Vladimir Fedorovich Mironov | Organic Chemistry | Best Research Article Award

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Dr. Vladimir Fedorovich Mironov | Organic Chemistry | Best Research Article Award

A.E.Arbuzov Institute of Organic and Physical Chemistry | Russia

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Early Academic Pursuits

Vladimir Fedorovich Mironov was born on September 12, 1957, in Kazan, Russia. Demonstrating early academic brilliance, he graduated from secondary school No. 132 in Kazan in 1974 with a gold medal. The same year, he enrolled in the Chemistry Department of Kazan State University (KSU), graduating with honors in 1979. His passion for organoelement chemistry led him to pursue postgraduate studies under Professor I.V. Konovalova, where he specialized in the chemistry of organoelement compounds. By 1983, Mironov had successfully defended his candidate’s dissertation on “Synthesis and some reactions of phosphorylated trialkyl phosphites,” marking the beginning of his research journey.

Professional Endeavors

Mironov’s career reflects a steady progression of academic and research excellence. Starting as a junior and later senior research fellow at Kazan institutions, he established himself as a respected scholar. In 1995, he defended his doctoral dissertation on reactions of fluoroalkyl phosphites, further solidifying his expertise. His appointment as professor in 2000, alongside leadership roles at the Institute of Organic and Physical Chemistry of the Kazan Scientific Center of the Russian Academy of Sciences, positioned him at the forefront of organoelement research. In addition, his long-standing role as professor at KSU reflects his dedication to teaching and academic mentorship.

Contributions and Research Focus

Professor Mironov has made substantial contributions in the field of organophosphorus chemistry, particularly in the synthesis of phosphorylated analogues of natural compounds and renewable natural raw materials. His research not only advanced theoretical chemistry but also found practical applications in pharmaceuticals and materials science. He has led pioneering projects on developing low- and high-molecular compounds from plant raw materials, expanding the scope of sustainable chemistry. His patents, including the pharmacological composition listed among Russia’s top 100 inventions in 2016, highlight his ability to translate fundamental research into applied innovation.

Impact and Influence

Mironov’s influence extends beyond his laboratory achievements. He has been instrumental in mentoring young scientists, supervising dissertations, and actively shaping the direction of chemical sciences in Russia. As Chairman of the Republican Chemical Society of Tatarstan and member of multiple dissertation councils, he has played a vital role in advancing academic standards. His leadership in editorial boards, particularly as editor-in-chief of Butlerov Communications, has further amplified his academic reach.

Academic Recognition and Awards

Over his career, Mironov has received numerous honors, including the G. Kamay Prize of the Academy of Sciences of the Republic of Tatarstan (2004), the title of “Honored Scientist of the Republic of Tatarstan” (2005), and the prestigious State Prize of the Republic of Tatarstan in Science and Technology (2013). His election as a Corresponding Member of the Russian Academy of Sciences in 2008 underscores his national recognition.

Legacy and Future Contributions

Vladimir Fedorovich Mironov’s legacy lies in his dual commitment to fundamental chemical research and its practical application for societal benefit. His extensive teaching career ensures the continuity of his scientific school, inspiring future generations of chemists. His ongoing leadership roles in professional societies and academic councils signal that his influence will remain strong in shaping Russian and international chemical sciences.

Conclusion

In sum, Vladimir Fedorovich Mironov embodies the qualities of a distinguished scientist, educator, and leader. His early academic brilliance, groundbreaking research in organophosphorus chemistry, significant innovations, and mentorship contributions have left an enduring mark on the scientific community. His work bridges the gap between theory and application, and his legacy continues to inspire both his peers and future scholars in the field of chemistry.

Notable Publications

“Amphiphilic ammonium acylhydrazones on the base of sterically-hindered catechol: Synthesis, self-assembly, reversible inhibition of butyrylcholinesterase and structure-activity relationships

  • Author: Z.M. Shaihutdinova, A.E. Vandyukov, S.V. Lushchekina, V.F. Mironov, S.V. Bukharov, R.G. Tagashev, A.V. Bogdanov, M.V. Arsenyev, P. Masson, T.N. Pashirova
  • Journal: Journal of Molecular Liquids
  • Year: 2025

“Membranotropic Property and Antibiofilm Efficacy of Novel Phosphonium Derivatives Bearing Phenolic Moiety

“Deoxygenation of Some 1,2-Dicarbonyl Compounds by Phosphorous Acid Amides (A Review)

