Sathish Panneer Selvam | Theoretical Advances | Best Scholar Award

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Dr. Sathish Panneer Selvam | Theoretical Advances | Best Scholar Award

Assistant Professor at Gachon university | South Korea

Dr. Sathish Panneer Selvam is a dynamic Assistant Professor at Gachon University, South Korea, specializing in electrochemical biosensors, nanomaterials, and density functional theory (DFT). With a strong foundation in experimental chemistry and computational modeling, Dr. Selvam’s interdisciplinary research bridges the gap between biomedical diagnostics and renewable energy catalysis, contributing significantly to next-generation sensor technologies.

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🎓 Early Academic Pursuits

Dr. Selvam began his academic journey with a Master’s degree in Electrochemical Sensing and Water Splitting under Prof. Kyusik Yun, where he focused on DNA-based nanomaterials and self-assembled sensors. He pursued his PhD (2020–2024) under Prof. Sungbo Cho, contributing to sensor development for disease diagnostics and reaction mechanism analysis via DFT. This formative period laid the groundwork for his future breakthroughs in smart diagnostics.

💼 Professional Endeavors

Starting as a Quality Control Executive at Biocon Biopharmaceutical Ltd., Dr. Selvam transitioned seamlessly into academia. His current role as an Assistant Professor (2024–2025) at Gachon University involves leading advanced biosensing projects, such as cancer diagnostics, enzyme activity detection, and nanocomposite development. His hands-on expertise spans fabrication, characterization, and computational modeling.

🔬 Contributions and Research Focus

Dr. Selvam’s research is distinguished by its interdisciplinary depth and real-world relevance. He has designed single-atom catalyst biosensors for detecting pancreatic and breast cancer. Additionally, he has explored molecularly imprinted polymers for biomarker detection and utilized DFT and molecular dynamics to simulate reaction pathways. His development of triboelectric nanogenerators for self-powered bacterial detection reflects his ability to address critical challenges in medical diagnostics, environmental monitoring, and energy applications.

🌍 Impact and Influence

Dr. Selvam has authored 16+ peer-reviewed publications, many in high-impact journals such as Chemical Engineering Journal, Small Methods, and Biosensors and Bioelectronics, with impact factors ranging from 8 to 23. His contributions to cancer biosensing, H2 evolution, and COVID-19 detection have attracted international collaborations with researchers from UK, France, and India, solidifying his global influence.

📊 Academic Cites & Recognition

Dr. Selvam’s work is increasingly cited by peers in the fields of biosensors, nanotechnology, and theoretical chemistry. With several publications already gaining traction in the academic community, he is on track for significant citation growth and thought leadership in applied quantum chemistry and nanomedicine.

🧪 Research Skills

Dr. Selvam demonstrates a robust technical skill set that seamlessly bridges experimental techniques with computational modeling. He excels in electrochemical characterization using systems like Iviumstat, Biologics, and PARSTAT. His expertise in structural analysis includes SEM, TEM, XRD, EXAFS, and Raman spectroscopy. Additionally, he is proficient in High-Performance Liquid Chromatography (HPLC) and a variety of spectroscopic tools. On the theoretical side, he utilizes DFT simulations, molecular docking, and molecular dynamics, allowing for deep insights into complex reaction mechanisms.

🎓 Teaching Experience

As an Assistant Professor, Dr. Selvam is engaged in mentoring undergraduate and graduate students. He fosters a research-driven learning environment that encourages critical thinking, scientific writing, and interdisciplinary collaboration, essential for shaping future scientists.

🌟Patents

Dr. Selvam holds several patents, including the Chalcogenide Loaded Cobalt MOF for Patulin Mycotoxin Detection (KR Patent 10-2437215), an Electrochemical Biosensing Platform for Rheumatoid Arthritis Biomarker detection (KR Patent 10-2381031), and a Nanocomposite modified electrode for Etidronic acid detection (KR Patent 10-2475238), co-authored with Sungbo Cho and Kyusik Yun. These innovations demonstrate his expertise in biosensing, electrochemical platforms, and biomarker detection.

📘 Legacy and Future Contributions

Dr. Selvam has a strong portfolio of patents, a growing reputation in academic publishing, and a unique ability to synthesize experimental and computational insights. As a thought leader in smart biosensing and energy catalysis, his future contributions are expected to include the development of scalable diagnostic tools for global health, AI-integrated sensor platforms, and further exploration of quantum chemistry for bio-interfaces. His work promises significant advances in both healthcare and energy solutions.

