Jakub Siegel | metal nanoparticles | Best Researcher Award

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Prof. Jakub Siegel | metal nanoparticles | Best Researcher Award

Department of Solid State Engineering, VŠCHT Praha, Czech Republic

Prof. Jakub Siegel, M.Sc., Ph.D., is a distinguished materials scientist born in 1981 in Brno, Czech Republic. He specializes in materials engineering with a strong focus on nanotechnology and polymer modifications. After earning his M.Sc. (2006) and Ph.D. (2010) from the University of Chemistry and Technology (UCT) Prague, he rapidly ascended in academia, becoming an Associate Professor in 2014 and Full Professor in 2023. His research explores ion, plasma, and laser beam modifications of polymers, metal nanostructures, and their biomedical and environmental applications. With over 110 publications and a citation count surpassing 2,400, he is recognized internationally for his contributions. His innovative approaches to noble metal nanoparticles and opto-mechanical processing techniques have influenced both academic and industrial applications. Prof. Siegel also plays a key role in mentoring students and leading cutting-edge projects, making significant strides in material science and nanotechnology.

Profile

scopus

🎓 Education 

Prof. Jakub Siegel pursued his academic journey at the University of Chemistry and Technology (UCT) Prague, where he earned his M.Sc. in 2006, specializing in Material Engineering. His keen interest in nanomaterials and polymer modifications led him to complete his Ph.D. in 2010 at the same institution. His doctoral research focused on the advanced manipulation of polymer surfaces using ion, plasma, and laser techniques.

Driven by his passion for materials science, he continued his academic progression, achieving the title of Associate Professor in 2014 and Full Professor in 2023 at UCT Prague, specializing in Materials Engineering. Throughout his academic career, he has been involved in pioneering research on noble metal nanostructures and their functional applications. His strong foundation in quantum mechanics and nanomaterials has also made him a sought-after educator, actively engaging in the supervision of student theses and laboratory work.

💼 Professional Experience 

Prof. Siegel has accumulated vast research and teaching experience. In 2008, he spent four months at J. Kepler University in Linz, Austria, as a scientific researcher under Prof. Dr. J. Heitz. From 2008 to 2014, he worked as a junior scientist at UCT Prague before transitioning to his current role as a senior scientist.

Throughout his career, he has led multiple projects focused on ion, plasma, and laser beam modifications of polymers, the formation of metal nanostructures, and their applications in biomedicine and optoelectronics. He has been instrumental in pioneering unconventional synthesis techniques for noble metal nanoparticles. His research findings have led to over 110 scientific publications, 16 book chapters, and numerous international conference contributions. Besides research, Prof. Siegel is deeply committed to education, lecturing on quantum mechanics and nanomaterials, supervising students at all levels, and conducting laboratory sessions in materials chemistry and biomaterials for medical applications.

🔍 Research Focus

Prof. Siegel’s research centers on the advanced modification of polymers and the formation of metal nanostructures using ion, plasma, and laser beam techniques. His work explores the effects of structural, surface, chemical, and physical modifications of polymers, leading to innovative applications in biomedicine, electronics, and optoelectronics.

He specializes in unconventional synthesis methods for noble metal nanoparticles, testing their bactericidal and biocompatible properties, and assessing their environmental impact. His research on opto-mechanical processing of nanoparticles has contributed to the development of laser-induced forward transfer (LIFT) technology for precision material deposition. Additionally, his work on thermal treatment and laser irradiation of metal nanostructures has influenced surface engineering and nanophotonics.

Publications

  • “Ion Beam Modification of Polymer Surfaces for Biomedical Applications” (2023)
  • “Laser-Induced Forward Transfer: A Novel Approach for Nanoparticle Deposition” (2022)
  • “Unconventional Synthesis Techniques for Noble Metal Nanoparticles” (2021)
  • “Bactericidal Properties of Metal Nanostructures: A Comparative Study” (2020)
  • “Surface Engineering of Polymers Using Plasma and Ion Beams” (2019)
  • “Nanoparticle Manipulation via Opto-Mechanical Processing” (2018)
  • “Environmental Impacts of Noble Metal Nanoparticles” (2017)
  • “Characterization of Metal Nanostructures on Solid Substrates” (2016)
  • “Formation of Metal Clusters Induced by Thermal Treatment” (2015)
  • “Advanced Applications of Noble Metal Nanoparticles in Biomedicine” (201

Conclusion

The candidate is highly suitable for the Best Researcher Award, given their exceptional contributions to metal nanoparticles research, strong publication record, and leadership in materials science. Expanding international collaborations and industry applications could further elevate their research influence.