  • Author: A. V. Bogdanov & V. F. Mironov
  • Journal: Russian Journal of General Chemistry
  • Year: 2025

“Design, synthesis, and antitumor activity of triphenylphosphonium iodides containing C(30)-modified lupane triterpenoid moieties

  • Author: OV Tsepaeva, AV Nemtarev, LR Idrisova, BI Khairutdinov, TI Abdullin, EV Kuznetsova & V. F. Mironov
  • Journal: Russian Chemical Bulletin
  • Year: 2025

“Replacement of phenyl substituents at phosphorus by hexyl ones in 2-(2-hydroxyaryl)vinylphosphonium salts can tune the nature of the induced proton transport through lipid membranes

  • Author: Tatyana I. Rokitskaya, Ljudmila S. Khailova, Anna G. Strelnik, Elena A. Kotova, Vladimir F. Mironov, Dmitry A. Tatarinov, Yuri N. Antonenko
  • Journal: Biochimica Et Biophysica Acta Biomembranes
  • Year: 2025

 

 

 

 

Kumara Swamy | Chemistry | Best Researcher Award

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Dr. B.E. Kumara Swamy | Chemistry | Best Researcher Award

Kuvempu University | India

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Early Academic Pursuits

Dr. B.E. Kumara Swamy demonstrated academic excellence from the very beginning of his educational journey. He secured his B.Sc. in Physics, Chemistry, and Mathematics with distinction in 1995, followed by an M.Sc. in Industrial Chemistry in 1997, where he achieved First Rank and was honored with the Gajendraghad Gold Medal. His strong foundation in chemistry paved the way for his Ph.D. at Kuvempu University (2002), where his doctoral research focused on cyclic voltammetric investigations of biologically and synthetically important organic and inorganic compounds. These early academic milestones highlighted his deep interest in electrochemistry and provided the groundwork for his later pioneering research.

Professional Endeavors

Dr. Swamy’s professional career spans more than two decades at Kuvempu University, where he advanced from Guest Lecturer in 1997 to his current role as Professor of Industrial Chemistry (2021–present). He has taught diverse postgraduate programs in Electrochemistry, Polymer Chemistry, Nanoscience, and Spectroscopy, contributing significantly to curriculum development. Alongside his teaching, he has held various administrative roles including Deputy Registrar, Assistant Director, Deputy Director of IQAC, Special Officer to the Vice-Chancellor, and Chairman of the Department of Industrial Chemistry. These positions demonstrate his multifaceted leadership and commitment to strengthening academic governance and institutional development.

Contributions and Research Focus

Dr. Swamy’s research primarily centers on electrochemical sensors, nanomaterials, and voltammetry-based detection methods. His pioneering work on carbon paste electrodes modified with nanostructures has contributed to advancements in detecting biologically and environmentally relevant molecules such as dopamine, serotonin, uric acid, and antibiotics. His post-doctoral research in the USA, funded by the National Science Foundation (2003–2006) and the University of Virginia (2006), further enriched his expertise in nonlinear electrochemical systems and biomedical sensors. His contributions extend beyond laboratory research, as evidenced by his Indian patents (2022, 2023, 2025) related to novel electrochemical detection methods, underlining his innovation-driven approach to applied chemistry.

Impact and Influence

Dr. Swamy’s influence extends internationally, with recognition by Stanford University’s Top 2% Most-Cited Scientists for four consecutive years (2020–2024). Furthermore, he was ranked among the Top 0.05% Highly Ranked Scholars globally by ScholarGPS (2022–2024), underscoring the global relevance of his work in energy and electrochemistry. His awards, including the Young Scientist Awards (2000, 2012), the Demetrios Nikeleis Award (2015), and the Dr. A.P.J. Abdul Kalam Lifetime Achievement Award (2016), highlight his consistent contributions to science and innovation. Through his teaching and mentorship, he has influenced several generations of students and researchers, advancing knowledge in electroanalytical chemistry.

Academic Citations and Recognition

Dr. Swamy’s prolific output includes numerous research papers presented at national and international conferences and publications in peer-reviewed journals. His work is frequently cited, reflecting its high impact across electrochemistry, nanoscience, and sensor technology. His recognition in Stanford’s global citation database and by international science agencies is a testament to the quality, originality, and continued relevance of his research.