Publications Top Notes

EXAFS and spectroscopic insights into Mn, Tc, and Re-doped phthalocyanines: A multifaceted DFT study of electronic and optical properties

  • Authors: Sathish Panneer Selvam, Zeeshan, Sungbo Cho
    Journal: Surfaces and Interfaces
    Year: 2025

Cerium single atom anchored silver selenide: A high-performance catalyst for hydrogen evolution reaction with ultra-low activation energy and enhanced stability

  • Authors: Sathish Panneer Selvam, Sungbo Cho
    Journal: Surfaces and Interfaces
    Year: 2024

Experimental insights and DFT analysis of metal-free DNA nanocatalyst with enhanced hydrogen evolution via phosphate-mediated proton acceptance

  • Authors: Sathish Panneer Selvam, Shanmugasundaram Kamalakannan, K. Rudharachari Maiyelvaganan, Muthuramalingam Prakash, Sivalingam Gopi, Hansa Mahajan, Kyusik Yun, Sungbo Cho
    Journal: International Journal of Hydrogen Energy
    Year: 2024

Highly Synergistic Co3+ and Pyridinic‐N‐Rich Bifunctional Electrocatalyst for Ultra‐Low Energy-Driven Effective Hydrogen Production and Urea Oxidation

  • Authors: Sathish Panneer Selvam, Sungbo Cho
    Journal: Advanced Sustainable Systems
    Year: 2022

Novel SeS2-loaded Co MOF with Au@PANI comprised electroanalytical molecularly imprinted polymer-based disposable sensor for patulin mycotoxin

  • Authors: Sathish Panneer Selvam
    Journal: Biosensors and Bioelectronics
    Year: 2021

 

Aleksandr Sipatov | Experimental methods | Best Researcher Award

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Prof. Aleksandr Sipatov | Experimental methods | Best Researcher Award

Professor at National Technical Univercity “Kharkiv Polytechnic Institute” | Ukraine

Dr. Alexander Yurievich Sipatov is a distinguished Professor in the Metal and Semiconductor Physics Department at the National Technical University “Kharkov Polytechnic Institute” (KPI), Ukraine. Born on March 21, 1957, in Nizhny Novgorod, Russia, Dr. Sipatov has had a long and illustrious career spanning over several decades in the field of semiconductor physics and nanostructures. His work has made notable contributions to the development of quantum effects and the exploration of superconductivity and thermoelectric properties in semiconductor multilayer nanostructures.

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Early Academic Pursuits 🎓

Dr. Sipatov’s academic journey began at the National Technical University “Kharkov Polytechnic Institute” (KPI), where he earned his Engineer-Physicist degree in 1980. He pursued postgraduate studies at KPI, completing his Ph.D. in 1986 and later achieving the title of Doctor of Science in 2007. Between 1995 and 1998, Dr. Sipatov was awarded a Postdoctoral stipend to further hone his expertise and research skills. His academic achievements laid the foundation for a highly successful career in semiconductor physics.

Professional Endeavors 💼

Dr. Sipatov’s professional career at KPI began in 1980 as an Engineer, and his role rapidly evolved over the years. He served as a Junior Researcher from 1983 to 1990, a Researcher from 1990 to 1992, and as a Senior Researcher from 1992 to 1995 and 1998 to 2007. His increasing responsibilities and leadership roles included becoming a Leading Researcher from 2007 to 2012 and the Head of the Technical Cryophysics Department at KPI from 2012 to 2020. Since 2020, he has held the position of Professor at KPI, where he continues to contribute significantly to both teaching and research.

Contributions and Research Focus 🔬

Dr. Sipatov’s research focuses on the growth, structure, and electronic, optic, magnetic, and thermoelectric properties of semiconductor multilayer nanostructures, particularly chalcogenides of elements such as lead (Pb), tin (Sn), bismuth (Bi), europium (Eu), and ytterbium (Yb). His studies have led to several groundbreaking discoveries, including:

  1. Energy Spectrum Quantization in thin films, notably in PbS films and PbS-EuS superlattices, identified by shifts in the photoluminescence edge.
  2. Resonant Tunneling phenomena observed through negative differential resistance in PbS-EuS double barrier tunneling structures.
  3. The discovery of superconductivity in IV-VI superlattices, with Tc values between 3-6 K.