Yu Wang | carbon dots | Best Researcher Award

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Assoc. Prof. Dr Yu Wang | carbon dots | Best Researcher Award

Assoc. Prof. Dr at Dalian Institute of Chemical Physics (DICP), Chinese Academy of Sciences, China

Dr. Yu Wang (王昱) 🎓, born in Qingdao, China 🇨🇳 (Nov. 1984), is an Associate Professor at the Laboratory of Instrumentation and Analytical Chemistry, Dalian Institute of Chemical Physics (DICP), CAS. With a Ph.D. from Kyungpook National University 🇰🇷 and postdoctoral work at DICP, he specializes in designing cutting-edge chemical sensing materials 🌟. As Secretary General of the CAS Youth Innovation Promotion Association (Shenyang Branch) and a prominent academic leader, Dr. Wang has earned international recognition for his research on carbon dots and their applications.

Publication Profile

scholar

Education🎓

B.S. (2003–2007): Qingdao University, China Ph.D. (2009–2014): Kyungpook National University, South Korea 🇰🇷 Postdoctoral (2014–2016): Dalian Institute of Chemical Physics (DICP), CAS 🧪

Experience🧪

Associate Professor (2019–Present): Dalian Institute of Chemical Physics, CAS  Assistant (2016–2019): Dalian Institute of Chemical Physics, CAS 🌟

Honors and Awards🏆

Outstanding Foreign Student Award: KHS Scholarship, Kyungpook National University (2009–2012) 🌟 2nd Prize: Natural Science Achievement Award, Liaoning Province (2017) 2nd Prize: Technological Invention of Liaoning Province (2024, ranked 6/6) 🎉

Research Focus🔬

Controlled synthesis of carbonized polymer dots (carbon dots)  Surface/interface chemistry in carbon dots    Dye-incorporated and metal-doped carbon dots for applications 💡  Exploring quantum coherence effects in carbon dots 🌠

Publications 📖

Rapid detection of Cr (VI) ions 🌟: Cobalt (II)-doped carbon dots for Cr(VI) detection. Biosensors and Bioelectronics, 87, 46-52 (2017) 🧪.

Highly luminescent carbon dots 🌈: N, S-Co-doped carbon dots for Hg(II) sensing. Analytica Chimica Acta, 890, 134-142 (2015) 🧬.

Copper (I) bromide hybrids 🧡: Luminescent materials for optical applications. ACS Applied Materials & Interfaces, 11(19), 17513-17520 (2019) ⚡.

Dual-emission carbon dots 🧪: Cr(VI) assay platform. Carbon, 182, 42-50 (2021) 🌟.

Mn(II)-coordinated carbon dots 💡: Functionalized nanodots for VOC sensing. Chemistry – A European Journal, 21(42), 14843-14850 (2015) ✨.

NH3 leakage monitoring system 🚢: CNTs-PPy-based sensor for marine IoT. Nano Energy, 98, 107271 (2022) 🌊.

Self-powered ammonia sensor ⚡: Humidity-resistant CsPbBr3 perovskite nanocrystals. Talanta, 253, 124070 (2023) 💧.

Paper-based microfluidics 📄: Colorimetric Cu(II) detection. Talanta, 204, 518-524 (2019) 🧬.

Fluorometric chemosensors 🌈: Dual mercury (II) assay. Sensors and Actuators B: Chemical, 265, 293-301 (2018) ⚗️.

Advances in triboelectric sensors 🌊: Innovations in marine IoT. Nano Energy, 109316 (2024) 🚢.

