Da Wan Kim | Soft Robotics | Best Researcher Award

Published on by Mechanics Awards

Prof. Da Wan Kim | Soft Robotics | Best Researcher Award

Assistant Professor | korea national university of transportation | South Korea

Assistant Professor in the Department of Electronic Engineering at Korea National University of Transportation (KNUT). With a background in chemical engineering and an interdisciplinary focus, he is recognized for his innovative research in soft bioelectronics, bioinspired adhesives, and skin-interfacing devices. His career bridges materials science, electronics, and biomedical applications, positioning him at the forefront of next-generation wearable technologies. After completing his B.Sc. and Ph.D. in Chemical Engineering at, Prof. Kim conducted postdoctoral research under Prof. Changhyun Pang and held a visiting researcher position at the. In , he joined KNUT as a faculty member, where he continues to explore adaptive materials and systems for human-machine interfaces, many of which have been featured on journal covers. His work is supported by several domestic and international patents related to advanced adhesives and sensor technologies. With a commitment to interdisciplinary collaboration, he continues to make significant contributions to smart, sustainable, and human-centric electronics

Professional Profile

Education

Prof. Da Wan Kim’s academic foundation is rooted in Chemical Engineering, having completed both his undergraduate and doctoral studies at Sungkyunkwan University in South Korea. His B.Sc. in Chemical Engineering  provided a strong grounding in thermodynamics, materials science, and process systems, which laid the groundwork for his transition into advanced materials research. He pursued his Ph.D. in Chemical Engineering under the mentorship of Prof. Changhyun Pang, focusing on bioinspired adhesive architectures for soft bioelectronics. His doctoral research emphasized multifunctional materials for skin-like electronics, exploring how nature-inspired strategies could enable better adaptability, adhesion, and integration with biological tissues. His dissertation contributed significantly to the fields of wearable technology and bioelectronics, and his early publications garnered international attention for their novelty and applicability. Throughout his academic journey, Prof. Kim demonstrated strong interdisciplinary engagement by integrating principles from chemical engineering, nanotechnology, biomedical engineering, and electronics. His academic performance and research outcomes during his Ph.D. positioned him for highly competitive postdoctoral and faculty roles.

Experience

Prof. Da Wan Kim has cultivated a rich and diverse professional portfolio in the fields of soft electronics, materials science, and bioengineering. Sinc, he has served as an Assistant Professor* in the Department of Electronic Engineering at Korea National University of Transportation (KNUT), where he leads research in soft bioelectronics and adaptive wearable systems. Prior to his faculty appointment, he worked as a Postdoctoral Researcher  in the Department of Chemical Engineering at Sungkyunkwan University, where he collaborated with Prof. Changhyun Pang on projects related to electroactive adhesives, self-healing materials, and next-generation skin-interfacing devices. During the same period, he was also a Visiting Researcher at KRISS (Korea Research Institute of Standards and Science) under the supervision of Dr. Minseok Kim, broadening his expertise in nanocharacterization and precision sensor design. His collaborative work has resulted in over high-impact publications, several  and journal features, including cover articles in Advanced Materials InfoMat, and ACS Nano. He has played both leading and corresponding author roles, underscoring his integral contributions.

Research Focus

Prof. Da Wan Kim’s research lies at the intersection of chemical engineering, materials science, and soft electronics, with a specific focus on bioinspired adhesives wearable sensors, and haptic human-machine interfaces. He explores the structure-property-function relationships of adaptive materials that interact seamlessly with human skin and biological environments. A hallmark of his research is the translation of biological adhesion mechanisms inspired by octopi, beetles, and amphibians—into engineered materials capable of wet/dry adhesion, electroactivity, and biocompatibility. These developments have applications in soft robotics, electronic skin (e-skin) and personalized healthcare devices. His recent work includes designing Marangoni-driven 3D microdomes for e-skin, self-healing micro-suction adhesives, and skin-adaptive optical sensors for biofluid analysis. He also investigates structural nanocomposites for energy harvesting, sensory feedback, and wireless communications in flexible systems. By combining*nanoengineering, functional polymers, and bioinspired mechanics, Prof. Kim’s lab develops platforms for autonomous, multifunctional, and sustainable soft electronics. His research contributes to the future of wearable healthcare XR technologies, and robotic interfaces aiming to bridge the physical and digital with comfort, intelligence, and adaptability.

Awards and Honors

Prof. Da Wan Kim has received significant academic recognition through featured journal covers, corresponding authorships, and international patent filings, reflecting the impact and novelty of his research in the fields of bioelectronics and functional materials. Multiple of his works have been selected for cover stories in prestigious journals such as Advanced Functional Materials ACS Nano Chemical Engineering Journal, and Advanced Materials Technologies. This includes the Inside Front Cover selection for his  article in Advanced Functional Materials on haptic interface platforms, and Back Cover features in Advanced Materials and Nano Research. These distinctions highlight the visual and scientific appeal of his designs, often inspired by octopus limbs, suction dynamics, or bioadaptive mechanisms. Prof. Kim has also co-invented more than  in South Korea and U.S.  related to adhesive materials, wearable devices, and sensor systems. His patents cover innovations such as vibration-resistant dry adhesives micro-absorbent hybrid patches, and fiber-based temperature sensors. Although early in his faculty career, his consistent publication record, interdisciplinary projects, and translational research achievements suggest a trajectory of continued recognition in academic and industrial spheres. His awards are evidence of his leadership in innovation-driven materials science.

Publication Top Notes

Bioinspired Hierarchical Soft Gripper with Hexagonal and Suction Interfaces for Strain-Guided Object Handling

Year 2025

Biodegradable Adhesive Interfaces for Bioelectronic and Biomedical Applications

Year 2025

Spatiotemporal molecular tracing of ultralow-volume biofluids via a soft skin-adaptive optical monolithic patch sensor

Year 2025

Development of Bioinspired Robotic Gripping Technology for Gripping Rough & Wet Surfaces based on Tactile Sensing

Year 2022

Conclusion

Prof. Da Wan Kim’s impressive research record, interdisciplinary approach, and high-impact publications make him an excellent candidate for the Best Researcher Award. His innovative research focus and collaboration skills demonstrate significant potential for continued contributions to the field. With some additional emphasis on expanding his research scope, mentorship, and broader societal impact, Prof. Kim’s application would be even stronger. Overall, he is a strong contender for the award.

Prof. Ruizi Li | Flexible Electronics | Best Researcher Award

Published on by Mechanics Awards

Prof. Ruizi Li | Flexible Electronics | Best Researcher Award 

Assoc. Prof, Northwestern Polytechnical University, China

Dr. Ruizi Li is a highly accomplished researcher with a strong background in materials science and engineering. With a prolific publication record and extensive experience in interdisciplinary research, Dr. Li has made significant contributions to the fields of hybrid X-ray scintillators, perovskite nanocrystals, and flexible electronics. Their work has been published in renowned journals such as Angewandte Chemie, Advanced Functional Materials, and npj Flexible Electronics. Dr. Li’s expertise and commitment to the scientific community are further demonstrated through their peer review contributions to esteemed journals.

Profile

Orcid

🎓 Education

Dr. Ruizi Li’s educational background is marked by a strong focus on materials science and engineering. Although specific details about their academic degrees are not provided, their research and publication record suggest a solid foundation in the principles of materials science, physics, and engineering. Dr. Li’s continuous involvement in cutting-edge research and their ability to collaborate with various researchers indicate a high level of academic achievement and expertise in their field.

👨‍🔬 Experience

With a substantial publication record and involvement in various research projects, Dr. Ruizi Li has accumulated significant experience in materials science and engineering. Their research spans multiple areas, including hybrid X-ray scintillators, perovskite nanocrystals, and flexible electronics. Dr. Li has also demonstrated the ability to work collaboratively with other researchers, contributing to successful projects and publications. Furthermore, their experience as a peer reviewer for prestigious journals highlights their expertise and recognition within the scientific community.

🔍 Research Interest

Dr. Ruizi Li’s research focus includes the development of hybrid X-ray scintillators, perovskite nanocrystals, and flexible electronics. Their work aims to innovate and improve the performance of these materials for various applications, including X-ray imaging and flexible electronics. Dr. Li’s research approach combines experimental and theoretical methods, demonstrating a comprehensive understanding of the materials and their properties. The goal of their research is to create materials and technologies that can be applied in real-world scenarios, enhancing performance and efficiency.

Awards and Honors

While specific awards and honors are not detailed in the provided information, Dr. Ruizi Li’s achievements and contributions to materials science and engineering suggest a strong potential for recognition. Their publication record, peer review activities, and collaborative research efforts demonstrate a commitment to excellence and a high level of expertise, which are often acknowledged through awards and honors in the scientific community.

Publications 

1. Bright and Fast‐Response Hybrid X‐Ray Scintillators by Molecular and Dielectric Confinement 🌟
2. Flash synthesis of high-performance and color-tunable copper(I)-based cluster scintillators for efficient dynamic X-ray imaging ⚡️
3. Photophysical Properties of Copper Halides with Strongly Confined Excitons and Their High-Performance X-Ray Imaging 📸
4. Ultrastable and flexible glass−ceramic scintillation films with reduced light scattering for efficient X−ray imaging 🔍
5. Size Effect on X‐ray Scintillation Performance for Perovskite Nanocrystals Revealed by Mathematical Model 📊
6. Intercalation pseudocapacitance in 2D N-doped V₂O₃ nanosheets for stable and ultrafast lithium-ion storage 🔋
7. Self-assembly of two-dimensional supramolecular as flame-retardant electrode for lithium-ion battery 🔥
8. Controllable assembling of highly-doped linked carbon bubbles on graphene microfolds 💡
9. Robust self-gated-carriers enabling highly sensitive wearable temperature sensors 🌡️
10. Stretchable and Ultrasensitive Intelligent Sensors for Wireless Human–Machine Manipulation 🤖
11. 3D Printed Flexible Strain Sensors: From Printing to Devices and Signals 🖨️
12. (1 1 0)-Bridged nanoblocks self-assembled VS₂ hollow microspheres as sodium-ion battery anode with superior rate capability and long cycling life 🔋
13. A sandwich-like porous hard carbon/graphene hybrid derived from rapeseed shuck for high-performance lithium-ion batteries 🥜
14. Facile synthesis of tetragonal NaV₂O₅·H₂O nanosheets co-intercalated by high content of Na⁺ and H₂O for boosted lithium storage 💧
15. Facile Synthesis of Three-dimensional Hierarchical Ni₃S₂@CoAl-LDHs Nanosheet Arrays and Their Efficient Hydrogen Evolution ⚗️
16. Mo-Doped ultrafine VC nanoparticles confined in few-layer graphitic nanocarbon for improved electrocatalytic hydrogen evolution 💡
17. Nitrogen-Doped Hard Carbon on Nickel Foam as Free-Standing Anodes for High-Performance Sodium-Ion Batteries 🌟
18. Nitrogen-doped porous hard carbons derived from shaddock peel for high-capacity lithium-ion battery anodes 🍊
19. Structure Engineering in Biomass-Derived Carbon Materials for Electrochemical Energy Storage 🌿
20. Sulfur-doped shaddock peel–derived hard carbons for enhanced surface

Conclusion

Dr. Ruizi Li is a highly accomplished researcher with a strong publication record, innovative contributions, and a collaborative approach. Their work in materials science and engineering has significant potential for practical applications and industrial impact. With some focus on practical applications, diverse funding sources, and public engagement, Dr. Li is an excellent candidate for the Best Researcher Award.