Currently, Dr. Sipatov is investigating the thermoelectric and magnetic properties of semiconductor thin films and nanostructures, which have important applications in energy efficiency and advanced electronics.

Impact and Influence 🌍

Dr. Sipatov’s work has had a profound impact on quantum physics and the field of nanostructures. His findings have broadened the understanding of quantum effects in semiconductors, contributing to advances in quantum technologies and low-temperature physics. Furthermore, his contributions to superconductivity have opened up new avenues for research in quantum computing and energy-efficient technologies. The interdisciplinary nature of his work positions him as a key figure in nanoscience, with direct implications for industries ranging from electronics to energy storage.

Academic Cites 📚

Dr. Sipatov is a highly published researcher with more than 60 publications in peer-reviewed journals, showcasing his dedication to advancing scientific knowledge. His work is indexed in Scopus (ID: 7004596183), highlighting his significant influence and recognition in the scientific community. His research continues to be cited by scholars worldwide, cementing his reputation as a thought leader in semiconductor physics and nanotechnology.

Research Skills 🔧

Dr. Sipatov possesses a broad range of specialized research skills, including:

  • Material Synthesis and Growth of semiconductor multilayer nanostructures.
  • Expertise in quantum effects such as energy spectrum quantization and resonant tunneling.
  • Advanced techniques for studying superconductivity and the magnetic properties of semiconductor materials.
  • Deep understanding of thermoelectric phenomena and their practical applications.

His expertise in low-temperature physics and nanoelectronics places him at the cutting edge of research in these fields.

Teaching Experience 📖

As a Professor at KPI, Dr. Sipatov has dedicated a significant portion of his career to teaching and mentoring the next generation of scientists and engineers. His leadership as the Head of the Technical Cryophysics Department between 2012 and 2020 provided an invaluable platform for the development of young researchers in the field of semiconductor physics. Through his courses and research supervision, Dr. Sipatov has influenced countless students, shaping the future of material science and nanotechnology.

Legacy and Future Contributions 🔮

Dr. Sipatov’s research legacy lies in his innovative contributions to the understanding of quantum effects in semiconductor nanostructures and superconductivity. His work on thermoelectric and magnetic properties holds the potential to revolutionize energy-efficient technologies and next-generation electronics. Moving forward, his future contributions are likely to focus on advanced materials for quantum computing and renewable energy solutions, continuing to drive progress in sustainable technologies and nanoscience.

Publications Top Notes

Interdiffusion in chalcogenide semiconductor superlattice nanostructures

  • Authors: A.Y. Sipatov, L.E. Konotopsky, E. Moroz, V.V. Volobuev
    Journal: Solid State Communications
    Year: 2025

Quantum interference phenomena and electron – electron interaction in topological insulator Bi2Se3 thin polycrystalline films

  • Authors: O.I. Rogachova, O. Pavlosiuk, A.V. Meriuts, K.V. Novak, D. Kaczorowski
    Journal: Thin Solid Films
    Year: 2022

Growth mechanism, structure and thermoelectric properties of thermally evaporated Bi2(Te0.9 Se01)3 thin films

  • Authors: O.I. Rogachova, S. Kryvonohov, A.G. Fedorov, O.N. Nashchekina, K.V. Novak
    Journal: Functional Materials
    Year: 2022

Effect of aging on thermoelectric properties of the Bi2Te3 polycrystals and thin films

  • Authors: O.I. Rogachova, K.V. Novak, A.N. Doroshenko, T.I. Khramova, S.A. Saenko
    Journal: Functional Materials
    Year: 2021

Size effects and thermoelectric properties of Bi0.98Sb0.02 thin films

  • Authors: O.I. Rogachova, K.V. Novak, D.S. Orlova, O.N. Nashchekina, G.V. Lisachuk
    Journal: Journal of Thermoelectricity
    Year: 2020

 

Issam Derkaoui | Materials Science | Member

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Dr. Issam Derkaoui | Materials Science | Member

PHD at FSDM, Fez, Morocco

Issam Derkaoui, a PhD holder in Materials Science and Industrial Processes, specializes in the experimental development of nanocomposites with graphene derivatives and metal oxides. His research, spanning from synthesis to characterization, aims to advance nanotechnologies. Additionally, he employs first-principles calculations like DFT to model metal oxides and perovskites. With extensive post-doctoral and teaching experience, Issam has honed skills in materials characterization and synthesis methods. He has contributed to numerous publications and presented at international conferences. As a reviewer and organizer, Issam actively engages in the academic community, fostering advancements in materials science and computational physics.

