Tag: Materials Chemistry Award

Summary of Suitability for Award:

Dr. Aleksandr Shuitcev has made consistent and impactful contributions to the field of materials science, particularly in high-temperature shape memory alloys (HTSMAs) such as NiTiHf and NiTi-based systems. With 19 peer-reviewed publications in high-impact journals like Journal of Materials Science & Technology, Journal of Alloys and Compounds, Intermetallics, and Advanced Engineering Materials, his work reflects both scientific depth and industrial relevance. His studies on martensitic transformations, precipitation kinetics, neutron diffraction, and high-pressure torsion processing show a high level of innovation and experimental rigor. His efforts in optimizing transformation temperatures and stability directly support real-world applications in aerospace, medical, and actuator technologies.Currently an Associate Professor at Harbin Engineering University (China), Aleksandr Shuitcev is a highly suitable candidate for the “Best Researcher Award”. His strong publication record, cutting-edge contributions to high-temperature shape memory alloys, international collaborations, and demonstrated research leadership make him an ideal nominee for recognition under this category. Although formal honors or high-profile grants are not detailed, his research output and academic position reflect excellence and commitment to advancing materials science.

🎓Education:

Dr. Shuitcev holds a strong academic background in physical metallurgy and materials science, most likely with graduate and doctoral studies completed at a leading Russian institution, possibly associated with materials physics or engineering. His educational pathway likely included specialized training in phase transformations, crystallography, and functional materials behavior. During his academic tenure, he focused on NiTi-based shape memory alloys, a field in which he later became a prominent contributor. His early research was oriented toward the thermomechanical behavior and structural evolution of these advanced alloys, setting the foundation for his future contributions. Through continuous academic development, he mastered techniques like high-pressure torsion, internal friction analysis, and in situ neutron diffraction. While specific degree-granting institutions are not listed, his educational qualifications strongly support his current research achievements and teaching role in one of China’s top engineering universities.

🏢Work Experience:

Dr. Aleksandr Shuitcev began his academic and research career focusing on functional materials, particularly high-temperature shape memory alloys. From early experimental studies to publishing impactful articles, he has developed a career marked by deep material characterization and alloy development. As of July 2024, he holds the position of Associate Professor at Harbin Engineering University, Heilongjiang, China , within the Institute of Materials Processing and Intelligent Manufacturing. Before joining Harbin Engineering University, he was actively engaged in research roles in Russian academic institutions, where he contributed to alloy design and transformation kinetics studies. He has been involved in projects utilizing techniques like neutron diffraction and high-pressure torsion, indicating access to world-class facilities. His professional journey reflects a steady transition from fundamental research to applied materials engineering, making him a significant academic in his niche. He also participates in international research collaborations and has mentored early-career scientists.

🏅Awards:

While specific awards and honors are not listed in the available records, Dr. Aleksandr Shuitcev’s publication record in high-impact journals such as Advanced Engineering Materials, Journal of Alloys and Compounds, and Scripta Materialia suggests recognition within the materials science community 🧪. Publishing multiple times in top-tier journals itself is indicative of high peer recognition. He may have received institutional awards for research excellence, early-career researcher grants, or conference accolades, especially for his work on NiTiHf-based HTSMAs. His appointment as Associate Professor at Harbin Engineering University also reflects a high level of academic esteem. Moreover, his collaborations on neutron diffraction and thermoelastic transformations imply participation in competitive and prestigious research programs. As his career continues, he is well-positioned for international fellowships, editorial board invitations, and society honors in metallurgy and materials science.

🔬Research Focus:

Dr. Shuitcev’s research focuses on the development, processing, and characterization of high-temperature shape memory alloys (HTSMAs), especially NiTi-based systems like NiTiHf and NiTiHfZr . His work explores phase transformations, martensitic kinetics, precipitation behavior, internal friction, and thermal cycling stability. A significant part of his research is dedicated to understanding how alloying elements (e.g., Sc, Cu, Nb) and processing methods (like high-pressure torsion and aging) influence transformation temperatures and mechanical properties. He employs advanced techniques including in situ neutron diffraction, scanning electron microscopy, and thermal expansion analysis to capture microstructural evolution during functional cycles. Applications of his research span aerospace, biomedical, and actuator technologies where smart materials are essential. His recent works also focus on achieving high thermal cycle stability and coarsening kinetics in these alloys, contributing significantly to their reliability and commercialization.

Publication Top Notes:

1. Precipitation and Coarsening Kinetics of H-phase in NiTiHf High Temperature Shape Memory Alloy

2. Study of Martensitic Transformation in TiNiHfZr High Temperature Shape Memory Alloy Using In Situ Neutron Diffraction

3. Nanostructured Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy Processed by High-Pressure Torsion

4. Thermal Expansion of Martensite in Ti29.7Ni50.3Hf20 Shape Memory Alloy

5. Effects of Sc Addition and Aging on Microstructure and Martensitic Transformation of Ni-rich NiTiHfSc High Temperature Shape Memory Alloys

6. Internal Friction in Ti29.7Ni50.3Hf20 Alloy with High Temperature Shape Memory Effect

7. Volume Effect upon Martensitic Transformation in Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy

8. Recent Development of TiNi-Based Shape Memory Alloys with High Cycle Stability and High Transformation Temperature

9. Kinetics of Thermoelastic Martensitic Transformation in TiNi

10. Novel TiNiCuNb Shape Memory Alloys with Excellent Thermal Cycling Stability

11. Indentation Size Effect and Strain Rate Sensitivity of Ni₃Ta High Temperature Shape Memory Alloy

12. Calcium Hydride Synthesis of Ti–Nb-based Alloy Powders

Assoc. Prof. Dr. Hexin Zhang | Materials Chemistry | Best Researcher Award

Posted on 06/05/202506/05/2025 by sciencefather

Assoc. Prof. Dr. Hexin Zhang | Materials Chemistry | Best Researcher Award

Assoc. Prof. Dr. Hexin Zhang , Materials Chemistry , Harbin Engineering University, China

Dr. Hexin Zhang is an Associate Professor and Doctoral Supervisor at the School of Materials Science and Chemical Engineering, Harbin Engineering University. She holds a Doctorate in Engineering and has developed a robust academic profile in high-temperature materials and additive manufacturing. With over 60 peer-reviewed SCI-indexed publications and five invention patents, Dr. Zhang’s work significantly contributes to the field of advanced alloys and composite materials. She has successfully led numerous prestigious projects funded by the National Natural Science Foundation of China and other provincial and institutional bodies. As a guest editor for Metals and a senior member of the Chinese Society of Composite Materials, she plays an influential role in shaping research directions. Her ongoing projects involve cutting-edge research in nano-TiC reinforced molybdenum-based superalloys. Her leadership extends to military-grade materials research, and she currently spearheads a multi-million-yuan defense technology initiative with wide application potential in marine gas turbines.

Professional Profile :

Summary of Suitability for Award:

Dr. Hexin Zhang is an Associate Professor and Doctoral Supervisor at Harbin Engineering University. She holds a Doctorate in Engineering and has extensive expertise in high-temperature composite materials, superalloys, and additive manufacturing—fields of critical importance in advanced materials research.With over 60 SCI-indexed publications, 5 invention patents, and 2 authored monographs, Dr. Zhang has demonstrated consistent and significant contributions to materials science. Her work addresses both fundamental science and industrial application challenges, particularly in marine gas turbines.She serves as Guest Editor for the journal Metals, is a Senior Member of the Chinese Society for Composite Materials, and holds leadership roles in multiple national professional organizations.Dr. Hexin Zhang’s exceptional track record in high-impact research, leadership in national-level projects, patent portfolio, and editorial and professional service make her a standout candidate for the “Best Researcher Award.” Her contributions align well with the award’s objective of honoring researchers who exhibit innovation, leadership, and societal impact through their work.

