Juan de Pablo | Materials Science | Best Researcher Award

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Prof. Juan de Pablo | Materials Science | Best Researcher Award

Professor and Vice President at New York University, United States

Dr. Juan José de Pablo is an internationally recognized leader in molecular engineering and materials science, currently serving as Professor and Vice President at New York University. With a distinguished academic and professional trajectory spanning over three decades, Dr. de Pablo has made pioneering contributions to soft matter physics, polymer engineering, and computational materials science. He has authored over 700 peer-reviewed publications and holds an H-index exceeding 120, reflecting the profound influence of his research. His recent roles include Executive Vice President for Global Science and Technology and Executive Dean of the Tandon School of Engineering at NYU, following a decade-long tenure at the University of Chicago. At the latter, he directed pivotal research centers and contributed to national laboratories like Argonne and Fermilab. A member of the U.S. National Academies of Engineering and Sciences, Dr. de Pablo’s interdisciplinary approach integrates theory, computation, and experimentation. His leadership in establishing large-scale scientific initiatives and educational outreach reflects a deep commitment to innovation, mentorship, and societal impact through science.

Professional Profile

Education

Dr. de Pablo began his academic journey with a Bachelor’s degree in Chemical Engineering from the National University of Mexico (UNAM) in 1985. He proceeded to earn a Ph.D. in Chemical Engineering from the University of California, Berkeley in 1990, a period during which he laid the foundation for his interest in polymeric systems and thermodynamics. Following this, he undertook a postdoctoral fellowship at ETH Zurich’s Institute for Polymers from 1990 to 1992, specializing in materials science. These formative years were instrumental in shaping his interdisciplinary research vision, blending rigorous theoretical training with practical insights. His educational background demonstrates a consistent trajectory toward advanced computational and molecular-level analysis of soft matter. The combination of leading North American and European institutions in his training reflects the global dimension of his perspective on science and engineering. These experiences equipped him with the skills to later lead international collaborations and scientific enterprises that bridge multiple disciplines, from nanotechnology to biophysics.

Professional Experience

Dr. de Pablo’s professional career is marked by leadership in academia, research management, and global scientific strategy. His early academic appointments were at the University of Wisconsin, where he progressed from Assistant to Full Professor of Chemical Engineering between 1992 and 2012. During this period, he also served as Director of the Materials Research Science and Engineering Center (MRSEC) and Deputy Director of the Nanoscale Science and Engineering Center (NSEC), driving frontier research in materials design and nanotechnology. In 2012, he joined the University of Chicago as the Liew Family Professor in the Institute for Molecular Engineering and Senior Scientist at Argonne National Laboratory. He later held multiple vice-presidential roles, overseeing national laboratories and leading global science initiatives. Currently, as Executive Vice President for Global Science and Technology and Executive Dean of NYU’s Tandon School of Engineering, he continues to shape science policy, innovation ecosystems, and advanced education. His leadership roles at UChicago-Argonne LLC and the Center for Hierarchical Materials Design (CHiMaD) further underscore his expertise in strategic research development and interdisciplinary collaboration.

Research Interest

Dr. de Pablo’s research interests span a broad spectrum within molecular and materials engineering, including soft condensed matter, computational thermodynamics, polymer physics, and biomolecular simulations. He has been instrumental in developing novel simulation techniques that enable a molecular-level understanding of materials behavior under complex conditions. His work frequently integrates theoretical frameworks with experimental data, enabling predictive modeling of systems ranging from liquid crystals to nucleic acids. More recently, he has expanded into machine learning-guided materials discovery and the design of functional materials for health, sustainability, and electronics. He is also deeply engaged in the Materials Genome Initiative, contributing to the national agenda for accelerating materials innovation. Dr. de Pablo’s research not only advances fundamental science but also facilitates translational outcomes, such as in the stabilization of biologics, nanofabrication, and soft robotics. His interdisciplinary and collaborative approach has positioned him at the forefront of modern materials science, with sustained funding from national agencies and partnerships with industry.

