen, T., Malléjac, M., Bi, C., Xia, B., & Fleury, R. (2025). Experimental demonstration of a space-time-modulated airborne acoustic circulator. Physical Review Applied, 23, 054017. https://doi.org/10.1103/PhysRevApplied.23.054017

Chen, T., Xia, B., Yu, D., & Bi, C. (2024). Robust enhanced acoustic sensing via gradient phononic crystals. Physics Letters A, 440, 129242. https://doi.org/10.1016/j.physleta.2023.129242

Chen, T., Wang, C., & Yu, D. (2022). Pressure amplification and directional acoustic sensing based on a gradient metamaterial coupled with space-coiling structure. Mechanical Systems and Signal Processing, 181, 109499. https://doi.org/10.1016/j.ymssp.2022.109499

Chen, T., & Yu, D. (2022). A novel method for enhanced demodulation of bearing fault signals based on acoustic metamaterials. IEEE Transactions on Industrial Informatics, 18(10), 6857–6864. https://doi.org/10.1109/tii.2022.3143161

Chen, T., Jiao, J., & Yu, D. (2022). Strongly coupled phononic crystals resonator with high energy density for acoustic enhancement and directional sensing. Journal of Sound and Vibration, 529, 116911. https://doi.org/10.1016/j.jsv.2022.116911

Size Ai | Engineering | Research Excellence Award

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Mr. Size Ai | Engineering | Research Excellence Award 

Harbin Institute of Technology | China

Dr. Size Ai, currently a PhD researcher at the Harbin Institute of Technology, is an emerging scholar in the field of mechanical metamaterials and advanced structural design. Holding a PhD in Mechanics from Harbin Institute of Technology, Dr. Ai has developed strong expertise in the design, modeling, and steady-state analysis of mechanical metamaterials, focusing particularly on negative stiffness structures, multi-stable metastructures, and pneumatic actuators with tunable mechanical responses. His academic journey reflects a commitment to high-quality research, having published three SCI-indexed papers in top-tier JCR Q1 journals such as Thin-Walled Structures and Engineering Structures. His works include: “Analysis of Negative Stiffness Structures with B-spline Curved Beams” (Thin-Walled Structures, 2024), “Design and Analysis of an Origami-Embedded Multi-Stable Metastructure with Shape Reconfiguration” (Engineering Structures, 2025), and “Deep Learning-Based Structural Design and Mechanical Properties Analysis of Pneumatic Actuators with Tunable Multistability” (Thin-Walled Structures, 2025). These publications highlight Dr. Ai’s ability to integrate theoretical modeling, simulation optimization, deep learning techniques, and experimental validation to solve complex challenges in structural mechanics. He has contributed significantly to ongoing national research through his involvement in the National Natural Science Foundation of China project (Grant No. 12372041), which further demonstrates his active engagement in advancing scientific knowledge. One of Dr. Ai’s major contributions includes developing a configuration parameterization method based on B-spline curves to customize negative stiffness characteristics in metamaterials. Additionally, he proposed a steady-state switching strategy using reconfigurable energy barrier elements, enabling precise control over multi-stability and shape transformation in engineered structures. His work successfully demonstrates, through combined theory, simulations, and experiments, the feasibility of programmable mechanical behavior after forming—an advancement with promising applications in soft robotics, adaptive structures, vibration isolation, and smart materials. Dr. Ai’s research continues to attract academic attention, with citations indexed in the Web of Science database. He maintains a strong ethical commitment to research integrity, with no consultancy projects, patents, or books yet undertaken. While he currently holds no editorial appointments, professional memberships, or formal collaborations, his research trajectory shows excellence, independence, and innovation, positioning him as a competitive candidate for the Research Excellence Award. Dr. Ai affirms that all submitted information is accurate, verifiable, and supported by relevant research links, including: 10.1016/j.tws.2025.114287 and 10.1016/j.tws.2023.111418. He fully agrees to the terms, policies, and responsibilities associated with this award nomination and submits this application with the highest level of integrity.