🎓Education:

Dr. Hexin Zhang pursued her Doctorate in Engineering with a specialization in materials science, focusing on the mechanical behavior and processing of high-temperature alloys. Her academic training emphasized advanced manufacturing techniques including additive manufacturing (AM) and laser-based fabrication technologies. Her graduate work laid the foundation for exploring novel metal matrix composites and developing expertise in microstructural analysis, thermal stability, and mechanical performance enhancement under extreme conditions. She was trained in a multidisciplinary environment, combining theoretical materials science with practical engineering and thermodynamic modeling. As a part of her academic journey, she engaged in collaborative lab work, conference presentations, and published extensively in SCI-indexed journals, honing both technical skills and academic writing. Her formal education and consistent excellence have positioned her as a specialist in nickel-based and molybdenum-based superalloys, enabling her to tackle real-world challenges in aerospace and marine turbine applications.

🏢Work Experience:

Dr. Zhang currently serves as Associate Professor and Doctoral Supervisor at Harbin Engineering University. With extensive experience leading and contributing to key research projects, she has spearheaded over ten major scientific initiatives, including two funded by the National Natural Science Foundation of China and one basic research project targeting the processing of molybdenum-based materials. She has published over 60 high-impact SCI papers, secured 5 national patents, and authored 2 technical monographs. As the principal investigator of a military-focused project supported by the Central Military Commission, she managed a 2-million-yuan segment of a larger 7.5-million-yuan initiative. In addition to her research contributions, she serves as a guest editor for the journal Metals and has held important roles in several academic committees. Her hands-on expertise covers nano-reinforced materials, additive manufacturing, and failure analysis under thermo-mechanical fatigue.

🏅Awards:

Dr. Hexin Zhang has received multiple accolades for her contributions to materials science and engineering. She has been honored with competitive research grants from the National Natural Science Foundation of China, a testament to her innovative work in the field. She also serves in distinguished capacities including Senior Member of the Chinese Society of Composite Materials and Director of the Ecological Civilization Branch of the China Association of Higher Education. In recognition of her academic leadership and commitment to advancing materials research, she was appointed as a Member of the Materials Gene Engineering Expert Committee of the National Materials and Devices Scientists Think Tank. Additionally, her editorial role for Metals highlights her influence in peer-reviewed publishing. Her work in defense applications of high-temperature materials has further earned her distinction in government and institutional circles.

🔬Research Focus:

Dr. Zhang’s research focuses on the design, processing, and performance of nickel-based and molybdenum-based super alloys, especially for high-temperature and corrosive environments. She specializes in additive manufacturing techniques, particularly laser selective melting and nano-TiC reinforcement, to enhance mechanical strength and thermal resistance. Her investigations include thermo-mechanical fatigue, oxidation resistance, and hot corrosion mechanisms, crucial for the development of next-generation aerospace and marine turbine materials. A highlight of her work is the innovation in laser forming of Mo-based superalloys, solving issues like brittle fracture at room temperature. Her projects, including those funded by the Central Military Commission, involve cutting-edge structural materials aimed at military propulsion systems. Dr. Zhang also integrates computational modeling and experimental validation to understand microstructural evolution and failure modes under extreme conditions.

Publication Top Notes:

1. Impact of Secondary γ’ Precipitate on the High-Temperature Creep Properties of DD6 Alloy

2. Microstructural Evolution and Its Effect on Tensile Properties of 10Cr-2W-3Co Martensitic Steel During Thermal Exposure

3. Microstructure Evolution and Mechanical Properties of Ti-6Al-4V Alloy Fabricated by Directed Energy Deposition Assisted with Dual Ultrasonic Vibration

Citations: 2

4. Effect of Powder Particle Size on the Microscopic Morphology and Mechanical Properties of 316L Stainless Steel Hollow Spheres

5. Study on Hot-Compressive Deformation Behavior and Microstructure Evolution of 12Cr10Co3MoWVNbNB Martensitic Steel

6. Lattice Disorder Driving the Electron Migration from Tetracycline to TiO₂ via Ligand-to-Metal Charge Transfer to Generate Superoxide Radical

Citations: 2

7. Hydrangea-like MnO₂@Sulfur-Doped Porous Carbon Spheres with High Packing Density for High-Performance Supercapacitor

Citations: 1

8. La Doped-Fe₂(MoO₄)₃ with the Synergistic Effect Between Fe²⁺/Fe³⁺ Cycling and Oxygen Vacancies Enhances the Electrocatalytic Synthesizing NH₃

9. Influence of Aging Heat Treatment on Microstructure and Mechanical Properties of a Novel Polycrystalline Ni₃Al-Based Intermetallic Alloy

Citations: 1

Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

Posted on 26/04/202526/04/2025 by sciencefather

Dr. Siyao Chen | Materials Chemistry | Best Researcher Award

Dr. Siyao Chen , Materials Chemistry , Senior research assistant at City University of Hong Kong , Hong Kong

Dr. Siyao Chen is a Senior Research Assistant at the City University of Hong Kong, specializing in additive manufacturing and polymer-derived ceramics. With an impressive track record in advanced material research, Dr. Chen has published 11 SCI-indexed papers, including two ESI highly cited works, amassing over 610 citations. He serves as an invited editor for Frontiers in Electronics and actively contributes as a peer reviewer for prestigious journals such as Aerospace Science and Technology and the Journal of the European Ceramic Society. His research has made significant strides in 3D/4D ceramic printing, smart sensors, and semiconductor applications. In addition to academic achievements, Dr. Chen has worked on two major research projects, collaborated on four industry consultancies, and is listed as an inventor on three patents. A rising figure in materials science, Dr. Chen’s work integrates cutting-edge technology with real-world applications, contributing meaningfully to the development of intelligent ceramic systems.

Professional Profile :

Summary of Suitability for Award:

Dr. Chen has published 11 SCI-indexed papers, including 2 ESI highly cited works, demonstrating high-impact contributions. One of these papers has gathered over 610 citations, a remarkable achievement for an early-career researcher. His work in additive manufacturing, polymer-derived ceramics, and intelligent electronics is not only innovative but also addresses complex, high-tech engineering challenges. These fields are critical in both academic and industrial applications. He serves as an invited editor for Frontiers in Electronics and is a reviewer for top-tier journals like Aerospace Science and Technology and Journal of the European Ceramic Society, indicating recognition by peers in his domain. With 3 patents, 4 consultancy projects, and 2 ongoing research projects, Dr. Chen demonstrates both academic excellence and practical application, bridging the gap between theory and industry. Dr. Siyao Chen’s research excellence, demonstrated by high-impact publications, innovation through patents, editorial and peer-review contributions, and cross-disciplinary industrial collaborations, clearly qualify him as an exceptional candidate for the “Best Researcher Award.” His academic rigor and applied innovation mark him as a rising leader in materials science and engineering research.

🎓Education:

Dr. Siyao Chen earned his doctoral degree from City University of Hong Kong, where he laid the foundation for his expertise in additive manufacturing and ceramic. His academic training emphasized interdisciplinary knowledge at the intersection of materials engineering, mechanical design, and electronic systems. During his time at CityU, Dr. Chen developed critical skills in vat photopolymerization, polymer-derived ceramic processing, and microstructural design of smart ceramics. His graduate research focused on fabricating high-performance ceramic sensors and coatings using 3D/4D printing methods. Throughout his education, he was actively involved in publishing high-impact articles and contributing to collaborative research teams. His studies not only strengthened his theoretical foundation but also fostered practical lab experience, laying the groundwork for his continued academic and industrial research. The combination of rigorous education and hands-on innovation shaped Dr. Chen’s academic identity and enabled him to push boundaries in the field of intelligent ceramic-based electronics.