Research Skills

Dr. de Pablo’s research skills are characterized by exceptional breadth and depth in theoretical, computational, and applied materials science. He has pioneered algorithms for calculating free energies, explored phase transitions in complex fluids, and designed coarse-grained models for large biomolecules. His fluency in molecular dynamics, Monte Carlo simulations, and density-of-states methods is complemented by expertise in high-performance computing and GPU acceleration. He applies these tools to problems in polymer behavior, nanostructured materials, and biointerfaces. Dr. de Pablo also has deep knowledge of lithography, directed self-assembly, and patterning technologies, as evidenced by his multiple U.S. patents in these areas. Moreover, he plays a leading role in training the next generation of scientists, having supervised over 70 Ph.D. students. His entrepreneurial activities and editorial roles reflect a commitment to disseminating innovation and shaping the scientific discourse. These research capabilities, coupled with leadership in large-scale initiatives and advisory committees, make Dr. de Pablo a uniquely effective figure in both advancing science and mentoring talent.

Awards and Honors

Dr. de Pablo’s illustrious career has been recognized with over 60 prestigious awards, fellowships, and honors, reflecting his outstanding contributions to science, education, and leadership. Early in his career, he received multiple young investigator awards from the NSF, IBM, Xerox, and 3M. Notably, he was honored with the Presidential Early Career Award in Science and Engineering (PECASE) and the Presidential Faculty Fellow Award by President Clinton. He has since delivered over 40 named lectures, including the Paul Flory, Marie Curie, and Samuel C. Johnson Distinguished Lectures. Dr. de Pablo is an elected Fellow of the American Physical Society, American Academy of Arts and Sciences, and a Member of both the National Academy of Engineering and National Academy of Sciences. His recent recognitions include the Polymer Physics Prize, DuPont Medal for Excellence, and international accolades such as the Chevalier de l’Ordre du Mérite (France). These honors highlight not only his scientific excellence but also his impact as an educator, innovator, and global science diplomat.

Conclusion

Dr. Juan José de Pablo’s career exemplifies the integration of scientific brilliance, visionary leadership, and a deep commitment to global collaboration and mentorship. From his foundational training in Mexico and the U.S. to his leadership at premier institutions like the University of Chicago and NYU, he has continuously advanced the frontiers of molecular engineering and materials science. His interdisciplinary research, extensive publication record, and innovative patent portfolio showcase both depth and translational relevance. Beyond his technical achievements, Dr. de Pablo’s influence on science policy, education, and diversity initiatives reflects a holistic vision for the role of science in society. As an advisor, editor, and entrepreneur, he fosters environments where cutting-edge research meets real-world challenges. His legacy is further amplified through the numerous students and researchers he has mentored, many of whom have become leaders in their own right. Dr. de Pablo remains an inspirational figure whose work bridges disciplines, institutions, and continents in the pursuit of scientific progress and societal advancement.

Publications Top Notes

Title: Water-mediated ion transport in an anion exchange membrane
Authors: Juan J De Pablo
Year: 2025
Citations: 2

Title: Structural studies of the IFNλ4 receptor complex using cryoEM enabled by protein engineering
Authors: Juan J De Pablo
Year: 2025
Citations: 1

Title: Free-Energy Landscapes and Surface Dynamics in Methane Activation on Ni(511) via Machine Learning and Enhanced Sampling
Authors: Juan J De Pablo
Year: 2025

Title: Synthetic Active Liquid Crystals Powered by Acoustic Waves
Authors: Juan J De Pablo
Year: 2025

Title: Current Advances in Genome Modeling Across Length Scales
Authors: Juan J De Pablo
Year: 2025

Title: Chromatin structures from integrated AI and polymer physics model
Authors: Juan J De Pablo
Year: 2025
Citations: 1

Title: A Twist on Controlling the Equilibrium of Dynamic Thia-Michael Reactions
Authors: Juan J De Pablo
Year: 2025

Title: Bio-Based Surfactants via Borrowing Hydrogen Catalysis
Authors: Juan J De Pablo
Year: 2025

Title: Efficient sampling of free energy landscapes with functions in Sobolev spaces
Authors: Juan J De Pablo
Year: 2025
Citations: 1