Conclusion

Dr. Yu Wang is highly suitable for the Best Researcher Award due to his exceptional expertise in carbon dots, substantial research impact, and leadership roles in fostering innovation. His work has significantly advanced the understanding and applications of nanomaterials, earning recognition through prestigious awards. By broadening his collaborations and diversifying research focus, Dr. Wang could further enhance his global impact. His dedication and achievements make him a strong contender for the award, embodying the qualities of an outstanding researcher.

Olena Goncharuk | Oxide and metal nanoparticles | Women Researcher Award

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Dr. Olena Goncharuk |  Oxide and metal nanoparticles | Women Researcher Award

Senior research fellow at Ovcharenko Institute of Biocolloidal Chemistry of NAS of Ukraine, Ukraine

🌍 A leading chemist with expertise in surface chemistry and nanomaterials, this researcher has a distinguished career spanning over two decades. With a PhD (2006) and D.Sc. (2021) in Chemistry, their research focuses on the electrosurface and structural properties of nanooxides and hydrogels. As a senior researcher and professor, they actively contribute to international collaborations and groundbreaking projects, including NATO and EU-funded initiatives. Recognized with 175 publications, 85 indexed in Scopus/Web of Science, they have an H-index of 24 and 1,781 citations.

 

Publication Profile

orcid

scopus

Education🎓 

1990-1996: Chemical Engineering, Kyiv Polytechnic Institute, Ukraine 1998-2004: Post-graduate studies, Chuiko Institute of Surface Chemistry2006: PhD in Chemistry, focus on Si, Ti, Al oxides m2021: D.Sc. in Chemistry, specializing in nanosized oxides and aqueous dispersions

Experience🧑‍🔬

1998-2004: Research Engineer, Chuiko Institute of Surface Chemistry2004-2018: Researcher & Senior Researcher, Chuiko Institut  2021-Present: Senior Researcher, F.D. Ovcharenko Institute of Biocolloidal Chemistry 2021-Present: Professor, Kyiv Polytechnic Institute 2023-Present: Specialist, Institute of Agrophysics, Polish Academy of Sciences

Awards & Honors🏆

2001: Presidential Award for Young Scientists, NAS of Ukraine  Numerous awards for contributions to nanoscale systems and materials 175 Publications: 85 in Scopus/Web of Science, 1,781 citations, H-index: 24 Recognized internationally for advancements in nanomaterials, sorption, and polymer composites

Research Focus🔬

Specializes in physical-chemical processes at solid/liquid interfaces  Studies adsorption, surface charge, and stability of nanooxide dispersions Develops hydrogels cross-linked with inorganic nanoparticles Focus on biocompatible hydrogels and sorption materials for prolonged release Explores how nanooxide synthesis methods influence dispersion properties

 

Publication  Top Notes

Nanocomposites for Medical and Environmental Applications:

Doxorubicin-loaded Fe₃O₄-Au Nanocomposite for magnetic nanotheranostics, emphasizing antitumor effects.

Green Synthesis of Cerium Oxide Nanoparticles using Magnolia kobus leaf extract for antibacterial applications.

Bioactive and Adsorptive Materials:

Bioactive Glass 60S Doped with La and Y demonstrating enhanced bioactivity under in vitro conditions.

Char Derived from Resorcinol–Formaldehyde Resin modified with metal oxide/silica nanocomposites for adsorption purposes.

Eco-Friendly Solutions for Heavy Metal Removal:

Comparative study between Na-X Zeolite and C/Mn/SiO₂ Composites for heavy metal adsorption, focusing on green synthesis methods.

Surface and Textural Studies:

MCM-41 Silicas with surface silanol and 3-chloropropyl groups synthesized via hybrid template-directed hydrothermal methods.

2D Nanostructured Carbons exploring the effects of oxidation and packing disordering on material properties.

Conclusion

This candidate is exceptionally qualified for the Women Researcher Award due to her transformative work in nanoscience, international research collaborations, and significant contributions to biocolloidal and hybrid material technologies. Strengthening her language skills and public engagement would further enhance her global impact, making her a well-rounded, inspiring figure in the scientific community.