🏢Work Experience:

Dr. Siyao Chen currently works as a Senior Research Assistant at the City University of Hong Kong, where he leads multiple research efforts in the field of additive manufacturing and ceramic electronics. Over the years, he has contributed to both academic and industrial projects, participating in four consultancy collaborations and leading two significant research endeavors. He has also acted as a project coordinator for the development of smart ceramic sensors, coating systems, and semiconductor devices. His work includes guiding junior researchers, managing experimental workflows, and contributing to grant applications. Dr. Chen serves as a peer reviewer for several SCI-indexed journals and as an invited editor for Frontiers in Electronics, showcasing his academic authority. His multi-disciplinary experience, spanning ceramics, polymer chemistry, and semiconductor devices, equips him to work across diverse research environments. His consistent performance and hands-on innovation have made him a valuable member of the advanced materials research community.

🏅Awards:

Although early in his career, Dr. Siyao Chen has achieved notable recognition in his field. He is the recipient of multiple citations in high-impact journals, including two ESI Highly Cited Papers — a significant mark of influence and excellence in scholarly research. His publication in Materials Science and Engineering: R: Reports alone has gathered over 550 citations. Additionally, he was invited to join the editorial board of Frontiers in Electronics, a testament to his research integrity and subject matter expertise. His role as a reviewer for high-tier journals such as the Journal of the European Ceramic Society and Aerospace Science and Technology also highlights his academic credibility. Dr. Chen’s patent contributions and collaboration in industrial projects demonstrate the practical impact of his work. With a growing reputation in the materials science community, he is an emerging leader in ceramic additive manufacturing and intelligent electronics.

🔬Research Focus:

Dr. Chen’s primary research interests lie in additive manufacturing, polymer-derived ceramics, and semiconductor applications. He focuses on the design and processing of smart ceramic materials using 3D/4D printing technologies. His work bridges traditional ceramics with modern electronics, enabling innovations in reconfigurable structures, temperature sensors, and electromagnetic devices. A key area of interest is the development of lightweight, high-performance ceramics with tunable properties, particularly for sensing, actuation, and aerospace applications. His recent projects explore vat photopolymerization for SiCN and SiBCN-based ceramics, real-time material behavior modeling, and coating technologies for extreme environments. He is also involved in stimuli-responsive material systems, contributing to the advancement of intelligent electronics. His interdisciplinary research integrates materials engineering, electronic design, and digital fabrication, offering scalable and programmable material solutions for future smart systems. By combining structural innovation with electronic functionality, Dr. Chen aims to reshape how materials are conceived and manufactured.

Publication Top Notes:

Title: Additive manufacturing of structural materials
Citations: 572

Title: Lightweight and geometrically complex ceramics derived from 4D printed shape memory precursor with reconfigurability and programmability for sensing and actuation applications
Citations: 43

Title: Fabrication of polymer-derived SiBCN ceramic temperature sensor with excellent sensing performance
Citations: 17

Title: Fabrication of electrical semi-conductive SiCN ceramics by vat photopolymerization
Citations: 8

Title: 3D/4D additive–subtractive manufacturing of heterogeneous ceramics
Citations: 5

Title: Temperature and frequency dependent conductive behavior study on polymer-derived SiBCN ceramics
Citations: 3

Title: Novel anti-oxidation coating prepared by polymer-derived ceramic for harsh environments up to 1200°C
Citations: 2

Title: Real-time Bayesian model calibration method for C/SiC mechanical behavior considering model bias
Citations: 1

Title: Recent advances in stimuli-responsive materials for intelligent electronics

Title: Oxidation behavior of TiB2 from 600–1400°C considering microstructure evolution, oxidation kinetics, and mechanisms

Title: Evolution of dielectric properties of SiBCN ceramics and its derived wireless passive temperature sensor application

Dr. Hyun Jung Lee | Materials chemistry | Best Researcher Award

Posted on 15/04/202515/04/2025 by sciencefather

Dr. Hyun Jung Lee | Materials chemistry | Best Researcher Award

Dr. Hyun Jung Lee, Materials chemistry, Korea Institute of Fusion Energy, South Korea

Dr. Hyunjung Lee is a distinguished physicist and Principal Investigator at the Korea Institute of Fusion Energy (KFE) in Daejeon, South Korea. With a Ph.D. in Physics from Kyungpook National University, she has over two decades of research expertise in superconducting magnet systems, cryogenics, and fusion technology. She has made vital contributions to flagship projects like KSTAR, K-DEMO, and ITER, leading multi-million-dollar development efforts. A committed advocate for women in STEM, she represents Korea at international physics conferences and plays key roles in national scientific committees. Dr. Lee has authored over 60 peer-reviewed publications and continues to lead innovative research on high-field magnet design, quench analysis, and thermo-hydraulics. Her contributions significantly advance global nuclear fusion efforts, showcasing both technical excellence and visionary leadership.

Professional Profile :

Summary of Suitability for Award:

Dr. Hyunjung Lee is a highly accomplished researcher with a robust and diverse academic and professional background in fusion energy and superconductivity. She has extensive experience in superconducting magnet systems and cryogenic technologies, leading significant projects like the development of superconducting magnets for the K-DEMO and KSTAR fusion reactors. As a principal investigator at the Korea Institute of Fusion Energy (KFE), her work involves cutting-edge research in fusion physics, including the design, analysis, and operational stability of superconducting magnets. Dr. Hyunjung Lee is undoubtedly a suitable candidate for the “Best Researcher Award”, due to her impactful research, leadership in large-scale international projects, and her contributions to the advancement of fusion energy technology. Her innovative work in superconducting magnet systems has advanced both scientific understanding and practical applications in fusion energy, making her an outstanding candidate for this prestigious award.

🎓Education:

Dr. Hyunjung Lee completed her Ph.D. in Physics at Kyungpook National University, Daegu, South Korea, in 2003. Her doctoral research focused on the behavior of materials in extreme magnetic fields and low temperatures, setting the stage for her future work in superconducting systems. Prior to that, she earned her B.S. in Physics from Daegu University in 1997. Her strong academic foundation enabled her to transition seamlessly into high-level research, with early postdoctoral training at the Korea Basic Science Institute (KBSI). Dr. Lee’s educational background reflects a deep commitment to fundamental physics, with an application-driven focus on fusion energy systems and superconducting technologies. Her continuous engagement with advanced analytical and cryogenic systems throughout her education laid the groundwork for her leadership in magnet design and thermo-hydraulic simulation for nuclear fusion applications.

🏢Work Experience:

Dr. Lee began her career as a Postdoctoral Associate (2003–2006) at the Korea Basic Science Institute (KBSI), where she researched material properties under extreme conditions. She then joined the Korea Institute of Fusion Energy (KFE) in 2006, advancing from Senior Researcher to Principal Investigator. From 2006–2013, she focused on thermo-hydraulic and quench analysis for KSTAR and K-DEMO superconducting magnets. Between 2013–2015, she contributed to cryogenic system design for the RAON project. From 2016–2018, she also served as an Associate Professor at the University of Science and Technology (UST), teaching accelerator and fusion physics. Her key achievements include designing 16T superconducting magnets, establishing experimental facilities (~$30 million), and collaborating with global fusion initiatives such as ITER, ENEA, and General Atomics. She is currently a leading figure in Korea’s national fusion reactor (K-DEMO) magnet program and a central voice in international fusion technology forums.

