Tetiana Starodub | Synthetic Metals | Best Researcher Award

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Tetiana Starodub | Synthetic Metals | Best Researcher Award

Dr. Tetiana Starodub,Institute of Chemistry, Jan Kochanowski University in Kielce, Poland.

Dr. Tetiana Starodub is an accomplished chemist specializing in synthetic metals and coordination chemistry. She graduated with honors from the National University of Vasyl Karazin and later pursued advanced research at the Institute of Technology in Karlsruhe, Germany. Currently an assistant professor at the Institute of Chemistry of the Jan Kochanowski University in Kielce, Poland, Dr. Starodub focuses on the synthesis and testing of 7,7′,8,8′-tetracyanoquinodimethane (TCNQ) derivatives for applications in electronics, biotechnology, and medicine. Her innovative research contributes significantly to modern materials science.Β πŸŽ“πŸ”¬πŸ“š

Publication ProfilesΒ 

Scopus
Orcid

Education and Experience

  • 1998: Graduated with honors from the National University of Vasyl Karazin in Kharkov, Ukraine.Β πŸŽ“
  • 1998-2000: Began education at the Theoretical and Organic Chemistry Department of KhNU.Β πŸ“–
  • 2000-2001: Worked in laboratories at the Institute of Technology in Karlsruhe, Germany.Β πŸ­πŸ‡©πŸ‡ͺ
  • 2000-2014: Conducted research on isotrithionedithiolate transition metal complexes and TCNQ anion-radical salts.Β πŸ”¬
  • 2018-Present: Assistant Professor at the Institute of Chemistry, Jan Kochanowski University, Kielce, Poland.Β πŸ‘©β€πŸ«πŸ‡΅πŸ‡±

Suitability For The Award

Dr. Tetiana Starodub, Assistant Professor at the Institute of Chemistry, Jan Kochanowski University, Kielce, Poland, is a highly deserving candidate for the Best Researcher Award due to her significant and ongoing contributions to the fields of synthetic metals, organic and coordination chemistry, and the development of innovative materials for modern electronics, biotechnology, and medicine. With an extensive career in scientific research and a focus on materials that promise to revolutionize numerous industries, Dr. Starodub exemplifies the qualities of a pioneering and impactful researcher.

Professional Development

Dr. Tetiana Starodub is dedicated to continuous professional development, engaging in various research initiatives and collaborations. Since 2018, she has focused on synthetic metals and coordination chemistry, particularly the synthesis and application of TCNQ compounds. Her commitment to academic excellence includes publishing research findings and presenting at international conferences, fostering connections within the scientific community. Through her work, Dr. Starodub aims to enhance the understanding of electrochemical properties and the potential applications of TCNQ materials in electronics and biotechnology.Β πŸŒπŸ“ˆπŸ”¬

Research Focus

Dr. Tetiana Starodub’s research centers on the synthesis and characterization of 7,7′,8,8′-tetracyanoquinodimethane (TCNQ) and its derivatives. Her work encompasses the development of anion-radical salts for use in various fields, including electronics, biotechnology, and medicine. She investigates the electrochemical properties of TCNQ salts to explore their applications in electrochemical sensors, organic batteries, gas storage, and drug delivery systems. Dr. Starodub has synthesized over two hundred TCNQ-based compounds, contributing to advancements in modern materials science and sustainable technologies.Β πŸ’‘βš›οΈπŸ”‹

Awards and Honors

  • Best Research PresentationΒ at the International Chemistry Conference, 2022.Β πŸ†
  • Grant RecipientΒ for Innovative Research in Synthetic Metals, 2021.Β πŸ’°
  • Recognition AwardΒ from the Jan Kochanowski University for Excellence in Teaching, 2020.Β πŸŽ–οΈ
  • Publication AwardΒ for outstanding contributions to the field of Coordination Chemistry, 2019.Β πŸ“œ
  • Scholarship RecipientΒ for International Research Collaboration, 2018. 🌐

Publication Top NotesΒ 

  • TCNQ and Its Derivatives as Electrode Materials in Electrochemical Investigationsβ€”Achievement and Prospects: A ReviewΒ (2024)Β πŸ“…πŸ”‹
  • Crystal Structure of Anion-Radical Salts of 7,7,8,8-tetracyanoquinodimethane with N-xylyl-pyridinium and N-xylyl-isoquinolinium CationsΒ (2022)Β πŸ“…πŸ”
  • Structure, optical and electro-physical properties of tetramerized anion-radical salt (N-Xy-Qn)(TCNQ)β‚‚Β (2022)Β πŸ“…πŸ”¬
  • Crystal and Molecular Structure of Anion Radical Salt (N-Me-DABCO)(TCNQ)β‚‚Β (2022)Β πŸ“…πŸ”¬
  • New radical-cation salts based on the TMTTF and TMTSF donors with iron and chromium bis(dicarbollide) complexes: Synthesis, structure, propertiesΒ (2021)Β πŸ“…πŸ”¬
  • Structure and Properties of Anion-Radical Salt of 7,7,8,8-Tetracyanoquinodimethane with N-Methyl-2,2′-dipyridyl CationΒ (2021)Β πŸ“…πŸ”¬
  • The Crystal Structure of a RAS (N–CH3-2-NH2-5-Cl–Py)(TCNQ)(CH3CN) SolvateΒ (2020)Β πŸ“…πŸ”
  • Optical properties of RAS (N–CH3-2-NH2-5Cl-Py)(TCNQ)(CH3CN) solvateΒ (2020)Β πŸ“…πŸ”¬
  • Stabilization of Pancake Bonding in (TCNQ)β‚‚.βˆ’ Dimers in the Radical-Anionic Salt (Nβˆ’CH3βˆ’2-NH2βˆ’5Clβˆ’Py)(TCNQ)(CH3CN) Solvate and Antiferromagnetism InductionΒ (2019)Β πŸ“…πŸ”¬

Terry Alford | Materials Processing | Best Researcher Award

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Prof Dr.Terry Alford | Materials Processing | Best Researcher Award

Associate Director and Professor at Arizona State University,United States

Dr. T.L. Alford is a distinguished professor of Materials Science and Engineering at Arizona State University. With extensive experience in academia and industry, he has significantly contributed to the field through teaching, mentoring, and research. His work spans several areas, including semiconductor materials and renewable energy technologies. Dr. Alford is also dedicated to enhancing diversity in engineering through active participation in professional societies and student organizations.

Profile:

Scopus Profile

Strengths for the Award:

  1. Extensive Academic Background: With a Ph.D. and multiple master’s degrees in Materials Science and Engineering, this researcher possesses a solid foundational knowledge and expertise in the field.
  2. Long-standing Academic Career: Serving as a professor at Arizona State University since 1993, the candidate has demonstrated commitment and sustained excellence in teaching and mentoring students.
  3. Diverse Research Interests: The researcher has explored a variety of cutting-edge topics, including metal contacts to diamond semiconductors, organic-based perovskite solar cells, and transparent composite electrodes, showcasing versatility and relevance in current scientific challenges.
  4. Industry Experience: The candidate has substantial industrial experience as a consultant for leading technology firms, bridging the gap between academia and industry and enhancing the practical impact of their research.
  5. Strong Publication Record: A significant number of publications in reputable journals, including recent advancements in nanofilms and perovskite solar cells, demonstrate a robust research output and engagement with contemporary scientific issues.
  6. Recognition and Awards: Induction into the National Academy of Inventors and being a Fellow of the African Scientific Institute reflect recognition by peers and professional bodies, affirming the impact and quality of their work.
  7. Commitment to Mentorship: The candidate has actively engaged in mentoring students, particularly underrepresented minorities in engineering, which speaks to their dedication to diversity and inclusion in academia.

Areas for Improvement:

  1. Broader Collaborative Networks: While there is experience with international collaborations, expanding these networks could enhance research opportunities and foster more interdisciplinary projects.
  2. Funding Acquisition: Increasing the focus on securing research grants could amplify the scope and impact of future projects, ensuring sustainability and growth in research activities.
  3. Public Engagement: Engaging more with the public and communicating research findings in accessible ways could enhance visibility and societal impact, fostering a greater appreciation for materials science.
  4. Leveraging Online Learning Tools: Further integrating innovative online learning tools and methodologies in courses could enhance student engagement and learning outcomes, particularly in a post-pandemic educational landscape.

Education:

Dr. Alford earned his Ph.D. and M.S. in Materials Science from Cornell University in 1991 and 1988, respectively. He also holds two master’s degrees: an M.S. in Materials Engineering from North Carolina State University (1986) and a B.S. in Materials Engineering, graduating Summa Cum Laude from the same institution in 1984. His rigorous educational background has laid a strong foundation for his impactful research and teaching career.

Experience:

Dr. Alford has been a faculty member at Arizona State University since 1993, progressing from Assistant to Professor. His extensive industrial experience includes consulting for leading tech companies like Adesto Technologies and Texas Instruments. He has also been involved in various academic affiliations and leadership roles, including serving as Characterization Leader at the Flexible Display Center. His unique blend of academic and industrial experience enriches his teaching and research endeavors.

Awards and Honors:

Dr. Alford has received numerous accolades, including being named a Fellow of the African Scientific Institute in 2020 and a Senior Member of the National Academy of Inventors in 2019. His recognitions include the Outstanding Graduate Mentor Award and the Golden Torch Pioneer of the Year Award. Additionally, he has been nominated for multiple teaching and mentoring awards, underscoring his commitment to excellence in education and research.

Research Focus:

Dr. Alford’s research interests encompass a diverse range of topics, including metal contacts to diamond semiconductors, organic-based perovskite solar cells, and materials characterization. He is particularly focused on developing innovative solutions for energy conversion and storage, employing advanced materials processing techniques. His research also aims to integrate online active learning tools to enhance educational outcomes in materials science.

Publications:

  1. Fundamentals of Nanoscale Film Analysis πŸ“š
  2. Characterization of PEDOT Nanofilms Printed via Electrically Assisted Direct Ink Deposition with Ultrasonic Vibrations πŸ”¬
  3. Ultrafast and Large-Scale Fabrication of PEDOT Nanofilms Using Electrical-Field-Assisted Direct Ink Deposition ⚑
  4. Ohmic contacts to nitrogen-doped nanocarbon layers on diamond (100) surfaces πŸ’Ž
  5. Theoretical analysis of green hydrogen from hydropower: A case study of the Northwest Columbia River system 🌊
  6. 3D Printing of Largescale Functional Nanofilm using Electrically assisted Direct Ink Deposition πŸ–¨οΈ
  7. Fabrication of triple cation perovskite solar cells using different post-spin coating anti-solvent treatments 🌞
  8. Understanding the crystallization of triple-cation perovskites assisted by mixed antisolvents for improved solar cell device performance πŸ”
  9. Phenyl Ethylammonium Iodide introduction into inverted triple cation perovskite solar cells for improved VOC and stability βš™οΈ
  10. Passivation of triple cation perovskites using guanidinium iodide in inverted solar cells for improved open-circuit voltage and stability πŸ“ˆ
  11. Impact of precursor concentration on the properties of perovskite solar cells obtained from the dehydrated lead acetate precursors πŸ§ͺ

Conclusion:

This researcher exemplifies the qualities of a leading figure in the field of Materials Science and Engineering. With a robust academic and industrial background, a diverse and impactful research portfolio, and a strong commitment to mentorship and community engagement, they are highly deserving of the Best Researcher Award. Addressing areas for improvement will further elevate their contributions to academia and the scientific community, solidifying their position as a leader in their field.