Profile: Scopus

Featured Publications

Ai, S., Xie, Z., & Wei, J. (2025, November). Deep learning-based structural design and mechanical properties analysis of pneumatic actuators with tunable multistability.

Ai, S., Hou, S., Wei, J., & Xie, Z. (2025, October). Design and analysis of an origami-embedded multi-stable metastructure with shape reconfiguration.

Hou, S., Wei, J., Ai, S., & Tan, H. F. (2025, March). Broadband nonlinear vibration isolation for a friction dynamic system via quasi-zero stiffness isolator.

Bian, S., Ai, S., Wei, J., & Qingxiang, J. (2025, March). Structural design and performance analysis of large inflatable solar membrane reflector.

Ai, S., Wei, J., Xie, Z., & Tan, H. F. (2023, November). Analysis of negative stiffness structures with B-spline curved beams.

Soujanya Reddy Annapareddy | Engineering | Women Researcher Award

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Mrs. Soujanyareddy Annapareddy | Engineering | Women Researcher Award

TAE Power Solutions | United States

Mrs. Soujanya Reddy Annapareddy is a seasoned Firmware Automation and Software Test Engineer with over 7.5 years of professional experience in embedded systems testing, automation frameworks, and data-driven validation methodologies. Her research and professional interests lie at the intersection of firmware validation, automation engineering, and intelligent system testing, focusing on how advanced test automation techniques enhance the performance, reliability, and scalability of embedded and IoT systems. At TAE Power Solutions, she has contributed to the automation and validation of Battery Energy Storage System (BESS) control platforms, integrating hardware-in-the-loop (HIL) environments and open-source frameworks such as PyTest, pandas, and matplotlib to improve regression coverage and testing efficiency. Her work explores the application of data analytics, fault-injection methods, and CI/CD pipeline integration in firmware testing to ensure real-world performance and fault tolerance. Her prior experience at Google Inc. involved automation testing for Android devices, wearable technologies, and data center systems, where she developed automation scripts in Python, Go, and C++, applied object-oriented design principles, and leveraged tools such as Mobly, Blueberry, and Buganizer for large-scale system validation. Soujanya’s analytical research focuses on automated testing frameworks, system-level reliability modeling, and signal strength optimization in wireless and connectivity domains. Methodologically, she employs Python-based automation, statistical analysis, and cloud-integrated validation frameworks, with hands-on experience in Linux environments, GCP cloud infrastructure, and RF system automation. Her interdisciplinary expertise bridges firmware engineering, test analytics, and computer science, offering insights into how automation accelerates innovation in embedded systems. Soujanya holds a Master of Science in Computer Technology from Eastern Illinois University and a Bachelor of Technology in Electronics and Communication Engineering from Jawaharlal Nehru Technological University Hyderabad (JNTUH), where she graduated with distinction. Her academic projects and industrial research underscore her commitment to advancing intelligent automation, embedded testing, and data-driven system optimization in modern technology ecosystems.

Profile: Google Scholar

Featured Publications

Annapareddy, S. R. (2025). Edge AI for real-time fault detection in embedded systems. International Journal of Emerging Trends in Computer Science and Information Systems.

Annapareddy, S. R. (2024). Managing power flows and energy efficiency in embedded systems for BESS. IJAIDR – Journal of Advances in Developmental Research, 15(2), 1–5.

Annapareddy, S. R. (2024). Advanced fault detection and diagnostics in embedded control units for BESS. IJSAT – International Journal on Science and Technology, 15(4).

Annapareddy, S. R. (2024). Firmware architecture and safety standards in battery energy storage systems. International Journal of Innovative Research in Engineering.

Annapareddy, S. R. (2024). Optimizing Android device testing with automation frameworks. International Journal of Innovative Research and Creative Technology, 10(4), 1–7.