Title: 3D Nano-architected Polymer Shell Enables Reconfigurable Stabilized Blue Phase Soft Crystals
Authors: Juan J De Pablo
Year: 2025

Yi Lu | Material Science | Best Researcher Award

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Dr. Yi Lu | Material Science | Best Researcher Award

Beijing University of Technology, China

Dr. Yi Lu is a dedicated researcher and academic at the School of Materials Science and Engineering, Beijing University of Technology. With a strong focus on aluminum alloys, Dr. Lu has developed a deep expertise in understanding the intricate relationship between their mechanical properties and microstructure. Over the course of her academic journey, she has been actively involved in a national key research and development project, contributing significantly to the advancement of materials science in China. Dr. Lu has authored multiple peer-reviewed journal articles, including four SCI-indexed papers, two of which are published in top-tier SCI1 journals. Her research outputs have garnered six citations to date, reflecting the growing relevance of her work in the scientific community. She has also established international research collaboration with the University of Auckland, further enhancing the global dimension of her academic contributions. Although early in her career, Dr. Lu’s commitment to innovation and excellence positions her as a promising figure in the field. Her work encompasses both theoretical and applied aspects of materials science, with special attention to corrosion behavior, hydrogen embrittlement, and refining processes in aluminum alloys. Driven by a passion for discovery, Dr. Lu continues to push the boundaries of research and make meaningful contributions to her field.

Professional Profiles

Education

Dr. Yi Lu pursued her academic training in materials science with a strong emphasis on metal research, particularly aluminum alloys. She earned her advanced degrees from reputable institutions that laid a strong foundation for her scientific pursuits. Throughout her studies, she demonstrated exceptional analytical and experimental skills, which were honed through hands-on laboratory work and advanced coursework in metallurgy, corrosion science, mechanical behavior of materials, and materials processing. Her educational journey emphasized the integration of theoretical knowledge with experimental application, preparing her to explore complex research topics such as microstructural characterization and failure mechanisms in metals. During her graduate studies, she was actively involved in collaborative research, presenting her work at seminars and contributing to peer-reviewed publications. These academic experiences sharpened her ability to approach scientific challenges methodically and rigorously. Her thesis focused on understanding the influence of microstructure on the mechanical and corrosion properties of aluminum alloys, a subject that continues to underpin her current research. The depth of her education, coupled with her persistent curiosity and discipline, has equipped Dr. Lu with the tools necessary to make substantial contributions in the field of materials science. Her academic background continues to serve as a vital pillar supporting her professional research and innovation.

Professional Experience

Currently serving as a researcher at the School of Materials Science and Engineering, Beijing University of Technology, Dr. Yi Lu plays a crucial role in advancing the institution’s research capabilities in metallic materials. Her professional work is centered around aluminum alloys, exploring key issues related to their mechanical properties, corrosion behavior, and hydrogen embrittlement mechanisms. Dr. Lu has been a vital team member in a national key research and development project, where she contributed to the experimental design, materials testing, and analysis of microstructural transformations. This project offered her a platform to apply her academic knowledge to real-world problems, bridging the gap between theory and industrial application. She has also authored several SCI-indexed journal articles, establishing her as a published researcher with international reach. Her professional collaborations extend beyond China, as evidenced by her research partnership with the University of Auckland. These experiences have strengthened her ability to work in cross-cultural, interdisciplinary teams and have enriched her understanding of global research dynamics. While Dr. Lu has not yet engaged in consultancy or industry-specific projects, her academic and project-based experience positions her well for future involvement in industrial research, particularly in sectors where material durability and performance are critical.