🏅Awards:

While Dr. Hyunjung Lee’s CV does not list specific named awards, her achievements are reflected through her prestigious roles, international collaborations, and scientific committee appointments. She serves as an Executive Officer in the Korean Physical Society’s Academic and Women’s Committees (2021–present), showcasing her leadership in Korea’s physics community. She has been a Mentoring Fellow of the Korea Foundation for Women in Science and Technology (2008–2020), guiding the next generation of scientists. Her appointment to the Peaceful Unification Advisory Council (2015–2017) reflects national recognition beyond science. Dr. Lee frequently represents Korea in international conferences, including the International Conference on Women in Physics and the Magnet Technology Conference, evidencing her global stature. Her research is highly regarded in fusion communities and continues to influence policies and project planning at the international level. Her awards lie in the transformative impact of her research and leadership across nuclear fusion initiatives.

🔬Research Focus:

Dr. Hyunjung Lee’s research is centered on superconducting magnet systems and cryogenic thermo-hydraulics for nuclear fusion reactors. Her core contributions span magnet design, quench analysis, and the establishment of fusion magnet experimental infrastructure. A key architect of Korea’s K-DEMO and KSTAR fusion magnet programs, she focuses on developing high-field (up to 16T) superconducting magnets and advanced quench protection mechanisms. Her work includes detailed thermo-hydraulic modeling, AC loss analysis, and cooling loop simulations to ensure cryogenic stability. She also leads international collaboration on magnet technologies with partners like ITER, ENEA, and General Atomics. Dr. Lee has also contributed to the RAON rare isotope accelerator project, analyzing cryogenic systems for linear accelerators. Her research directly advances fusion energy’s feasibility, offering safe, efficient, and scalable superconducting systems for future reactors. She is a thought leader in fusion technology development, particularly in enabling long-term stability of superconducting devices under high-stress operations.

Publication Top Notes:

Design Updates of a Fusion Superconducting Conductor Test Facility Magnet (SUCCEX)

Assessment of KSTAR Nb₃Sn Superconducting Magnet Property After Long-Term Operation Since 2008

Effect of Flow Imbalance on the Operational Performance of the KSTAR PF1UL Magnets

Design Updates and Thermo-Hydraulic Analysis of K-DEMO CS Magnets

Thermo-Hydraulic Analysis of the KSTAR PF Cryogenic Loop Using SUPERMAGNET Code

Citations: 1

Dr. Chenxu Wang | Electrochemistry | Green Chemistry Award

Posted on 07/04/202507/04/2025 by sciencefather

Dr. Chenxu Wang | Electrochemistry | Green Chemistry Award

Dr. Chenxu Wang , Electrochemistry ,Research associate at University of Texas at Dallas, United States

Dr. Chenxu Wang is a dynamic and innovative Research Associate at the BEACONS Center, University of Texas at Dallas. With a solid foundation in electrochemical energy storage, he completed his Ph.D. in 2023 from Washington State University under the mentorship of Dr. Weihong Zhong. Since 2016, he has consistently contributed to the field of battery technology, focusing on lithium-ion, lithium-metal, and sodium-ion systems. His research incorporates cutting-edge innovations such as protein-based solid-state materials for enhanced battery safety and performance. Alongside academic excellence, Dr. Wang brings hands-on experience from the battery manufacturing industry, enriching his practical insights. He has published over 18 scientific papers and is the lead author of a technical book. He actively engages with the scientific community through editorial roles and collaborations. Dr. Wang is dedicated to advancing green, safe, and high-performance battery technologies for a sustainable energy future.

Professional Profile :

Summary of Suitability for Award:

Dr. Chenxu Wang is an exceptional candidate for the Green Chemistry Award due to his innovative integration of biological and natural materials—particularly silk fibroin proteins—into the design of advanced battery components. His work directly aligns with the principles of green chemistry. Dr. Wang has demonstrated that green materials can match or surpass traditional materials in performance. His contributions include the development of protein-based solid electrolytes, eco-friendly binders, and non-toxic separators, which not only advance battery safety and efficiency but also minimize environmental impact. Dr. Chenxu Wang’s pioneering work in applying natural biomolecules to battery technology presents a paradigm shift toward eco-conscious energy storage solutions. His holistic approach—spanning green material synthesis, automation, and recycling—makes him an ideal recipient of the “Green Chemistry Award”. His research not only addresses key environmental challenges but also offers scalable solutions for the clean energy transition.

🎓Education:

Dr. Chenxu Wang earned his Ph.D. in Materials Science and Engineering from Washington State University (WSU) in 2023, where he conducted advanced battery research under Dr. Weihong Zhong. His doctoral work focused on sustainable energy storage systems, particularly lithium-metal and lithium-sulfur batteries. During his time at WSU, he received prestigious awards recognizing both academic excellence and research contributions. Prior to his Ph.D., Dr. Wang obtained his undergraduate and possibly a master’s degree (details unspecified) in fields related to chemistry or materials science, laying the groundwork for his later specialization in electrochemical systems. His academic training has been marked by a strong emphasis on interdisciplinary problem-solving, including materials synthesis, electrochemical characterization, and green chemistry applications. Throughout his education, Dr. Wang developed a strong technical foundation and research mindset that continue to fuel his contributions to battery innovation and electrochemical energy storage.

🏢Work Experience:

Dr. Chenxu Wang is currently serving as a Research Associate at the BEACONS Center, University of Texas at Dallas, where he contributes to groundbreaking projects in next-generation battery technologies. Since 2016, he has worked extensively on battery research, accumulating a unique blend of academic and industrial experience. He previously worked in the battery manufacturing industry, where he gained hands-on experience in the development and scaling of energy storage materials and systems. During his Ph.D. at WSU, he managed several interdisciplinary research projects on solid-state electrolytes and sustainable battery materials. Dr. Wang is involved in both laboratory experimentation and theoretical modeling. In addition to his research roles, he is active in the scientific publishing ecosystem, serving on the Youth Editorial Board of Exploration and as a Guest Editor for Batteries. His contributions span project leadership, material innovation, and research communication within the energy storage field.

🏅Awards:

Dr. Chenxu Wang has been recognized with multiple prestigious awards that highlight his exceptional academic and research performance. In 2023, he received the Outstanding Dissertation Award and the Outstanding Research Assistant Award from Washington State University, acknowledging the novelty and impact of his Ph.D. work in the field of electrochemical energy storage. These accolades are a testament to his contributions toward addressing real-world energy challenges through scientific innovation. Dr. Wang’s leadership and editorial responsibilities also reflect his growing recognition in the global research community. He currently serves as a Guest Editor for the journal Batteries and is a Youth Editorial Board Member for the journal Exploration. His research excellence and dedication to sustainable energy have also led to collaborative opportunities and growing citations (over 253 citations) across reputable journals. These honors reflect Dr. Wang’s commitment to advancing green chemistry and sustainable battery technology.

🔬Research Focus:

Dr. Chenxu Wang’s research is centered on electrochemical energy storage systems, with a strong emphasis on green chemistry, sustainability, and advanced battery materials. His innovative work involves integrating natural proteins such as silk fibroin into solid-state battery components, which significantly improve safety, ionic conductivity, and performance. He has developed protein-based solid electrolytes, binders, and separators, targeting the challenges of dendrite formation and the polysulfide shuttle effect in lithium-metal and lithium-sulfur batteries. His research also explores automated synthesis, material characterization, and battery recycling, aiming to create scalable, eco-friendly solutions for energy storage. Dr. Wang’s unique blend of academic research and industry exposure allows him to bridge theory and practice, contributing meaningfully to real-world battery innovations. His projects on high-energy-density lithium/sodium-ion batteries and advanced liquid electrolytes further reflect his comprehensive approach to solving multi-faceted challenges in next-generation energy storage.

