Levi Felix | Nanomaterials | Best Researcher Award

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Levi Felix | Nanomaterials | Best Researcher Award

Dr. Levi Felix, Rice University, United States.

Levi Felix, a Postdoctoral Research Associate at the Department of Materials Science and Nanoengineering, Rice University, specializes in computational mechanics, nanomaterials, and molecular dynamics simulations 🌌🧑‍🔬. With a Ph.D. in Physics from UNICAMP (2022), Levi’s research spans porous materials, carbon nanostructures, and advanced modeling methods 🧪. He has earned recognition, including a 2022 award from NIST and the Best Poster Award at MRS Fall Meeting 2021 🏅. Fluent in multiple programming languages and skilled in software like LAMMPS and Quantum ESPRESSO, Levi contributes to cutting-edge advancements in nanotechnology and materials science 🌟.

Publivation Profiles

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Education and Experience

🎓 Education:

  • Ph.D. in Physics (2018–2022): State University of Campinas (UNICAMP)
    • Thesis: Computational Mechanics of Porous and 2D Carbon Nanomaterials
  • M.Sc. in Physics (2016–2018): Federal University of Ceará (UFC)
    • Dissertation: Wave-packet Propagation in Phosphorene with Grain Boundaries
  • B.S. in Physics, Magna Cum Laude (2013–2016): Federal University of Ceará (UFC)
    • Monograph: Landau Levels in Graphene Influenced by 1D Potentials

💼 Experience:

  • Postdoctoral Research Associate (Oct 2022–Present): Rice University, USA
  • Graduate Teaching Assistant (2019): State University of Campinas (UNICAMP)
  • Graduate Teaching Assistant (2017): Federal University of Ceará (UFC)

Suitability summary for best researcher Award

Dr. Levi Felix is highly deserving of the Best Researcher Award due to his groundbreaking contributions to the field of materials science and nanoengineering. Currently serving as a Postdoctoral Research Associate at Rice University, Felix’s work is at the forefront of computational mechanics and the study of two-dimensional carbon nanomaterials. His research has significantly advanced our understanding of the mechanical, optical, and thermoelectric properties of novel materials, particularly within the realm of advanced carbon allotropes and porous nanostructures.

Professional Development

Levi Felix is an accomplished researcher with extensive expertise in molecular dynamics, density functional theory, and tight-binding methods for material simulations 🛠️. Proficient in Python, C++, and software like LAMMPS and VMD, Levi’s work bridges computational techniques and practical applications in nanotechnology 🖥️. He has presented at prominent conferences, including MRS Meetings in the U.S. and Brazil, earning accolades for his contributions 🏆. With multilingual abilities (Portuguese, English, and Spanish) 🌐, Levi’s collaborative research continues to push the boundaries of materials science, focusing on innovative approaches to structural and electronic properties of advanced materials 🔬.

Research Focus

Levi Felix’s research lies at the intersection of computational materials science, with a focus on porous materials and two-dimensional carbon nanomaterials. His work employs techniques such as molecular dynamics simulationsdensity functional theory (DFT), and density functional tight-binding (DFTB) to explore the mechanical propertiesvibrational characteristics, and electronic structures of novel nanomaterials, including grapheneschwarzites, and borophene. His research has applications in nanotechnologymaterials engineering, and energy storage systems🌍🔬🧑‍🔬

Awards and Honors

  • 🏅 2022: Recognition Award from NIST for oral presentation on Symposium DS02 at MRS Spring Meeting, Honolulu-HI, USA.
  • 🏆 2021: Best Poster Award at MRS Fall Meeting, Boston-MA, USA.
  • 🎓 2016: Magna Cum Laude on Bachelor of Physics at Federal University of Ceará, Brazil.

