Keivan Narooei | Engineering | Editorial Board Member

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Assoc. Prof. Dr. Keivan Narooei | Engineering | Editorial Board Member

K. N. Toosi University of Technology | Iran

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Early Academic Pursuits ✨

Assoc. Prof. Dr. Keivan Narooei's journey into the field of materials science and engineering began with a strong academic foundation. He earned his Bachelor of Science in Materials Science and Engineering from Isfahan University of Technology in 2002. With a keen interest in computational mechanics and finite element modeling, he pursued his Master of Science at the prestigious Sharif University of Technology, completing it in 2004. His academic dedication culminated in a Ph.D. in Finite Element Method (FEM) from the same institution in 2009. His doctoral studies equipped him with a profound understanding of mechanical behavior modeling, setting the stage for his future research contributions.

Professional Endeavors 🌟

Dr. Narooei has established himself as a leading academic and researcher in materials science. He currently serves as an Associate Professor at K. N. Toosi University of Technology, a renowned institution in Iran. Throughout his academic career, he has been instrumental in advancing research in computational modeling, hyperelasticity, and smart materials. His role as a mentor and educator has inspired numerous students to delve into the complexities of materials science and engineering.

Contributions and Research Focus πŸ“š

Dr. Narooei's research encompasses various groundbreaking topics in mechanical behavior analysis and materials modeling. His primary areas of expertise include:

  • Plasticity: Investigating the deformation and mechanical behavior of materials under stress.
  • Shape Memory Polymers (SMPs): Exploring smart materials with the ability to recover their shape upon external stimulus.
  • Self-Healing Hydrogels: Developing bio-composite materials with self-repairing capabilities.
  • Hyperelasticity & Viscoelasticity: Studying advanced materials with unique mechanical responses for biomedical and industrial applications.

His work in these fields has led to numerous influential publications in high-impact journals, contributing significantly to advancements in materials science.

Accolades and Recognition πŸ†

Dr. Narooei's research has gained widespread recognition in the academic community. His contributions to 4D printing, smart materials, and bio-composites have been cited extensively. Some of his most notable publications include:

  • "4D printing of shape memory polylactic acid beams: An experimental investigation into FDM additive manufacturing process parameters, mathematical modeling, and optimization" (Journal of Manufacturing Processes, 2023).
  • "A hyperelastic-damage model to study the anisotropic mechanical behavior of coral-hydrogel bio-composite" (Journal of the Mechanical Behavior of Biomedical Materials, 2022).
  • "Strain rate-dependent mechanical metamaterials" (Science Advances, 2020).

His work has received accolades from peers and institutions, recognizing his innovative approach to materials modeling and smart material applications.

Impact and Influence πŸ’ͺ

Dr. Narooei’s research has made a significant impact on the development of advanced materials with real-world applications. His studies on self-healing hydrogels and hyperelastic materials have influenced both biomedical engineering and industrial applications. His work in computational modeling has paved the way for more accurate simulations of material behaviors, essential for designing next-generation smart materials. Beyond research, Dr. Narooei has played a crucial role in mentoring young researchers, guiding them toward impactful scientific contributions. His teaching at K. N. Toosi University of Technology has nurtured a new generation of engineers and scientists specializing in material behavior and computational mechanics.

Legacy and Future Contributions πŸ”

Looking ahead, Dr. Narooei continues to push the boundaries of materials science with innovative research in smart and bio-inspired materials. His work in 4D printing is expected to revolutionize manufacturing processes, while his studies on self-healing materials hold promise for medical applications, such as tissue engineering and prosthetics. As an influential figure in his field, Dr. Narooei’s legacy lies in his contributions to cutting-edge materials research and his dedication to fostering academic excellence. His future endeavors will undoubtedly shape the development of smarter, more resilient materials, leaving a lasting impact on both academia and industry.

 

Publications

  • πŸ“„ A micromechanical model to predict the effective thermomechanical behavior of one-way shape memory polymers
    Journal: Mechanics of Materials
    Year: 2025-02
    Authors: M. Bakhtiari, K. Narooei

  • πŸ“„ Investigation of multiplicative decompositions in the form of FeFv and FvFe to extend viscoelasticity laws from small to finite deformations
    Journal: Mechanics of Materials
    Year: 2022-04
    Authors: Marzieh Bahreman, Hossein Darijani, Keivan Narooei

  • πŸ“„ A hyperelastic-damage model to study the anisotropic mechanical behavior of coral-hydrogel bio-composite
    Journal: Journal of the Mechanical Behavior of Biomedical Materials
    Year: 2022-02
    Authors: R. Eghbali, K. Narooei

  • πŸ“„ Strain rate–dependent mechanical metamaterials
    Journal: Science Advances
    Year: 2020-06-17
    Authors: S. Janbaz, K. Narooei, T. van Manen, A. A. Zadpoor

  • πŸ“„ A new hyper-viscoelastic model for investigating rate dependent mechanical behavior of dual cross link self-healing hydrogel
    Journal: International Journal of Mechanical Sciences
    Year: 2019-08
    Authors: A. Ghorbanoghli, K. Narooei

 

Hyoungsoo Kim | Engineering | Best Researcher Award

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Assoc. Prof. Dr. Hyoungsoo Kim | Engineering | Best Researcher Award

KAIST | South Korea

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πŸŽ“ Early Academic Pursuits

Assoc. Prof. Dr. Hyoungsoo Kim began his academic journey with a deep-rooted passion for fluid mechanics and engineering. He earned his Bachelor's degree in Mechanical Engineering from Kumoh National Institute of Technology, South Korea, graduating Summa Cum Laude in 2006. His undergraduate research focused on numerical analysis of microflows in microchannels. Continuing his academic excellence, he pursued a Master’s degree at KAIST, where he worked on controlling electroosmotic flow in microchannels using thermal fields. His doctoral studies at Delft University of Technology in the Netherlands further honed his expertise, culminating in a thesis titled Moving Liquid Droplets with Inertia: Experiment, Simulation, and Theory, under the guidance of Professor Jerry Westerweel.