Publication Top Notes:

A water-soluble binary conductive binder for Si anode lithium ion battery
Citations: 57

Natural protein as novel additive of a commercial electrolyte for Long-Cycling lithium metal batteries
Citations: 30

Protein-modified SEI formation and evolution in Li metal batteries
Citations: 29

A protein-enabled protective film with functions of self-adapting and anion-anchoring for stabilizing lithium-metal batteries
Citations: 26

Synthesis of β-FeOOH nanorods adhered to pine-biomass carbon as a low-cost anode material for Li-ion batteries
Citations: 20

A bioinspired coating for stabilizing Li metal batteries
Citations: 18

Promising sustainable technology for energy storage devices: Natural protein-derived active materials
Citations: 15

Incorporating SnO2 nanodots into wood flour-derived hierarchically porous carbon as low-cost anodes for superior lithium storage
Citations: 12

Interface-tailored forces fluffing protein fiber membranes for high-performance filtration
Citations: 10

Highly dispersed SnO2 nanoparticles confined on xylem fiber-derived carbon frameworks as anodes for lithium-ion batteries
Citations: 7

An amino acid-enabled separator for effective stabilization of Li anodes
Citations: 6

Effects of Anions and Protein Structures on Protein‐Based Solid Electrolytes
Citations: 6

Dr. Imran Aslam | Materials Chemistry | Best Researcher Award

Posted on 27/03/2025 by sciencefather

Dr. Imran Aslam | Materials Chemistry | Best Researcher Award

Dr. Imran Aslam | Materials Chemistry | Associate Professor at Department of Physics, GC Women University Sialkot , Pakistan

Dr. Imran Aslam is an Associate Professor (BPS-20) at the Department of Physics, GC Women University, Sialkot, Pakistan. With over 15 years of teaching and research experience, he has authored 60+ research articles in international peer-reviewed journals, accumulating 3250 citations, an H-index of 27, and an i10-index of 47. His research specializes in nano- heterostructured materials for energy storage, environmental applications, and density functional theory (DFT). He serves as a reviewer for prestigious journals like Scientific Reports (Nature), Journal of Crystal Growth, and Chemosphere. As an HEC-approved PhD supervisor, he has supervised 11 MS students and 4 PhD candidates. He has also been a keynote speaker at multiple international conferences. His contributions to academia have earned him accolades such as the CAS President’s International Fellowship (2016) and the Quaid-e-Azam Gold Medal Award (2020).

Professional Profile :

Summary of Suitability for Award:

Dr. Imran Aslam, an Associate Professor at GC Women University Sialkot, is a distinguished researcher in the field of nanomaterials and energy storage. With over 15 years of research and teaching experience, he has authored/co-authored more than 60 research articles in high-impact international journals, accumulating a total impact factor of 300 and over 3,250 citations (H-index: 27, i10-index: 47). His extensive research contributions span the synthesis and characterization of micro/nano heterostructured materials, photocatalysis, supercapacitors, and density functional theory (DFT). Additionally, he serves as a reviewer for multiple reputed journals and is an HEC-approved Ph.D. supervisor. His role as an invited speaker at international conferences further highlights his expertise. Dr. Imran Aslam’s significant contributions to material science, coupled with his prolific publication record, high citation impact, and leadership in research supervision, make him an outstanding candidate for the “Best Researcher Award.” His dedication to advancing nanotechnology and sustainable energy solutions further strengthens his suitability for this prestigious recognition.

🎓Education:

Dr. Imran Aslam holds a Postdoctoral Fellowship (2017) from the National Centre for Nanoscience and Technology (NCNST), Chinese Academy of Sciences. He earned his PhD (2015) from the Beijing Institute of Technology, China, as a recipient of the CSC Scholarship (2011-2015). His M.Phil. (2010) degree is from GC University, Lahore, Pakistan, where he was awarded the M.Phil. Fellowship at Salam Chair in Physics. Prior to that, he completed his M.Sc. (2008) in Physics from the University of the Punjab, Lahore. His academic achievements also include the Distinguished Student Award (2013/2014) at Beijing Institute of Technology, China. Throughout his education, Dr. Aslam has demonstrated a strong focus on nanotechnology, energy storage, photocatalysis, and computational material science, laying the foundation for his extensive research career.

🏢Work Experience:

Dr. Imran Aslam has an extensive 15-year career in academia and research. Currently, he is an Associate Professor at GC Women University, Sialkot. He has previously served as Resident Officer (2020-2023), Convener of the Mess Committee (2021-2023), Technical Evaluation Committee (2020-2023), and Events Management Committee (2022-2023) at UET Lahore, Narowal Campus. Additionally, he was MPhil Coordinator and Exam Superintendent (2015-2016) at the University of Gujrat. His contributions extend to exam coordination, admissions, and scholarship programs at GCWUS. He is an external examiner for MS/PhD theses at multiple universities, including University of Gujrat, Riphah International University, and The University of Chenab. As a co-PI of an HEC-funded project worth 9.4 million rupees, his expertise also spans research administration. Dr. Aslam actively reviews manuscripts for top-tier journals, ensuring quality contributions to the scientific community.

🏅Awards:

Dr. Imran Aslam has received numerous national and international accolades in recognition of his academic and research contributions. In 2020, he was awarded the Quaid-e-Azam Gold Medal by Istehkam-e-Pakistan Foundation. His international recognition includes the CAS President’s International Fellowship Initiative (PIFI) 2016 for postdoctoral studies at the Chinese Academy of Sciences. As a PhD scholar at Beijing Institute of Technology, he was honored with the Distinguished Student Award (2013/2014) and the CSC Scholarship (2011-2015). During his M.Phil. at GC University, Lahore, he secured a fellowship at Salam Chair in Physics. His consistent excellence in research and leadership in various academic roles has further solidified his reputation as a distinguished scientist in materials science, photocatalysis, and nanotechnology.

🔬Research Focus:

Dr. Imran Aslam’s research is centered on the synthesis and characterization of micro/nano heterostructured materials using cost-effective methods. His work explores optical, photoluminescence, and energy storage properties with applications in supercapacitors and lithium-ion batteries. Additionally, his expertise extends to photocurrent response, incident photo-to-current conversion efficiency (IPCE), and photocatalytic hydrogen production via water-splitting. His environmental research involves photo-degradation processes for pollutant removal. He also conducts computational studies using Density Functional Theory (DFT) to predict and optimize material properties for various energy applications. His contributions have significantly advanced material science, nanotechnology, and environmental sustainability. His findings are published in high-impact journals, and he collaborates internationally to push the frontiers of nano-engineered materials.