Publication Top Noted

 

Chang Wu | Nanomaterials design | Best Researcher Award

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Dr. Chang Wu | Nanomaterials design | Best Researcher Award

Doctorate at University of Canterbury, New Zealand

Chang Wu is a Postdoctoral Research Fellow in the Chemical and Process Engineering Departments at the University of Canterbury, Christchurch, New Zealand. He earned his PhD in Chemistry/Engineering from the University of Wollongong, Australia, where he specialized in the development of advanced materials for metal-oxygen batteries. Wu’s research expertise lies in the synthesis of nano-materials, metal-oxygen batteries, and electrocatalysts. His work includes investigating advanced catalysts for oxygen evolution reactions and exploring novel materials for energy storage applications.

Author Metrics

Scopus Profile

Chang Wu has made significant contributions to the field of electrochemistry and materials science, with multiple high-impact publications in reputable journals. His work has been cited extensively, reflecting his influence and recognition in the research community. As a co-first author on several publications, Wu’s contributions have been pivotal in advancing the understanding and application of electrocatalysts and battery technologies.

Education

Chang Wu completed his PhD in Chemistry/Engineering at the University of Wollongong, Australia, focusing on advanced materials for metal-oxygen batteries. His educational background also includes a Bachelor of Engineering from Dalian University of Technology, China, where he studied materials science and engineering. His academic training has provided a strong foundation in both theoretical and practical aspects of materials and electrochemical engineering.

Research Focus

Wu’s research focuses on the synthesis and application of nano-materials, particularly in the context of metal-oxygen batteries and electrocatalysts. He investigates the performance and mechanisms of materials used in energy storage systems, such as Li-O2, Na-O2, and Zn-air batteries. His current work includes developing advanced catalysts for oxygen evolution reactions in alkaline electrolytes and exploring bi-functional materials for rechargeable battery applications.

Professional Journey

Chang Wu’s professional journey includes roles as a Research Assistant at the Institute of Superconducting and Electronic Materials, Wollongong, and as a Postdoctoral Research Fellow at the University of Canterbury. His work has involved significant research into non-noble metal catalysts and advanced materials for energy storage, highlighting his progression from early research roles to leading complex projects and collaborations in his current position.

Honors & Awards

Wu’s contributions to the field have been recognized through various honors and awards. Notably, he represented New Zealand at the 15th JSPS HOPE Meeting with Nobel Laureates in Japan. His research achievements and collaborations have also secured funding from prestigious organizations, including the New Zealand Ministry of Business Innovation & Education (MBIE) and the Australian Nuclear Science and Technology Organization (ANSTO).

Publications Noted & Contributions

Wu has authored and co-authored numerous publications in high-impact journals, contributing to the fields of electrochemistry and materials science. Notable publications include articles on Na-O2 battery performance, highly efficient catalysts for Li-O2 batteries, and advancements in carbon materials for electrochemical applications. His research has advanced the understanding of electrocatalysts and energy storage materials, making significant contributions to both fundamental and applied sciences.

Lattice Distortion and H-passivation in Pure Carbon Electrocatalysts for Efficient and Stable Two-electron Oxygen Reduction to H2O2

  • Authors: Lin, L., Huang, L., Wu, C., Wallace, G.G., Huang, W.
  • Journal: Angewandte Chemie – International Edition
  • Year: 2023
  • Volume: 62
  • Issue: 49
  • Page: e202315182
  • Citations: 7

Abstract

This study explores how lattice distortion and H-passivation in pure carbon materials enhance their efficiency and stability for the two-electron oxygen reduction reaction (ORR) to hydrogen peroxide (H₂O₂). The authors investigate the structural and chemical modifications in carbon electrocatalysts that contribute to improved catalytic performance.

Boosting Na-O2 Battery Performance by Regulating the Morphology of NaO2

  • Authors: Wu, C., Yang, Q., Zheng, Z., Chen, J., Wang, J.
  • Journal: Energy Storage Materials
  • Year: 2023
  • Volume: 54
  • Pages: 1–9
  • Citations: 3

Abstract

This paper discusses methods to enhance the performance of sodium-oxygen (Na-O₂) batteries by manipulating the morphology of sodium superoxide (NaO₂). The authors demonstrate how controlling the structural aspects of NaO₂ can significantly impact battery efficiency and stability.

Novel Porous Thermosensitive Gel Electrolytes for Wearable Thermo-electrochemical Cells

  • Authors: Zhou, Y., Zhang, S., Buckingham, M.A., Wallace, G., Chen, J.
  • Journal: Chemical Engineering Journal
  • Year: 2022
  • Volume: 449
  • Article Number: 137775
  • Citations: 26

Abstract

The research introduces innovative porous thermosensitive gel electrolytes designed for wearable thermo-electrochemical cells. These electrolytes are intended to enhance the performance and flexibility of electrochemical devices integrated into wearable technologies.

Fast Activation of Graphene with a Highly Distorted Surface and Its Role in Improved Aqueous Electrochemical Capacitors

  • Authors: Zhong, L., Wu, C., Lei, S., Gao, B., Lin, L.
  • Journal: ACS Applied Energy Materials
  • Year: 2022
  • Volume: 5
  • Issue: 7
  • Pages: 8004–8014
  • Citations: 6

Abstract

This article explores how the rapid activation of graphene with a highly distorted surface contributes to enhanced performance in aqueous electrochemical capacitors. The study highlights the effects of structural modifications on the electrochemical properties and efficiency of capacitors.

Research Progress and Future Perspectives on Rechargeable Na-O2 and Na-CO2 Batteries

  • Authors: Zheng, Z., Wu, C., Gu, Q., Konstantinov, K., Wang, J.
  • Journal: Energy and Environmental Materials
  • Year: 2021
  • Volume: 4
  • Issue: 2
  • Pages: 158–177
  • Citations: 27

Abstract

This review paper provides a comprehensive overview of recent advancements and future directions in rechargeable sodium-oxygen (Na-O₂) and sodium-carbon dioxide (Na-CO₂) batteries. It discusses the current state of research, challenges, and potential improvements in these battery technologies.

Strengths of Chang Wu’s Research

  1. Innovative Material Synthesis: Chang Wu’s work in synthesizing advanced nanomaterials, particularly for metal-oxygen batteries and electrocatalysts, reflects his expertise in creating novel materials that enhance performance and stability. His research on lattice distortion and H-passivation in carbon electrocatalysts is an example of this innovative approach.
  2. High-Impact Publications: Wu has authored several high-impact publications in reputable journals such as Angewandte Chemie – International Edition and Energy Storage Materials. His research is well-cited, indicating significant influence in the fields of electrochemistry and materials science.
  3. Focus on Energy Storage and Catalysis: Wu’s research on metal-oxygen batteries (e.g., Na-O₂ and Li-O₂) and electrocatalysts demonstrates a clear focus on improving energy storage technologies and catalytic processes. This specialization is crucial for advancing sustainable energy solutions.
  4. Recognition and Awards: Wu’s representation of New Zealand at the JSPS HOPE Meeting with Nobel Laureates and other awards highlight his recognition and esteemed position in the research community. These accolades emphasize his contributions and the impact of his work.
  5. Funding and Support: The funding received from organizations such as the New Zealand MBIE and Australian ANSTO underscores the importance and potential of Wu’s research. It reflects confidence from prestigious institutions in his research’s direction and outcomes.

Areas for Improvement

  1. Broader Collaboration: While Wu has a strong track record in his niche areas, expanding collaborations beyond his current scope could open new interdisciplinary research avenues and enhance the application of his findings in diverse fields.
  2. Publication Variety: Although Wu has published extensively in high-impact journals, diversifying his publication portfolio to include more interdisciplinary or applied journals could broaden the reach and application of his research.
  3. Public Engagement: Increasing engagement with the broader public and industry stakeholders through outreach activities or public talks could enhance the societal impact of his research and foster greater awareness of his work’s practical applications.
  4. Research Funding Diversity: While Wu has secured funding from notable organizations, exploring additional funding sources, including industry partnerships or international grants, could provide more financial stability and support for innovative projects.
  5. Translational Research: Emphasizing the translation of his research findings into commercial or practical applications could improve the real-world impact of his work. This might involve closer collaboration with industry partners to develop and commercialize new technologies.

Conclusion

Chang Wu’s research stands out for its innovative approach to material synthesis, high-impact publications, and focus on critical areas such as energy storage and catalysis. His accolades and funding reflect his significant contributions to these fields. However, expanding collaborations, diversifying publication venues, engaging with the public, exploring varied funding sources, and focusing on translational research could further enhance the impact and reach of his work. Overall, Wu’s research has made a notable mark on the field, and addressing these areas for improvement could elevate his influence and application of scientific advancements.

Dr. AYSE DURMUS SAYAR| carbon nano materials Awards | Best Researcher Award

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Dr. AYSE DURMUS SAYAR| carbon nano materials Awards | Best Researcher Award

Dr. AYSE DURMUS SAYAR , Sabanci University , Turkey

Ayşe Durmuş Sayar is a dedicated material scientist with a strong academic background and research expertise in materials science and nanoengineering. She holds a Doctor of Philosophy (PhD) in Materials Science and Nano Engineering from Sabancı University, Istanbul, Turkey, where her doctoral research focused on surface modification of carbon nano-materials and their integration into fiber surfaces to enhance interfacial interactions in fiber-reinforced polymeric composites.

During her academic journey, Ayşe obtained a Master of Science (MSc) in Materials Science and Nano Engineering from the same institution, specializing in polyurethane synthesis for coating applications. Her master’s research delved into the synthesis and characterization of branched, functional polyurethane dispersions for self-crosslinking textile coatings.

Professional Profile:

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🎓 Education:

  • Ph.D. in Materials Science and Nano Engineering
    Thesis: “Synthesis and Characterization of Branched, Functional Polyurethane Dispersions as a Technology Platform for Self-Crosslinking Textile Coatings”
    Sabancı University, Istanbul, Turkey (2017 – 2023)
  • Master of Science in Materials Science and Nano Engineering
    Sabancı University, Istanbul, Turkey (2015 – 2017)
  • Bachelor of Science in Textile Engineering
    Istanbul Technical University, Istanbul, Turkey (2009 – 2015)

🏆 Awards:

  • Tuition waiver, Housing, and Stipend for both Master’s and Ph.D. programs.

🔬 Research Interests:

Ayşe’s research primarily revolves around materials science, with a focus on polymer synthesis, characterization, and application. Her doctoral and master’s studies delved into areas such as polyurethane chemistry, functional coatings, and the integration of carbon nanomaterials into composites.

🎓 Teaching Experience:

Ayşe has served as a teaching assistant, contributing to the education of future scientists and engineers in courses like Polymer Chemistry & Physics and Calculus II.

🔬 Work Experience:

Currently working as a Technical and Marketing personnel at Tanatex Chemicals in the Netherlands, Ayşe brings her expertise in polyurethane coatings and materials science to her role, contributing to product development and market research.

🌟 Research Contributions:

Ayşe’s research has significantly contributed to advancing the understanding and application of materials in various industries, ranging from textile engineering to acoustic applications. Her work emphasizes innovation, sustainability, and interdisciplinary collaboration.

🌱 Future Endeavors:

Continuously striving to expand her academic and professional horizons, Ayşe remains dedicated to pushing the boundaries of materials science through her research, teaching, and industry contributions.

Publication Top Notes:

Recent advances in waterborne polyurethanes and their nanoparticle-containing dispersions

Citation : 24

Antibacterial hybrid coatings from halloysite-immobilized lysostaphin and waterborne polyurethanes

Citation : 15

Synthesis and characterization of branched, functional polyurethane dispersions as a technology platform for self-crosslinking textile coatings

Incorporation of Graphene Nanoplatelets into Fiber-Reinforced Polymer Composites in the Presence of Highly Branched Waterborne Polyurethanes