Annapareddy, S. R. (2024). Real-world applications of Python in firmware and software automation. International Journal of Innovative Research and Creative Technology, 10(2), 1–6.

Annapareddy, S. R. (2024). Advancements in firmware testing and validation techniques. ESP Journal of Engineering & Technology Advancements, 4(3).

Ning Chen | Engineering | Best Researcher Award | 13558

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Mr. Ning Chen | Engineering | Best Researcher Award

Mr. Ning Chen, Shandong University of Science and Technology, China

Mr. Ning Chen, Lecturer at Shandong University of Science and Technology, China, is an emerging researcher in high-precision mechatronic systems. With a Ph.D. in mechanical engineering and prior industry experience, he has developed innovative piezoelectric galvanometers, stiffness-adjustable servo systems, and micro-nano motion platforms. His work is shaping the future of laser positioning, scanning, and ultra-precision control technologies. Backed by prestigious national and provincial research grants, Mr. Chen exemplifies academic excellence and practical innovation in mechanical and precision engineering.

Author Profile

Orcid

Education

Dr. Weijian Wang embarked on his academic journey with a solid foundation in chemical sciences. He earned his Bachelor’s degree in Chemical Engineering and Technology from the China University of Petroleum (East China)—an institution known for producing talent in energy and chemical sectors. His academic excellence and growing passion for applied chemical research led him to pursue a Master’s degree in Chemical Engineering at the China University of Mining and Technology, where he deepened his understanding of reaction engineering, process modeling, and advanced materials.

Eager to contribute to cutting-edge innovation in the energy sector, Dr. Wang pursued his Ph.D. in Chemical Technology at the Research Institute of Petroleum Processing (RIPP), Sinopec, one of China’s leading industrial research institutions. His doctoral training provided him with hands-on experience in industrial-scale research, advanced materials development, and interdisciplinary collaboration. To further strengthen his academic and research profile, Dr. Wang completed a postdoctoral fellowship at Zhejiang University, where he explored emerging materials and device applications, preparing him for a career at the intersection of academia and applied science.

Experience

In 2022, Dr. Wang joined Beibu Gulf University as an Associate Professor, where he has since led a promising research group focusing on halide perovskite materials. As a faculty member, he has embraced both teaching and research, mentoring students while pursuing innovative solutions to modern energy and optoelectronic challenges.

One of his key professional milestones includes leading the Guangxi Science and Technology Major Program (GuikeAA23062016). This ambitious research initiative demonstrates his leadership and technical capability in managing multi-disciplinary projects aligned with regional and national scientific goals. With no industry consultancies yet, Dr. Wang remains fully invested in academic research, pushing boundaries in materials science through both simulations and experimental designs.

Research Focus

Dr. Weijian Wang’s research is centered on the green synthesis and application of halide perovskite materials, a rapidly evolving class of compounds celebrated for their extraordinary optoelectronic properties. These materials are particularly promising in fields such as solar energy conversion, light-emitting diodes (LEDs), and medical bioimaging. At the heart of Dr. Wang’s innovation is the drive for sustainability. He has developed eco-friendly synthesis techniques that minimize environmental harm while maintaining material performance, advancing the goal of sustainable science. 🌱

In the field of perovskite solar cells, Dr. Wang employs simulation-assisted design methodologies to enhance energy conversion efficiency. His designs have led to devices with superior performance characteristics, addressing one of the key challenges in renewable energy technology. 🌞 Beyond energy, his research also extends to optoelectronic devices, including perovskite-based LEDs and imaging systems with applications in healthcare diagnostics and bioimaging. 💡

Dr. Wang’s robust scientific output includes 11 peer-reviewed publications in internationally recognized SCI-indexed journals, with eight authored as first or corresponding author. Additionally, he has secured 15 authorized invention patents as the primary inventor, underscoring his capacity to translate theoretical research into tangible technological innovations.

Award and Recognition

Despite being in the early stages of his academic journey, Dr. Wang has already built a strong research profile distinguished by originality, technical rigor, and innovation. His contributions have earned him 11 published articles in high-impact SCI-indexed journals, demonstrating both quality and consistency in scientific communication. 📚

Dr. Wang also holds 15 authorized invention patents, a notable achievement that reflects his focus on applied research and technology transfer. 🧾 These patents not only reinforce his expertise in halide perovskite materials but also highlight his dedication to practical solutions for global energy and environmental challenges.

Further elevating his academic standing, Dr. Wang currently leads a major government-funded research program, indicating trust in his leadership and vision at the national level. 💼 His H-index of 5 signifies an increasing impact within the scholarly community, with a trajectory that suggests sustained and growing influence in the years to come.

Although he does not yet hold editorial roles or memberships in professional societies, his impressive publication and patent record mark him as a promising figure in materials science. His career is on a path toward broader recognition, leadership roles, and continued contributions to the scientific community.

Publications

📖 A Semi-analytical Method for Vibro-Acoustic Properties of Functionally Graded Porous Piezoelectric Annular Plates with Cavity – Journal of Vibration Engineering and Technologies (2025).
📖 Enhancing the motion performance of 3-DOF micro/nano-manipulators facing thermo-piezoelectric-mechanical coupling effects – Sensors and Actuators A Physical (2025)
📖 Robust control of uncertain asymmetric hysteretic nonlinear systems with adaptive neural network disturbance observer – Applied Soft Computing (2024)
📖 Low thermal budget lead zirconate titanate thick films integrated on Si for piezo-MEMS applications – Microelectronic Engineering (2020)

 

 

 

Young Soo Yoon | Engineering | Best Researcher Award

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Prof. Young Soo Yoon | Engineering | Best Researcher Award

Technology Transfer at Gachon University, South Korea.

Young Soo Yoon, PhD, is a distinguished researcher and professor at Gachon University’s Department of Environment and Energy Engineering. He earned his PhD from the Korea Advanced Institute of Science and Technology and has held significant roles including Research Fellow at the University of Minnesota and Principal Research Scientist at the Korea Institute of Science and Technology. His academic journey includes tenure as an associate professor at Konkuk University and Yonsei University. Dr. Yoon’s current research focuses on advanced materials for all-solid lithium-based secondary batteries and nuclear materials, particularly in cladding and MSR reactors. He brings expertise in thin film processes, measurement, and the synthesis of nano-tailored ceramic-metal composite powders for battery applications, including innovative ATF cladding processes using room temperature swaging methods.

Professional Profiles:

Education 🎓

He earned his Ph.D. from the Korea Advanced Institute of Science and Technology (KAIST), Korea, specializing in his research focus on all solid Li-based secondary battery materials and systems, nuclear materials such as cladding and MSR reactor.

Professional Experience

He has held significant positions in academia and research, starting as a Research Fellow at the Academic Staff at the University of Minnesota and later as a Principal Research Scientist at the Korea Institute of Science and Technology from 1997 to 2003. Transitioning into academia, he served as an Associate Professor at the Department of Advanced Technology Fusion of Konkuk University from 2004 to 2008, followed by a tenure at the Department of Materials Science and Engineering of Yonsei University from 2008 to 2012. Currently, he holds a professorship at the Department of Environment and Energy Engineering at Gachon University, where he continues to lead research in advanced materials for energy storage and nuclear applications.

Research Interest

His current research interests are focused on two primary areas. Firstly, he specializes in the development of advanced materials and systems for all-solid lithium-based secondary batteries, emphasizing innovations in electrode materials and solid electrolytes. Secondly, he explores nuclear materials, particularly in the areas of cladding materials and Molten Salt Reactor (MSR) technologies. With a wealth of experience in thin-film processes, nanostructured ceramics, and composite powder synthesis tailored for battery applications, his recent endeavors include pioneering advancements in the development of new cladding processes for nuclear reactors using room temperature swaging methods.

Research Skills

He possesses matured experience in various domains, including thin film processes and measurements, essential for precise fabrication and characterization in materials science. His expertise extends to the synthesis of nano-tailored ceramic-metal composite powders, particularly for electrodes and solid electrolytes in lithium-based secondary battery systems. His current focus includes pioneering new processes for Advanced Thin Film (ATF) cladding using innovative room temperature swaging methods, aimed at enhancing the safety and efficiency of nuclear materials. These skills underline his proficiency in advancing technologies crucial for energy storage solutions and nuclear reactor safety.

Publications

  1. Corrigendum to “Fabrication and characteristics of Li2TiO3 pebbles manufactured by using powder injection molding (PIM) process”
    • Authors: Park, Y.A., Park, Y.-H., Ahn, M.-Y., Yoon, Y.S.
    • Journal: Journal of Nuclear Materials, 2024, 598, 155165
  2. Fabrication and characteristics of Li2TiO3 pebbles manufactured by using powder injection molding (PIM) process
    • Authors: Park, Y.A., Park, Y.-H., Ahn, M.-Y., Yoon, Y.S.
    • Journal: Journal of Nuclear Materials, 2024, 597, 155140
  3. Selective etching-induced surface modifications of FeCrAl alloy bipolar plates: Mechanisms for enhanced corrosion resistance and hydrophobicity
    • Authors: Kang, H.E., Kim, S.H., Choi, J.-H., Kim, D.-J., Yoon, Y.S.
    • Journal: Chemical Engineering Journal, 2024, 493, 152409
  4. Corrigendum to “Li4SiO4 slurry conditions and sintering temperature for fabricating Li4SiO4 pebbles as tritium breeder for nuclear-fusion reactors”
    • Authors: Park, Y.A., Yoo, J.W., Park, Y.-H., Yoon, Y.S.
    • Journal: Nuclear Engineering and Technology, 2024, 56(5), 1941
  5. Enhanced Durability and Catalytic Performance of Pt–SnO2/Multi-Walled Carbon Nanotube with Shifted d-Band Center for Proton-Exchange Membrane Fuel Cells
    • Authors: Min, H., Choi, J.-H., Kang, H.E., Kim, D.-J., Yoon, Y.S.
    • Journal: Small Structures, 2024, 5(3), 2300407
    • Citations: 3
  6. Recent progress in utilizing carbon nanotubes and graphene to relieve volume expansion and increase electrical conductivity of Si-based composite anodes for lithium-ion batteries
    • Authors: Kang, H.E., Ko, J., Song, S.G., Yoon, Y.S.
    • Journal: Carbon, 2024, 219, 118800
    • Citations: 2
  7. Characterization of CrAl coating on stainless steel bipolar plates for polymer electrolyte membrane fuel cells
    • Authors: Kang, H.E., Choi, J.-H., Lee, U., Kim, H.-G., Yoon, Y.S.
    • Journal: International Journal of Hydrogen Energy, 2024, 51, 1208–1226
    • Citations: 6
  8. Effect of ball milling energy and carbon content on electrochemical properties of FeF3/acetylene black composites for high-capacity thermal battery
    • Authors: Park, S.-H., Kim, S.H., Cheong, H.-W., Yoon, Y.S.
    • Journal: Ceramics International, 2024 (Article in Press)
  9. Corrigendum: Enhanced electrochemical properties of catalyst by phosphorous addition for direct urea fuel cell
    • Authors: Lee, U., Lee, Y.N., Yoon, Y.S.
    • Journal: Frontiers in Chemistry, 2024, 12, 1400748
  10. Hierarchical PtCuMnP Nanoalloy for Efficient Hydrogen Evolution and Methanol Oxidation
    • Authors: Basumatary, P., Choi, J.-H., Konwar, D., Han, B., Yoon, Y.S.
    • Journal: Small Methods, 2024 (Article in Press)