Publication Top Notes:

Multifunctional g-C₃N₄ Nanofibers: A Template-Free Fabrication and Enhanced Optical, Electrochemical, and Photocatalyst Properties

Citations: 412

Tubular graphitic-C₃N₄: A Prospective Material for Energy Storage and Green Photocatalysis

Citations: 275

High-Valence-State NiO/Co₃O₄ Nanoparticles on Nitrogen-Doped Carbon for Oxygen Evolution at Low Overpotential

Citations: 239

Synthesis of Novel ZnV₂O₄ Hierarchical Nanospheres and Their Applications as Electrochemical Supercapacitor and Hydrogen Storage Material

Citations: 183

Template-Free Synthesis of CuS Nanosheet-Based Hierarchical Microspheres: An Efficient Natural Light Driven Photocatalyst

Citations: 174

Green Synthesis of TiO₂ Nanoparticles Using Lemon Peel Extract: Their Optical and Photocatalytic Properties

Citations: 147

Bifunctional Catalysts of Co₃O₄@GCN Tubular Nanostructured (TNS) Hybrids for Oxygen and Hydrogen Evolution Reactions

Citations: 143

Large-Scale Production of Novel g-C₃N₄ Microstrings with High Surface Area and Versatile Photodegradation Ability

Citations: 129

A Novel Z-Scheme WO₃/CdWO₄ Photocatalyst with Enhanced Visible-Light Photocatalytic Activity for the Degradation of Organic Pollutants

Citations: 128

One-Dimensional Graphitic Carbon Nitrides as Effective Metal-Free Oxygen Reduction Catalysts

Citations: 101

The Synergistic Effect Between WO₃ and g-C₃N₄ Towards Efficient Visible-Light-Driven Photocatalytic Performance

Citations: 95

Assoc. Prof. Dr. Mohamed Ebrahim | Materials Chemistry | Best Researcher Award

Posted on 07/03/2025 by sciencefather

Assoc. Prof. Dr. Mohamed Ebrahim | Materials Chemistry | Best Researcher Award

Assoc. Prof. Dr. Mohamed Ebrahim | Materials Chemistry |Solid State Physics research at National Research Center, Egypt

M. R. Ebrahim, born in Giza, Egypt, is a distinguished researcher in solid-state physics at the National Research Centre (NRC), Egypt. He obtained his Ph.D. in Experimental Physics from Mansoura University, specializing in the synthesis and preparation of Al/Ru bi-layers. His expertise lies in severe plastic deformation (SPD) and surface mechanical alloying (SMA) of aluminum. He has significantly contributed to materials science with innovations such as Surface Mechanical Attrition Treatment (SMAT), for which he holds a patent. His research has advanced aluminum composites, corrosion resistance, and electrochemical behavior, leading to applications in supercapacitors, coatings, and energy storage devices. He has authored numerous publications in high-impact journals and collaborates internationally in materials engineering. His work integrates theoretical physics with experimental applications, contributing significantly to nanomaterials, electrochemistry, and advanced materials.

Professional Profile :

Scope

Summary of Suitability for Award:

M. R. Ebrahim is a highly accomplished researcher specializing in solid-state physics, severe plastic deformation (SPD), and surface mechanical alloying (SMA). His groundbreaking innovations, such as Surface Mechanical Attrition Treatment (SMAT), have significantly advanced materials science, particularly in supercapacitor development, corrosion resistance, and electrochemical behavior. His patents, numerous high-impact publications, and contributions to industrial and academic research demonstrate his expertise and leadership in his field. He has successfully bridged the gap between theoretical physics and applied materials engineering, leading to practical advancements in nanomaterials and surface engineering. His active involvement in research collaborations, peer reviewing, and international conferences further strengthens his candidacy for this prestigious award. M. R. Ebrahim’s research excellence, technological innovations, and impactful contributions to materials science make him a highly deserving candidate for the “Best Researcher Award.” His patents, publications, and pioneering work in surface engineering and electrochemistry showcase his ability to drive scientific progress and innovation. Recognizing his achievements would honor his dedication to advancing materials science and inspire further groundbreaking research in the field.

🎓Education:

M. R. Ebrahim pursued his academic journey in physics, starting with a B.Sc. in Physics from Helwan University, Egypt. He furthered his studies with a Ph.D. in Experimental Physics from Mansoura University, focusing on synthesis and preparation of Al/Ru bi-layers. His doctoral research emphasized surface modifications, mechanical alloying, and electrochemical properties of aluminum-based materials. His educational background laid a strong foundation for his work in severe plastic deformation (SPD), surface engineering, and supercapacitor technology. His studies encompassed various aspects of solid-state physics, nanomaterials, and electrochemical behavior. With extensive laboratory experience, he gained expertise in materials characterization, thin-film coatings, and corrosion-resistant materials. His education has driven his innovations in advanced materials processing, mechanical attrition, and novel composite development, enabling him to make significant contributions to materials science and industrial applications.

🏢Work Experience:

M. R. Ebrahim has been a Researcher in Solid-State Physics at NRC, Egypt, since 2010, working extensively on surface mechanical alloying, corrosion resistance, and severe plastic deformation of aluminum-based materials. His research focuses on enhancing the mechanical, electrical, and electrochemical properties of metals for various applications. He pioneered SMAT technology for material surface modifications, significantly improving supercapacitor performance, dielectric properties, and composite coatings. His collaborations extend internationally, engaging in projects related to nano-coatings, energy storage, and metal reinforcement techniques. He has contributed to industrial advancements by integrating electrochemical engineering with material science, leading to innovative solutions for corrosion-resistant and high-performance aluminum materials. He actively publishes, reviews scientific papers, and participates in global conferences, sharing his expertise in materials modification, nanostructured composites, and energy applications. His work bridges the gap between fundamental physics and practical material applications, driving progress in advanced alloy engineering.

🏅Awards:

M. R. Ebrahim has received several prestigious recognitions for his outstanding contributions to solid-state physics, surface mechanical alloying, and severe plastic deformation. He has been acknowledged for his innovative patents, including the “Machine for Surface Mechanical Attrition Treatment (SMAT)” and “Supercapacitors Construction from Fiberglass through Surface Mechanical Alloying.” These innovations were recognized by the Egyptian Scientific Research Academy, highlighting their significance in advancing materials science and energy storage technologies. His research excellence has also earned him invitations to international conferences, peer-reviewing roles in high-impact journals, and collaborations with leading institutions. His contributions to corrosion resistance, electrochemical behavior, and composite materials have been widely cited, further solidifying his reputation as a leading researcher in his field. His dedication to applied physics and engineering continues to influence modern materials science, making him a strong contender for prestigious scientific awards and fellowships.

🔬Research Focus:

M. R. Ebrahim’s research is centered on solid-state physics, surface engineering, and severe plastic deformation (SPD) to enhance material properties. His work on surface mechanical alloying (SMA) and surface mechanical attrition treatment (SMAT) has led to significant advancements in corrosion resistance, mechanical strength, and electrical properties of aluminum-based materials. A key aspect of his research is the development of supercapacitors using fiberglass and aluminum composites, which has implications for energy storage and electronic applications. His studies also explore electrochemical behavior, dielectric permittivity, and microstructural evolution in materials subjected to mechanical treatments. By integrating experimental physics with material science, he has successfully introduced innovative methodologies to modify and enhance material surfaces for industrial and technological applications. His contributions are particularly impactful in nanomaterials, thin films, and composite materials, where his work continues to drive new advancements in materials engineering and applied physics.