Professional Profiles:

EDUCATION

Temporary Post-Doctoral Researcher Solid State Physics Laboratory, FSDM, Fez, Morocco July 2018 – 2022 Experimental: Synthesis and characterization of nanomaterials and nanocomposites. Theoretical: Validation of experimental results using DFT calculations. Permanent Teacher of Physics Preparatory classes for engineering schools, Ibn Ghazi, Meknes, Morocco 2015 – 2019 Training in Materials Characterization Techniques National Institute of Materials Physics (NIMP), Bucharest, Romania X-ray diffractometer, Raman Spectroscopy, Spectroscopic Ellipsometry Training in Material Synthesis Methods National Institute of Materials Physics (NIMP), Bucharest, Romania Magnetron Sputtering Method, Hydrothermal Method, Pyrolysis Spray Technique Vacancy for the Training: Methodology of Writing a Final Project Laboratory of Theoretical and Applied Physics, FSDM, Fez, Morocco

RESEARCH INTERNSHIPS

Associate Professor: University of Dschang, Cameroon (2019 – Present) Lecturer and Visiting Lecturer: Various institutions in Cameroon (2012 – 2019) Visiting Lecturer: National Polytechnic Bambui, Cameroon (2008 – 2009) Visiting Lecturer: Intitut Privé Polyvalent la Reforme, Cameroon (2007 – 2008)

SOFTWARE SKILLS

CASTEP Materials Studio Movavi OriginLab PVSyst PVGIS PowerPoint Quantum Espresso Python

RESEARCH AREA EXPERIENCE

Issam Derkaoui’s research interests lie in both experimental and theoretical aspects of materials science, with a focus on: Hydrothermal Synthesis Chemical synthesis methods Metal oxides (VxOy, WOx, ZnO, etc.) Graphene (GO, rGO) Nanostructures Nanocomposites Structural properties Optoelectronic properties

Research Focus:

Based on the provided publications, Issam Derkaoui’s research primarily focuses on the structural, electronic, and optical properties of various materials, including ZnO nanowires, graphene nanohybrids, and metal oxides. His investigations span experimental and theoretical approaches, employing techniques such as first-principles calculations and experimental characterization methods. Derkaoui’s work contributes to advancing our understanding of nanocomposites, thin films, and semiconductor materials, with applications ranging from optoelectronic devices to photodetectors. Overall, his research interests lie at the intersection of materials science, nanotechnology, and computational physics, aiming to drive innovations in diverse technological domains.

Publications 

  1. Optimization of the luminescence and structural properties of Er-doped ZnO nanostructures: effect of dopant concentration and excitation wavelength, cited by: 21, Publication date: 2022.
  2. Improved first-principles electronic band structure for cubic (Pm3m) and tetragonal (P4mm, P4/mmm) phases of BaTiO3 using the Hubbard U correction, Publication date: 2023.
  3. Overview of the Structural, Electronic and Optical Properties of the Cubic and Tetragonal Phases of PbTiO3 by Applying Hubbard Potential Correction, Publication date: 2023.
  4. Thermionic Emission of Atomic Layer Deposited MoO3/Si UV Photodetectors, Publication date: 2023.
  5. Effect of strontium (Sr) doping on the structural, electronic and optical properties of ZnO, by first-principles calculations, Publication date: 2023.
  6. Reduced graphene oxide-functionalized zinc oxide nanorods as promising nanocomposites for white light emitting diodes and reliable UV photodetection devices, Publication date: 2023.
  7. Impact of thickness on optoelectronic properties of α-MoO3 film photodetectors: Integrating first-principles calculations with experimental analysis, Publication date: 2023.
  8. Self-Powered UV Photodetector Utilizing Plasmonic Hot Carriers in 2D α-MoO3/Ir/Si Schottky Heterojunction Devices, Publication date: 2023.
  9. Investigation of structural and optical properties of Mg doped ZnS thin films prepared by Mist-CVD technique: Experimental and theoretical aspectsPublication date: 2024.
  10. The interface structural, electronic and optical properties of ZnO nanowires/Graphene nanohybrid (ZnO NWs/G): Experimental and theoretical DFT investigations, Publication date: 2024.

 

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