Research Interest

Dr. Yi Lu’s research interests lie at the intersection of materials science and engineering, with a strong focus on the behavior and performance of aluminum alloys. Her primary areas of investigation include the mechanical properties of aluminum alloys and how these are influenced by microstructural features. She is particularly intrigued by the factors that govern the corrosion resistance of these materials, an issue of critical importance in industries such as aerospace, automotive, and construction. Dr. Lu also explores various refining techniques to enhance the purity and structural uniformity of aluminum alloys. One of the more specialized aspects of her work is the study of hydrogen embrittlement—an often overlooked but significant phenomenon that compromises the integrity of metals. Through her research, she seeks to understand the mechanisms behind hydrogen-induced failures and propose mitigation strategies. These interconnected areas form a cohesive framework that allows Dr. Lu to address both fundamental questions and practical challenges in materials performance. Her interests are not only driven by academic curiosity but also by the broader societal need for more resilient, lightweight, and corrosion-resistant materials. By focusing her research on these critical topics, she aims to contribute to the development of next-generation metallic materials with enhanced longevity and reliability.

Research Skills

Dr. Yi Lu possesses a robust set of research skills that enable her to tackle complex problems in materials science with precision and innovation. She is proficient in a wide range of experimental techniques used to analyze the mechanical and corrosion behavior of metals, particularly aluminum alloys. Her expertise includes mechanical testing methods such as tensile, hardness, and fatigue analysis, which she uses to assess the structural integrity of alloys. In addition, she is skilled in metallographic examination and advanced microscopy, including scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDS), allowing her to investigate microstructural features at fine resolutions. Dr. Lu is also experienced in electrochemical testing methods, which are essential for understanding corrosion kinetics and resistance. Her analytical skills extend to data interpretation and modeling, ensuring that experimental findings are rigorously evaluated and contextually grounded. Furthermore, she demonstrates competence in scientific writing and has successfully published in high-impact SCI journals. Her collaborative research experience with the University of Auckland highlights her ability to contribute to international projects and interdisciplinary teams. Whether conducting experiments, interpreting results, or drafting manuscripts, Dr. Lu consistently applies scientific rigor and attention to detail, making her a capable and well-rounded researcher in her field.

Awards and Honors

Although Dr. Yi Lu is in the early stages of her academic and research career, she has already achieved notable recognition for her contributions to materials science. Her most significant honor to date is her participation in a national key research and development project, a competitive and prestigious initiative that selects promising researchers to contribute to groundbreaking scientific work. In this project, Dr. Lu’s role was instrumental in generating valuable findings related to aluminum alloy performance. She has published four SCI-indexed papers and one EI paper, with two articles appearing in high-impact SCI1 journals—an accomplishment that reflects both the quality and relevance of her research. Her work has received six citations, an encouraging indicator of her growing impact within the academic community. Dr. Lu has also been nominated for the Best Researcher Award, a testament to her dedication and early academic promise. These accolades, while still accumulating, signify her upward trajectory in the field. As she continues to publish, collaborate, and contribute to material science research, Dr. Lu is poised to garner more awards and recognition. Her commitment to excellence and innovation lays the groundwork for future honors at both national and international levels.

Conclusion

Dr. Yi Lu exemplifies the qualities of a dedicated and forward-thinking researcher in the field of materials science and engineering. Her academic journey and professional work are unified by a clear focus on improving the performance and durability of aluminum alloys, which are critical to a wide range of industrial applications. Through rigorous experimentation, international collaboration, and scholarly publication, she has demonstrated the ability to contribute meaningful insights to her discipline. Her areas of expertise—including mechanical behavior, corrosion mechanisms, refining methods, and hydrogen embrittlement—address some of the most pressing challenges in metallic materials. Despite being at an early stage in her career, Dr. Lu’s accomplishments—such as participation in a national research initiative and publications in high-tier journals—highlight her potential for future leadership in research and innovation. She continues to refine her experimental techniques, expand her scientific understanding, and seek impactful collaborations. Looking ahead, Dr. Lu aims to further integrate her theoretical knowledge with practical applications, ultimately contributing to the design and development of materials that are stronger, lighter, and more resistant to environmental stress. Her dedication to scientific progress and her methodical approach to research ensure that she will remain a valuable asset to her institution and the global materials science community.

 Publications Top Notes

  1. Title: High thermal stability of Si-containing Al-Zn-Mg-Cu crossover alloy caused by metastable GPB-II phase
    Authors: Yi Lu, Shengping Wen, Wu Wei, Xiaolan Wu, Kunyuan Gao, Hui Huang, Zuoren Nie
    Year: 2025

  2. Title: The enhanced aging hardening behavior in Si-containing Al-5Zn-1Mg-1Cu alloys
    Authors: Yi Lu, Shengping Wen, Zuoren Nie
    Year: 2024

  3. Title: The phase transformation and enhancing mechanical properties in high Zn/Mg ratio Al–Zn–Mg–Cu(-Si) alloys
    Authors: Yi Lu, Shengping Wen, Kunyuan Gao, Xiangyuan Xiong, Wu Wei, Xiaolan Wu, Hui Huang, Zuoren Nie
    Year: 2024

  4. Title: TeleAware Robot: Designing Awareness-augmented Telepresence Robot for Remote Collaborative Locomotion
    Authors: Ruyi Li, Yaxin Zhu, Min Liu, Yihang Zeng, Shanning Zhuang, Jiayi Fu, Yi Lu, Guyue Zhou, Can Liu, Jiangtao Gong
    Year: 2024

Christos Mytafides | Nanotechnology Innovations | Innovation in Science Award

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Dr. Christos Mytafides | Nanotechnology Innovations | Innovation in Science Award

Postdoctoral Researcher From Technical University of Crete, Greece

Christos K. Mytafides is a dedicated researcher specializing in advanced multifunctional energy-harvesting materials. His expertise spans printed electronics, structural composites, and renewable energy applications. He is currently a Postdoctoral Research Scientist at the Physical Chemistry & Chemical Processes Laboratory at the Technical University of Crete. His previous roles include PhD research positions at the University of Ioannina, the University of Miami, and Eindhoven University of Technology. His research primarily focuses on integrating energy-harvesting capabilities into composite materials, particularly through thermoelectric and optoelectronic technologies. His academic background includes a PhD and master’s degrees in Materials Science & Engineering, as well as Environmental Engineering. With numerous publications in high-impact journals and multiple prestigious scholarships, including the Fulbright Scholarship, Mytafides continues to contribute significantly to the field of sustainable energy technologies. His work has practical implications for developing next-generation materials with enhanced energy efficiency, sustainability, and functionality.

Professional Profiles

Education

Christos K. Mytafides holds a PhD in Materials Science & Engineering from the University of Ioannina, where he specialized in advanced multifunctional energy-harvesting materials. His doctoral research focused on integrating printed electronics with energy-harvesting capabilities in advanced structural composites. Prior to his PhD, he earned a Master’s Degree in Advanced Materials from the University of Ioannina, specializing in optoelectronic and magnetic materials. His master’s thesis explored the design and efficiency enhancement of dye-sensitized solar cells through plasmonic nanoparticles. Additionally, he obtained another Master’s Degree in Environmental Engineering & Science from Democritus University of Thrace, where he focused on energy-efficient design and renewable energy applications. His thesis investigated transforming a university building into a zero-energy structure. His diverse academic background has provided him with a strong foundation in materials science, optoelectronics, nanotechnology, and sustainable energy solutions, all of which play a crucial role in his ongoing research contributions.

Professional Experience

Mytafides has amassed extensive experience in academia and research, with notable positions at prestigious institutions. Currently, he is a Postdoctoral Research Scientist at the Technical University of Crete’s Physical Chemistry & Chemical Processes Laboratory. Previously, he was a PhD Researcher at the University of Ioannina, where he explored multifunctional energy-harvesting materials. He also conducted research at the Advanced Nano Systems Laboratory at the University of Miami, focusing on multifunctional composites with embedded photo-thermal energy-harvesting capabilities. During a research traineeship at Eindhoven University of Technology, he worked on innovative solar cell materials and designs. His expertise includes additive manufacturing, thermoelectric generators, and carbon-based flexible electronics. His work integrates advanced material processing techniques with real-world applications, leading to the development of next-generation energy solutions. Mytafides’ research contributions are widely recognized, making him a key figure in energy-harvesting composite materials.

Research Interests

Mytafides’ research interests center on developing multifunctional materials for energy harvesting and sustainable applications. His work involves integrating printed electronics into composite materials to create energy-efficient structures. He is particularly interested in thermoelectric and optoelectronic materials, which have the potential to revolutionize energy sustainability. His expertise extends to carbon-based nanostructures, additive manufacturing, and hybrid energy systems that combine solar and thermal energy harvesting. By utilizing advanced material synthesis and characterization techniques, Mytafides aims to enhance energy conversion efficiency in various applications, including smart materials and green technologies. His work aligns with global efforts to develop innovative solutions for renewable energy and energy-efficient materials, with applications in aerospace, automotive, and structural engineering. His research contributions have been published in high-impact journals, highlighting his significant role in advancing sustainable energy solutions.

Research Skills

Mytafides possesses extensive research skills in materials science, nanotechnology, and energy harvesting. He is proficient in advanced material characterization techniques such as spectroscopy, electron microscopy, and thermal analysis. His expertise in additive manufacturing enables him to develop highly conductive carbon-based structures for flexible thermoelectric applications. He has experience with composite materials engineering, particularly in integrating energy-harvesting functionalities into fiber-reinforced polymers. His computational skills include simulation and modeling of energy conversion processes, optimizing material performance for real-world applications. Additionally, he has hands-on experience with printed electronics, allowing him to design and fabricate novel energy-efficient devices. His interdisciplinary approach combines experimental research with theoretical insights, leading to the development of high-performance materials for sustainable applications. His skillset makes him a valuable contributor to advancements in renewable energy and smart material technologies.

Awards and Honors

Mytafides has received numerous awards and distinctions for his research excellence. He was awarded the prestigious Fulbright Scholarship for PhD research at the University of Miami, where he studied multifunctional composites with embedded photo-thermal energy-harvesting capabilities. He also received funding from the Hellenic Foundation for Research and Innovation and the National Strategic Reference Framework for his doctoral research. Additionally, he participated in the Erasmus+ Mobility program, which supported his research traineeship at Eindhoven University of Technology. His contributions have been recognized through multiple fellowships and research grants, reflecting his impact on the field of materials science and energy harvesting. These accolades highlight his commitment to advancing sustainable technologies and his ability to conduct high-impact research in collaboration with international institutions.

Conclusion

Christos K. Mytafides is a distinguished researcher in the field of advanced multifunctional energy-harvesting materials. His expertise in materials science, nanotechnology, and energy-efficient design has led to significant contributions in printed electronics, composite materials, and renewable energy technologies. His academic journey, spanning multiple prestigious institutions, has equipped him with the necessary skills and knowledge to develop next-generation sustainable energy solutions. His research has been widely recognized, with numerous publications, awards, and funded projects supporting his work. As a Postdoctoral Research Scientist, he continues to explore innovative ways to enhance energy conversion efficiency, aiming to develop smart, sustainable materials for various applications. His dedication to interdisciplinary research and collaboration ensures that his work remains at the forefront of scientific advancements in energy harvesting and materials engineering.

 Publications Top Notes

  1. Advanced functionalization of carbon fiber-reinforced polymer composites towards enhanced hybrid 4-terminal photo-thermal energy harvesting devices by integrating dye-sensitized solar cells and thermoelectric generators

    • Authors: Mytafides, Christos K.; Tzounis, Lazaros; Prouskas, Costas; Yentekakis, Ioannis V.; Paipetis, Alkiviadis S.

    • Year: 2025

  2. A hierarchically modified fibre-reinforced polymer composite laminate with graphene nanotube coatings operating as an efficient thermoelectric generator

    • Authors: Mytafides, Christos K.; Tzounis, Lazaros; Tsirka, Kyriaki; Karalis, George; Liebscher, Marco; Lambrou, Eleftherios; Gergidis, Leonidas; Paipetis, Alkiviadis

    • Year: 2024

  3. Additive manufacturing of highly conductive carbon nanotube architectures towards carbon-based flexible thermoelectric generators

    • Authors: Mytafides, Christos K.; Wright, William J.; Gustinvil, Raden; Tzounis, Lazaros; Karalis, George; Paipetis, Alkiviadis; Celik, Emrah

    • Year: 2024

  4. Carbon fiber/epoxy composite laminates as through-thickness thermoelectric generators

    • Authors: Karalis, George; Tzounis, Lazaros; Tsirka, Kyriaki; Mytafides, Christos K.; Liebscher, Marco; Paipetis, Alkiviadis

    • Year: 2022

  5. Automated detection-classification of defects on photo-voltaic modules assisted by thermal drone inspection

    • Authors: Gurras, Arsenios; Gergidis, Leonidas; Mytafides, Christos K.; Tzounis, Lazaros; Paipetis, Alkiviadis S.

    • Year: 2021

  6. Fully printed and flexible carbon nanotube-based thermoelectric generator capable for high-temperature applications

    • Authors: Mytafides, Christos K.; Tzounis, Lazaros; Karalis, George; Formanek, Petr; Paipetis, Alkiviadis

    • Year: 2021

  7. Printed Single-Wall Carbon Nanotube-Based Joule Heating Devices Integrated as Functional Laminae in Advanced Composites

    • Authors: Karalis, George; Tzounis, Lazaros; Dimos, Evangelos; Mytafides, Christos K.; Liebscher, Marco; Karydis-Messinis, Andreas; Zafeiropoulos, Nikolaos E.; Paipetis, Alkiviadis

    • Year: 2021

  8. A high-performance flexible and robust printed thermoelectric generator based on hybridized Te nanowires with PEDOT:PSS

    • Authors: Karalis, George; Tzounis, Lazaros; Mytafides, Christos K.; Tsirka, Kyriaki; Formanek, Petr; Stylianakis, Minas M.; Kymakis, Emmanuel; Paipetis, Alkiviadis S.

    • Year: 2021

  9. Advanced Glass Fiber Polymer Composite Laminate Operating as a Thermoelectric Generator: A Structural Device for Micropower Generation and Potential Large-Scale Thermal Energy Harvesting

    • Authors: Karalis, George; Tzounis, Lazaros; Tsirka, Kyriaki; Mytafides, Christos K.; Itskaras, Angelos Voudouris; Liebscher, Marco; Lambrou, Eleftherios; Gergidis, Leonidas N.; Barkoula, Nektaria-Marianthi; Paipetis, Alkiviadis

    • Year: 2021

  10. An Approach toward the Realization of a Through-Thickness Glass Fiber/Epoxy Thermoelectric Generator

  • Authors: Karalis, George; Mytafides, Christos K.; Tzounis, Lazaros; Paipetis, Alkiviadis; Barkoula, Nektaria-Marianthi

  • Year: 2021

  1. High-Power All-Carbon Fully Printed and Wearable SWCNT-Based Organic Thermoelectric Generator

  • Authors: Mytafides, Christos K.; Tzounis, Lazaros; Karalis, George; Formanek, Petr; Paipetis, Alkiviadis S.

  • Year: 2021

  1. Epoxy/glass fiber nanostructured p- and n-type thermoelectric enabled model composite interphases

  • Authors: Karalis, George; Tsirka, Kyriaki; Tzounis, Lazaros; Mytafides, Christos K.; Koutsotolis, Loukas; Paipetis, Alkiviadis S.

  • Year: 2020

  1. Hierarchical reinforcing fibers for energy harvesting applications—A strength study

  • Authors: Karalis, George; Mytafides, Christos K.; Polymerou, Angelos; Tsirka, Kyriaki; Tzounis, Lazaros; Gergidis, Leonidas; Paipetis, Alkiviadis S.

  • Year: 2020

  1. Design, fabrication and characterization of plasmon-enhanced dye-sensitized solar cells

  • Authors: Mytafides, Christos K.

  • Year: 2019

  1. Transformation of a university building into a zero-energy building in Mediterranean climate

  • Authors: Mytafides, Christos K.; Dimoudi, A.; Zoras, S.

  • Year: 2017

  1. Integrated architectures of printed electronics with energy-harvesting capabilities in advanced structural composites

  • Authors: Mytafides, Christos K.