Legacy and Future Contributions

Dr. Swamy’s legacy lies in his ability to integrate fundamental electrochemical theory with practical applications in medicine, environment, and nanotechnology. His patents, leadership roles, and academic contributions mark him as a visionary scientist who bridges academia, research, and innovation. Looking ahead, his ongoing work in nanomaterial-based sensors and green electrochemical methods is expected to address emerging challenges in healthcare and environmental monitoring. His sustained dedication to advancing industrial chemistry ensures his continued role as a thought leader and mentor for future generations.

Conclusion

Dr. B.E. Kumara Swamy stands out as a distinguished academician, researcher, and innovator whose career reflects excellence in teaching, pioneering research, and impactful leadership. His contributions to electrochemistry and nanotechnology, combined with his global recognition as one of the most-cited scientists, establish him as a deserving candidate for honors such as the Outstanding Scientist Award. With a proven track record of academic brilliance, innovation, and mentorship, his journey exemplifies both scientific achievement and societal impact.

Notable Publications

"Fabrication of CuS-MoO3 nanocomposite for high-performance photocatalysis and biosensing

  • Author: EV Kumar, TL Soundarya, BEK Swamy, G Nagaraju
  • Journal: Journal of Molecular Structure
  • Year: 2025

"Advanced ZnFe₂O₄@ f-CNF electrode: A robust electrochemical sensor for Tert-butyl hydroquinone detection in food and edible oil

  • Author: R Yemmi, BEK Swamy, KM Manjunath, K Yusuf, AM Aljuwayid
  • Journal: Food Chemistry
  • Year: 2025

"Environmental contaminants detection by disposable burnt carving-based graphite pencil electrode for hydroquinone and catechol

  • Author: BEK Swamy, SC Sharma
  • Journal: Microchemical Journal
  • Year: 2025

"One step facile green synthesis of ZnFe2O4-ZnO Nanocomposite: Efficient photocatalytic activity towards organic dyes under visible light and photoluminescence applications

  • Author: EV Kumar, R Harini, BEK Swamy, G Nagaraju
  • Journal: Environmental Nanotechnology, Monitoring & Management 23
  • Year: 2025

"A sensitive detecting and analyzing of indigo carmine at ZnO nanoparticle modified carbon paste electrode: a voltammetric study

  • Author: M B,Puneeth, B.E.Kumara, Swamy and L.S
  • Journal: Sensing Technology
  • Year: 2025

 

Adnan Ali Khan | Applied Chemistry | Young Scientist Award

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Dr. Adnan Ali Khan | Applied Chemistry | Young Scientist Award

Lecturer at University of Malakand Chakdara Pakistan, Pakistan📖

Dr. Adnan Ali Khan is a distinguished researcher in applied chemistry, specializing in computational chemistry for energy storage systems. His expertise lies in the design and analysis of rechargeable magnesium-ion batteries using first-principles studies. With over a decade of academic and research experience, he has significantly contributed to the development of microporous polymeric cathode materials, catalytic mechanisms, and advanced material modeling. Dr. Khan’s impactful research is reflected in his numerous publications in high-impact journals and his active involvement in computational materials science.

Profile

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Education Background🎓

  • Ph.D. in Applied Chemistry (2017–2024)
    Thesis: First Principles Study of Quinone Derivatives Conjugated Polymers Electrode Materials for Magnesium Ion Batteries
    University of Malakand, Pakistan
  • M.Phil. in Applied Chemistry (2015–2017)
    Thesis: Ab-Initio Study of Halotoluenes
    University of Malakand, Pakistan
  • Bachelor of Science in Chemistry (2009–2013)
    Thesis: Qualitative and Quantitative Analysis of Drinking Water Samples of Different Localities in District Lower Dir
    Islamia College Peshawar, Pakistan

Professional Experience🌱

Dr. Khan has served as a lecturer and researcher at esteemed institutions, including the University of Malakand and Gandhara Institute of Basic Sciences. His work spans teaching, material modeling, and computational research funded by the Higher Education Commission of Pakistan. Notably, his Ph.D. studentship under Project No. 1486 involved the development of novel microporous polymeric cathode materials for magnesium-ion batteries, showcasing his ability to address cutting-edge challenges in energy storage technologies.