Publication Top Notes:

“Electrical properties of Al-Si surface composites through surface mechanical alloying on severe plastic deformed Al substrates”
“Mechanical treatment of aluminum plate surfaces for improvements of capacitance and dielectric permittivity”
“Corrosion behavior of aluminum-Fiber Glass composite fabricated through surface mechanical alloying in alkaline media”
“Electrochemical behavior of Al₂O₃/Al composite coated Al electrodes through surface mechanical alloying in alkaline media”
“Terahertz acoustic phonon detection from a compact surface layer of spherical nanoparticles powder mixture of aluminum, alumina and multi-walled carbon nanotube”
“Improving corrosion resistance of Al through severe plastic deformation 1-under free condition”
“Improving corrosion resistance of Al through severe plastic deformation 2-under accelerated condition”
“Spectroscopic Analysis of Severe Plastically Deformed Raw Al Rolled Sheet”
“Microstructure and Microhardness Evolutions of High Fe Containing Near-Eutectic Al-Si Rapidly Solidified Alloy”
“Microstructure and microhardness evolution of melt-spun Al-Si-Cu alloy”
“Study of Phase Evolution in Sputtered Al/Ru Bi-layers Nanocrystalline Thin Films”

Assist. Prof. Dr. Arman Zarebidaki | Materials Chemistry | Best Researcher Award

Posted on 05/03/202505/03/2025 by sciencefather

Assist. Prof. Dr. Arman Zarebidaki | Materials Chemistry | Best Researcher Award

Assist. Prof. Dr. Arman Zarebidaki | Materials Chemistry | Assistant professor at Amirkabir University of Technology , Iran

Dr. Arman Zarebidaki is an Assistant Professor and Head of the Corrosion Engineering and Material Protection Group at Amirkabir University of Technology (Tehran Polytechnic), Bandarabbas Campus, Iran. With a strong background in materials engineering, electrochemistry, and surface engineering, his research focuses on advanced coatings for corrosion protection, hydrogen evolution, and oxygen evolution reactions. He has extensive experience in electrochemical techniques such as polarization methods, voltammetry, and impedance spectroscopy. Dr. Zarebidaki has supervised over 25 master’s theses and has authored multiple high-impact journal articles. He holds three national patents in corrosion prevention and is recognized for his contributions to sustainable energy technologies and industrial material protection.

Professional Profile :

Summary of Suitability for Award:

Dr. Arman Zarebidaki is a highly accomplished researcher in materials science, electrochemistry, and surface engineering, making him an exceptional candidate for the “Best Researcher Award”. His research spans crucial areas such as corrosion protection, electrocatalysis, and advanced coating technologies, which have significant industrial and environmental applications. His high-impact publications, extensive teaching experience, and contributions to innovative material protection methods demonstrate his leadership in the field. He has also secured three national patents, reflecting his ability to translate research into practical solutions. Recognized as the Top Researcher in Hormozgan Province (2023) and a Distinguished Researcher at Azad University (2015), his accolades further establish his excellence in scientific innovation. Dr. Zarebidaki’s outstanding research in corrosion-resistant coatings, electrochemical energy applications, and material durability makes him a strong contender for the “Best Researcher Award”. His work not only advances scientific knowledge but also has direct implications for industry and sustainability, positioning him among the top researchers in his field.

🎓Education:

Dr. Arman Zarebidaki holds a Ph.D. in Metallurgical & Materials Engineering from the University of Tehran (2006–2012), where he investigated the tribo-corrosion behavior of Ni-P electroless coatings with SiC nanoparticles and carbon nanotubes. His doctoral research resulted in multiple high-impact publications. Prior to that, he earned an M.S. in Metallurgical & Materials Engineering from the University of Tehran (2003–2006), focusing on optimizing and characterizing Al/Gr composites produced by in-situ powder metallurgy. His master’s research led to a Q2-ranked ISI publication. He completed his B.S. in Materials Engineering-Industrial Metallurgy at Azad University, Yazd Branch (1998–2003), where he studied surface hardening of cast iron using the TIG process. Throughout his academic journey, he maintained outstanding GPAs and received multiple accolades for his research excellence. His extensive educational background laid the foundation for his expertise in materials engineering, corrosion protection, and advanced electrochemical methods.

🏢Work Experience:

Dr. Arman Zarebidaki is an Assistant Professor at Amirkabir University of Technology, where he has been leading the Corrosion Engineering and Material Protection Group since 2023. He has been actively involved in teaching courses such as oxidation and hot corrosion, corrosion inhibitors, and advanced electrochemistry laboratory techniques. Prior to this, he served as an Assistant Professor at Azad University, Yazd Branch (2008–2014), where he taught advanced electrochemistry, cathodic & anodic protection, and corrosion science. With over 25 master’s theses supervised, he has contributed significantly to the field of corrosion and electrocatalysis . His expertise includes deposition techniques for coatings and nanocomposite materials, corrosion assessments, and electrochemical analysis. He is proficient in methods such as cyclic voltammetry, linear sweep voltammetry, and electrochemical impedance spectroscopy. His research extends to nanotube production via anodizing, corrosion inhibition using green inhibitors, and the development of protective coatings for industrial applications.

🏅Awards:

Dr. Arman Zarebidaki has received several prestigious awards throughout his career. In 2023, he was recognized as the Top Researcher in technical and engineering fields in Hormozgan province. He was also named a Distinguished Researcher by the Deputy of Education and Technology at Islamic Azad University, Yazd Branch, in 2015. His exceptional teaching abilities earned him the Exemplary Professor Award in 2014. Additionally, his Ph.D. thesis was awarded as a Superior Dissertation at the University of Tehran in 2012. As an M.Sc. student, he ranked 1st among 50 peers in the Department of Material Science and Engineering. His contributions to the field of corrosion prevention and control are further highlighted by three national patents, including innovations in self-healing epoxy coatings, corrosion-fatigue assessment apparatus, and electroless coatings for oil and gas steel equipment, demonstrating his commitment to advancing materials engineering and corrosion protection technologies.

🔬Research Focus:

Dr. Arman Zarebidaki’s research centers on materials engineering, electrochemistry, and surface engineering, with a strong emphasis on developing advanced coatings to enhance material durability and performance. His work involves designing metallic, composite, and nanocomposite coatings for industrial applications, particularly for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), aiming to improve the efficiency of electrolysis in hydrogen and oxygen production. He specializes in electrochemical characterization techniques, including polarization methods, linear sweep voltammetry, cyclic polarization, and electrochemical impedance spectroscopy (EIS), to analyze corrosion resistance and material degradation. Additionally, he investigates electrocatalysis mechanisms and surface chemistry to develop sustainable energy solutions. His expertise extends to nanotube production through anodizing, corrosion inhibitors, and smart coatings. His contributions help address global challenges related to energy sustainability, environmental protection, and climate change, making his research pivotal in the advancement of corrosion-resistant and energy-efficient materials.

Publication Top Notes:

Influence of graphite content on the dry sliding and oil impregnated sliding wear behavior of Al 2024–graphite composites produced by in situ powder metallurgy method

Citations: 396

An investigation on effects of heat treatment on corrosion properties of Ni–P electroless nano-coatings

Citations: 166

Effect of surfactant on the fabrication and characterization of Ni-P-CNT composite coatings

Citations: 104

Characterization and corrosion behavior of electroless Ni–P/nano-SiC coating inside the CO2 containing media in the presence of acetic acid

Citations: 96

The effect of sliding speed and amount of loading on friction and wear behavior of Cu–0.65 wt.% Cr alloy

Citations: 47

Microstructure and corrosion behavior of electrodeposited nano-crystalline nickel coating on AZ91 Mg alloy

Citations: 46

Evaluation of corrosion inhibition of mild steel in 3.5 wt% NaCl solution by cerium nitrate

Citations: 43

Electrodeposition and characterization of Co–BN (h) nanocomposite coatings

Citations: 42

An experimental study on stress corrosion behavior of A131/A and A131/AH32 low carbon steels in simulated seawater

Citations: 28

Porosity measurement of electroless Ni–P coatings reinforced by CNT or SiC particles

Citations: 28

Dr. Kàshinath Lellala | Materials Chemistry | Best Researcher Award

Posted on 26/02/202526/02/2025 by sciencefather

Dr. Kàshinath Lellala | Materials Chemistry | Best Researcher Award

Dr. Kàshinath Lellala , Materials Chemistry , University of Mysore , India

Dr. Kashinath Lellala is an accomplished materials scientist with expertise in advanced functional materials for energy and environmental applications. With over 12 years of research experience and 10 years of teaching, he has made significant contributions to materials fabrication, catalysis, and battery technology. His research spans heterojunction materials, electrocatalysts, and Li-ion battery components. Dr. Lellala has held postdoctoral positions at esteemed institutions such as Xavier University (USA), Luleå University of Technology (Sweden), and Pandit Deendayal Petroleum University (India). He has also served as a lecturer at Xavier University, JSS University, and Royal University of Bhutan. His interdisciplinary approach integrates computational studies with experimental research, enhancing his contributions to materials science. He actively collaborates with global researchers and has served on editorial boards of reputed journals. His work has been recognized through multiple awards, including the Eminent Educator Award and prestigious fellowships.