🎨 Professional Endeavors

Dr. Kim's professional journey reflects an unwavering commitment to experimental fluid mechanics and interdisciplinary research. His early postdoctoral experience at Seoul National University and Princeton University, where he worked with Professor Ho-Young Kim and Professor Howard A. Stone, respectively, laid the foundation for his groundbreaking research. He served as an Associate Research Scholar at Princeton before joining KAIST as an Assistant Professor in 2017. In 2021, he was promoted to Associate Professor at KAIST’s Department of Mechanical Engineering. Dr. Kim has also contributed as a Visiting Scholar at Harvard University’s School of Engineering and Applied Sciences and as an Editorial Advisory Board Member for Experiments in Fluids since 2019.

πŸ‘©β€πŸ”¬ Contributions and Research Focus

Dr. Kim's research revolves around experimental fluid mechanics, focusing on physicochemical hydrodynamics, thin film and interfacial flows, colloids and interfaces, and micro- and bio-fluidics. His work spans multiple scales, from nanoscale to macroscale, with applications in environmental pollution, COVID-19-related respiratory diseases, and material transport in multiscale channels. Leveraging advanced optical measurement techniques, he explores interfacial instabilities, droplet dynamics, viscoelastic fluid behavior, and evaporation processes. His research has resulted in significant theoretical models and scaling analyses that contribute to the understanding of multiphase flows and soft matter hydrodynamics.

πŸ† Accolades and Recognition

Dr. Kim's exceptional contributions to fluid mechanics and engineering have been widely recognized. He has secured over $5.5 million USD in research grants since joining KAIST and has published 49 high-impact journal papers, including articles in Nature Physics, Nature Communications, ACS Nano, Advanced Science, and Physical Review Letters. His research has received 2,241 citations, with an H-index of 23 and an FWCI of 1.69 in Mechanical Engineering. Some of his studies have been highlighted in Physics, Nature Physics, The New York Times, and Chosun Ilbo. His patent portfolio includes numerous domestic and international patents related to medical devices, negative pressure systems, and quantum dot patterning technologies.

🌐 Impact and Influence

Dr. Kim’s research has far-reaching implications across multiple disciplines. His work on interfacial instability and solutal-Marangoni flows has advanced the understanding of complex fluid behaviors. His patented technologies, including cyclone negative pressure masks and modular negative pressure facilities, have been pivotal in enhancing personal protective equipment and medical chamber designs. Moreover, his studies on liquid metal and metamaterials have influenced the development of stretchable electronics and anti-icing coatings. His collaborations with industrial partners such as Shinsung E&G and Woojung Bio have facilitated technology transfer, further extending the impact of his research into real-world applications.

🌟 Legacy and Future Contributions

As a leading figure in experimental fluid mechanics, Dr. Kim continues to push the boundaries of interfacial hydrodynamics and multiphase flows. His work is expected to drive innovations in biomedical engineering, environmental sustainability, and advanced materials. His commitment to mentoring young researchers and fostering interdisciplinary collaborations ensures that his legacy will endure through the next generation of scientists and engineers. With ongoing research projects in nanofluidics, soft matter physics, and energy-efficient transport systems, Dr. Kim remains at the forefront of pioneering fluid mechanics research, shaping the future of the field.

 

Publications

  • πŸ“„ Cyclone negative pressure pump for efficient purification of airborne contaminants

    • Journal: Indoor Environments
    • Year: 2025
    • Authors: Gihyun Song, Kyungcheol Jang, Woobin Song, Wonchul Choi, Simon Song, Hyoungsoo Kim

  • πŸ“„ Single theoretical model for breakup of viscous thread with and without a fiber

    • Journal: Physical Review Fluids
    • Year: 2024
    • Authors: Hyejoon Jun, Hyoungsoo Kim

  • πŸ“„ Prediction of curing depth dependence on CNT nanofiller dispersion for vat photopolymerization 3D printing

    • Journal: Chemical Engineering Journal
    • Year: 2024
    • Authors: Taehyub Lee, Jeong-Hwan Kim, Chin Siang Ng, Alberto Andreu, Insup Kim, Wonhee Lee, Hyoungsoo Kim, Pei-Chen Su, Yong-Jin Yoon

  • πŸ“„ Vapor distribution changes evaporative flux profiles of a sessile droplet

    • Journal: Journal of Colloid and Interface Science
    • Year: 2023
    • Authors: Minhyeok Kuk, Jeongsu Pyeon, Hyoungsoo Kim

  • πŸ“„ Plasmonic metasurfaces of cellulose nanocrystal matrices with quadrants of aligned gold nanorods for photothermal anti-icing

    • Journal: Nature Communications
    • Year: 2023
    • Authors: Jeongsu Pyeon, Soon Mo Park, Juri Kim, Jeong-Hwan Kim, Yong-Jin Yoon, Dong Ki Yoon, Hyoungsoo Kim