Research Interests🔬
  • Computational chemistry and first-principles studies
  • Design and optimization of electrode materials for rechargeable batteries
  • Catalytic mechanisms for environmental and energy applications
  • Microporous polymeric materials for energy storage
  • Density Functional Theory (DFT) and advanced simulation codes

Author Metrics

Dr. Khan’s research output includes over 50 publications in reputable journals such as Journal of Power Sources, Computational Materials Science, and Journal of Physical Chemistry C. His work has garnered significant recognition, reflected by:

  • Impact Factor: 209.98 (2024)
  • h-index: 17
  • i10-index: 24
  • Citations: Over 800

His research contributions focus on enhancing the performance of energy storage materials and advancing computational chemistry methodologies.

Publications Top Notes 📄

1. Adsorptive removal of Cd²⁺ from aqueous solutions by a highly stable covalent triazine-based framework

  • Authors: Z.A. Ghazi, A.M. Khattak, R. Iqbal, R. Ahmad, A.A. Khan, M. Usman, F. Nawaz, et al.
  • Journal: New Journal of Chemistry
  • Volume: 42, Issue 12, Pages 10234-10242
  • Year: 2018
  • Citations: 84
  • Abstract: This study explores the efficacy of a covalent triazine-based framework for the adsorptive removal of cadmium ions (Cd²⁺) from aqueous solutions. It demonstrates exceptional stability and high adsorption capacity, supported by experimental results and theoretical insights.
  • Impact: Highlights the potential of covalent frameworks for environmental remediation and water purification.

2. Removal of azo dye from aqueous solution by a low-cost activated carbon prepared from coal: adsorption kinetics, isotherms study, and DFT simulation

  • Authors: Saeed Ullah Jan, Aziz Ahmad, Adnan Ali Khan, Saad Melhi, Iftikhar Ahmad, et al.
  • Journal: Environmental Science and Pollution Research
  • Year: 2020
  • Citations: 58
  • Abstract: The research investigates the use of coal-derived activated carbon for the removal of azo dyes from water. Combining adsorption kinetics and density functional theory (DFT) simulations, the study provides a comprehensive understanding of the adsorption mechanism.
  • Impact: Showcases cost-effective and efficient methods for wastewater treatment.

3. DFT investigation of adsorption of nitro-explosives over C₂N surface: Highly selective towards trinitro benzene

  • Authors: Sehrish Sarfaraz, Muhammad Yar, Adnan Ali Khan, Rashid Ahmad
  • Journal: Journal of Molecular Liquids
  • Volume: 352, Article 118652
  • Year: 2022
  • Citations: 46
  • Abstract: This study examines the adsorption properties of a C₂N surface for nitro-explosives, particularly trinitro benzene. The results demonstrate the material’s high selectivity and potential for explosive detection.
  • Impact: Contributes to the development of advanced materials for sensing and security applications.

4. Investigation of the photocatalytic potential enhancement of silica monolith decorated tin oxide nanoparticles through experimental and theoretical studies

  • Authors: Idrees Khan, Adnan Ali Khan, Ibrahim Khan, Muhammad Usman, et al.
  • Journal: New Journal of Chemistry
  • Volume: 44, Pages 13330
  • Year: 2020
  • Citations: 43
  • Abstract: This paper focuses on the enhancement of photocatalytic properties of silica monoliths decorated with tin oxide nanoparticles. Experimental and theoretical studies validate the material’s efficiency in environmental remediation.
  • Impact: Advances the application of nanostructured materials for photocatalysis.

5. Influence of electric field on CO₂ removal by P-doped C₆₀-fullerene: A DFT study

  • Authors: Adnan Ali Khan, Iftikhar Ahmad, Rashid Ahmad
  • Journal: Chemical Physics Letters
  • Year: 2020
  • Citations: 40
  • Abstract: The study investigates the role of an external electric field in enhancing CO₂ adsorption on phosphorus-doped C₆₀-fullerenes. The findings provide insights into improving adsorption efficiency using computational chemistry techniques.
  • Impact: Demonstrates innovative approaches for CO₂ capture and environmental sustainability.

Conclusion

Dr. Adnan Ali Khan is a strong and deserving candidate for the Young Scientist Award. His expertise in applied chemistry, particularly in computational approaches for energy storage, has led to impactful contributions that address global challenges in energy and sustainability. With his robust publication record, innovative methodologies, and early career accomplishments, he exemplifies the qualities sought in an award-winning scientist.

By focusing on global collaborations, leadership in research funding, and industrial applications, Dr. Khan can further solidify his position as a leader in his field and continue to make transformative contributions to science and society.