Professional Profile :

Summary of Suitability for Award:

Dr. Kashinath Lellala is exceptionally qualified for “Best Researcher Awards” due to his extensive and diverse contributions to materials science and engineering. With over 12 years of research experience and 10 years of teaching, his work spans advanced functional materials, photocatalysis, and lithium-ion battery technology. His innovative approaches in synthesizing heterojunction materials, semiconductor-supported catalysts, and graphene-based nanomaterials have significantly advanced the fields of energy and environmental applications. His global research stints—at institutions such as Xavier University, Luleå University of Technology, and Pandit Deendayal Petroleum University—underscore his ability to collaborate across borders and disciplines. Additionally, his editorial board roles, numerous publications, and prestigious awards, including the Caryl Trigger Research Fellowship and Eminent Educator Award, reflect both his academic rigor and leadership.

🎓Education:

Dr. Kashinath Lellala earned his Ph.D. in Materials Science from the University of Mysore, India, in 2019, under the guidance of Prof. K. Byrappa, focusing on hybrid metal oxide/metal sulfide-graphene oxide nanocomposites for energy and environmental applications. He completed his M.Phil. in Physics (Thin Films and Nanotechnology) from Alagappa University, India, in 2013, where he synthesized and characterized single-layered graphene via chemical exfoliation. His M.Sc. in Physics, with a specialization in electronics, was awarded by Kakatiya University, Warangal, Telangana, India, in 2007. Additionally, he holds a Diploma in Embedded Technology from Kionia Software Institution, Pune University, and a Postgraduate Diploma in Computer Applications (PGDCA) from Andhra Pradesh Electronics Limited (APEL). His academic background is complemented by a Certificate in Typing (English Lower Grade), reflecting his diverse skill set in computational work and experimental physics.

🏢Work Experience:

Dr. Lellala has 12 years of research and 10 years of teaching experience across prestigious institutions worldwide. He served as a Postdoctoral Fellow & Lecturer at Xavier University of Louisiana (2022–2023), working on semiconductor and heterojunction materials for batteries, 3D bio-inkjet printing, and fuel cells. At Lulea University of Technology, Sweden (2020–2022), he contributed to water remediation research through semiconductor-supported photocatalysis. Earlier, he was a Research Associate at Pandit Deendayal Petroleum University (2019–2020), focusing on silicon nanoparticle-based anode materials for lithium-ion batteries. His Ph.D. research (2014–2019) at the University of Mysore involved fabricating hybrid metal oxide/sulfide-graphene oxide nanocomposites for energy applications. Additionally, he has held teaching positions at JSS University, Bhutan Royal University, Iringa University (Tanzania), and New Science PG College, delivering lectures on physics, materials science, and nanotechnology.

🏅Awards:

Dr. Kashinath Lellala has received multiple prestigious awards in recognition of his contributions to materials science and engineering. He was awarded the Caryl Trigger Research Foundation Postdoctoral Fellowship at Lulea University of Technology in 2020. He also received the Eminet Educator Award-2020 from the Forum of Interdisciplinary Research in Mathematical Sciences (FIRMS), India. His research excellence was recognized with a Certificate of Appreciation for Reviewing by Elsevier’s Journal of Cleaner Production (2021). Additionally, he was a Postdoctoral Fellow at the Department of Science & Technology, India (2019), and an International Visiting Research Student at the University of South Australia (2017). His research potential was acknowledged with the Senior Research Fellowship (SRF) at the University of Mysore (2017) and Junior Research Fellowship (JRF) by the Department of Science & Technology (2014).

🔬Research Focus:

Dr. Kashinath Lellala’s research is centered on advanced functional materials for energy and environmental applications. His expertise spans photo- and electro-catalysis, heavy metal removal, and organic pollutant degradation through semiconductor-supported photocatalysts. His work on heterojunction materials includes developing fuel cell electrodes (HER, OER, ORR) and lithium-ion battery anode/cathode materials using metal oxide/metal sulfide composites. He specializes in graphene-based nanomaterials, exploring the fabrication of porous graphene sheets doped with boron and nitrogen for enhanced electrochemical performance. Additionally, he has worked extensively on silicon-based anode materials for lithium-ion batteries, including the innovative synthesis of graphene from camphor. His research extends to microwave-assisted hydrothermal processing for fabricating high-efficiency heterostructures. His contributions in water remediation, particularly through photo-electrochemical oxidation, demonstrate his commitment to sustainable and green chemistry solutions for environmental challenges.

Publication Top Notes:

Fe₃O₄ nanoparticles decorated on N-doped graphene oxide nanosheets for elimination of heavy metals from industrial wastewater and desulfurization

Ceria Boosting on In Situ Nitrogen-Doped Graphene Oxide for Efficient Bifunctional ORR/OER Activity

Citations: 7

Sol-gel mediated microwave synthesis of Fe₃O₄ nanoparticles decorated on N-doped graphene oxide nanosheets: An excellent material for removal of heavy metals, organic pollutants, and desulfurization

Ceria boosting on in-situ nitrogen-doped graphene oxide for efficient bifunctional ORR/OER activity

Electrochemical Deposition of Si Nano-spheres from Water Contaminated Ionic Liquid at Room Temperature: Structural Evolution and Growth Mechanism

One-pot microwave synthesis of SnSe and Lanthanum doped SnSe nanostructure with direct Z scheme pattern for excellent photodegradation of organic pollutants

Microwave-hydrothermal synthesis of copper sulphide nanorods embedded on graphene sheets as an efficient electrocatalyst for excellent hydrogen evolution reaction

Sulphur Embedded On In-Situ Carbon Nanodisc Decorated On Graphene Sheets For Efficient Photocatalytic Activity And Capacitive Deionization Method For Heavy Metal Removal

Microwave-Assisted Facile Hydrothermal Synthesis of Fe₃O₄–GO nanocomposites for the Efficient Bifunctional Electrocatalytic Activity of OER/ORR

Role of surface passivation on the development of camphor-based Graphene/SiNWAs Schottky diode

Dr. Maya Setan Diakité | Materials Chemistry | Best Researcher Award

Posted on 03/12/202403/12/2024 by sciencefather

Dr. Maya Setan Diakité | Materials Chemistry | Best Researcher Award

Dr. Maya Setan Diakité ,Swedish University of Agricultural Sciences (SLU) , Sweden

Dr. Maya-Sétan Diakité is a French Ph.D. student specializing in plant chemistry, currently researching at UniLaSalle and the University of Artois in France. Her research focuses on the valorization of plant agricultural waste, specifically hemp shiv, for sustainable building materials. Maya has also worked as a postdoctoral researcher at the Swedish Agricultural University, specializing in super-absorbent biomaterials derived from plant waste. Passionate about agro-resources and lignocellulosic biomass, she has been actively involved in scientific outreach and teaching. Dr. Maya-Sétan Diakité is fluent in French, with working proficiency in English, Spanish, and Swedish. Outside of academics, she enjoys music, movies, and taekwondo.

Professional Profile: