Abedien Zabardasti | Inorganic Chemistry | Research and Development Excellence Award

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Prof. Abedien Zabardasti | Inorganic Chemistry | Research and Development Excellence Award

Prof. Abedien Zabardasti, Lorestan University, Iran

šŸŒŸ Prof. Abedien Zabardasti is a distinguished chemist and Full Professor of Inorganic Chemistry at Lorestan University, Khorramabad, Iran, where he has also served as the Head of the Department of Chemistry since 2019. He earned his PhD in Chemistry (2002) and MSc in Chemistry (1996) from Shiraz University, along with a BSc in Chemistry (1994) from Tehran University. Prof. Zabardasti’s research focuses on molecular interactions, coordination chemistry, nanochemistry, and theoretical chemistry, with an emphasis on porphyrins and metallo-porphyrins. A prolific author, he has made significant contributions to hydrogen storage, catalytic materials, and nanocomposites for environmental applications. Renowned for his expertise in inorganic and organometallic chemistry, his pioneering work continues to shape the field of advanced material sciences.

Publication Profile

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Academic Journey in Inorganic Chemistry

Prof. Abedien Zabardasti is a distinguished Professor of Inorganic Chemistry at Lorestan University, Khorramabad, Iran. He holds a PhD in Chemistry from Shiraz University, where he graduated in 2002, demonstrating exceptional expertise in the field. Prof. Zabardasti also earned his MSc in Chemistry from Shiraz University in 1996 and completed his BSc in Chemistry at Tehran University in 1994. With a strong foundation in chemistry, his academic pursuits and contributions have significantly advanced the discipline, inspiring students and researchers alike. šŸ“˜šŸ§Ŗ

Research Interests

Prof. Abedien Zabardastiā€™s research spans diverse and cutting-edge areas of chemistry. His primary focus lies in exploring molecular interactions and advancing the field of coordination chemistry. He is also deeply engaged in the innovative realm of nano chemistry, contributing to the development of nanomaterials with unique properties. Additionally, his expertise extends to theoretical chemistry, where he investigates complex chemical systems. Prof. Zabardasti is particularly interested in porphyrin and metallo porphyrins, delving into their structures and applications in various scientific fields. His work continues to inspire innovation in modern chemistry. šŸ§ŖšŸ”—āš›ļø

Teaching Expertise

Prof. Abedien Zabardasti is a dedicated educator with a wealth of knowledge in several key areas of chemistry. His teaching expertise includes inorganic chemistry, where he imparts a deep understanding of chemical elements and their properties. He is also proficient in organometallic chemistry, exploring compounds containing metal-carbon bonds. Prof. Zabardasti’s lessons in solid-state chemistry provide insights into the structures and behaviors of solids. Additionally, he specializes in the kinetics and mechanisms of transition metal reactions, fostering studentsā€™ comprehension of reaction dynamics and processes. His teaching inspires future chemists to excel in these advanced fields. šŸ§‘ā€šŸ«āš—ļøšŸ“š

Research Focus

Prof. Abedien Zabardasti specializes in inorganic and theoretical chemistry with diverse applications in nanomaterials, catalysis, and environmental remediation. His research explores metal-organic frameworks (MOFs), nanocomposites, and porphyrins, addressing challenges in radioactive iodine capture, hydrogen storage, and toxic pollutant removal. He also delves into noncovalent interactions and catalytic performance optimization, contributing to advancements in energy storage and visible-light photocatalysis. Prof. Zabardastiā€™s interdisciplinary approach bridges experimental studies with theoretical modeling, fostering innovative solutions for environmental and energy-related challenges. His work integrates green chemistry principles to develop sustainable and efficient chemical systems. šŸŒāš—ļøšŸ§ŖāœØ

Publication Top Notes

šŸ“„ Radioactive iodine capture by hexagonal boron nitride (h-BN) nanosheets in liquid and vapor phases: Experimental and theoretical studies
Year: 2025

šŸ“„ Silver (Ag) nanoparticles decorated on magnetic CoFeā‚‚Oā‚„/h-BN nanocomposites for efficient catalytic removal of toxic nitrophenols
Year: 2025

šŸ“„ Author Correction: Tailoring topology and bio-interactions of triazine frameworks
Year: 2024

šŸ“„ A theoretical modelling of NaBr(Hā‚‚)ā‚™ clusters as an approach in hydrogen gas storage
Year: 2024

šŸ“„ Tailoring topology and bio-interactions of triazine frameworks
Year: 2024

šŸ“„ Hā‚ƒPWā‚ā‚‚Oā‚„ā‚€/MIL-88A(Fe)/MIL-88B(Fe)/NiFeā‚‚Oā‚„ nanocomposite: A new magnetic sorbent based on MOF/MOF hybrid coupled with PWā‚ā‚‚Oā‚„ā‚€Ā³ā» polyanions for efficient removal of hazardous ā€¦
Cited by: 4
Year: 2024

šŸ“„ Construction of novel CoFeā‚‚Oā‚„/h-BN/MIL-53(Al) magnetic nanocomposites for the removal of hazardous antibiotics from water
Cited by: 5
Year: 2024

šŸ“„ Flower-like MoSā‚‚ microspheres highly dispersed on CoFeā‚‚Oā‚„/MIL-101(Fe) metal organic framework: A recoverable magnetic catalyst for the reduction of toxic nitroaromatics in ā€¦
Cited by: 1
Year: 2024

šŸ“„ Construction of magnetic MoSā‚‚/NiFeā‚‚Oā‚„/MIL-101(Fe) hybrid nanostructures for separation of dyes and antibiotics from aqueous media
Cited by: 3
Year: 2024

šŸ“„ The noncovalent complexes of nido-Cā‚„Bā‚‚Hā‚† with Hā‚‚O, CHā‚ƒOH and NHā‚ƒ Lewis bases: A theoretical study
Year: 2024

šŸ“„ A theoretical modeling of NaBr(Hā‚‚)ā‚™ clusters as a unique approach in hydrogen gas storage
Year: 2023

šŸ“„ Cooperation of Peripheral Hydrogen Atoms for the Stabilization of Aachno-pentaborane(11) with Small Molecules: Hydrogen Bonds and Dihydrogen Bonds
Year: 2023

šŸ“„ Simultaneous adsorption of ciprofloxacin drug and methyl violet dye on boron nitride nanosheets: Experimental and theoretical insights
Cited by: 5
Year: 2023

šŸ“„ Synthesis of pā€“n heterojunction SrFeOā‚ƒā‚‹ā‚“/TiOā‚‚ via thermal treatment/hydrolysis precipitation method with enhanced visibleā€light activity
Cited by: 7
Year: 2022

šŸ“„ A comprehensive research on BiFeOā‚ƒ/TiOā‚‚ nanocomposite synthesized via thermal treatment/hydrolysis precipitation method
Cited by: 4
Year: 2021

šŸ“„ Synthesis of the Novel ZSM-5/NiO/MIL-101(Cr) Zeolite Catalyst Nanocomposite and Its Performance for the Sonodegradation of Organic Dyes in Aqueous Solutions
Cited by: 2
Year: 2021

šŸ“„ A NaX zeolite framework containing magnetic MgFeā‚‚Oā‚„/CdO nanoparticles: synthesis, characterization and catalytic performance in the decontamination of 2-chloroethyl phenyl ā€¦
Cited by: 2
Year: 2021

šŸ“„ The formation of HĀ·Ā·Ā·X hydrogen bond, CĀ·Ā·Ā·X carbon-halide or SiĀ·Ā·Ā·X tetrel bonds on the silylene-halogen dimers (X = F or Cl): Intermolecular strength, molecular orbital ā€¦
Cited by: 5
Year: 2020

šŸ“„ Enhanced visible light activity of EuFeOā‚ƒ/TiOā‚‚ nanocomposites prepared by thermal treatmentā€“hydrolysis precipitation method
Cited by: 13
Year: 2020

Conclusion

Prof. Zabardasti’s leadership in the academic field, combined with his impactful research on nanomaterials, hydrogen storage, and environmental chemistry, establishes him as a strong candidate for the Research for Research and Development Excellence Award. His prolific publication record, especially in high-impact journals, and his significant contributions to both theoretical and practical chemistry make him a recognized expert in his field.

 

 

 

Kaipeng Wu | Physical Chemistry | Best Researcher Award

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Prof. Dr. Kaipeng Wu | Physical Chemistry | Best Researcher Award

Prof. Dr. Kaipeng Wu, Sichuan University, China

Prof. Dr. Kaipeng Wu, a native of Zhangye, Gansu Province, China, is an esteemed researcher specializing in energy storage materials. He earned his Ph.D. in Metallurgy and Environment from Central South University, focusing on scalable graphene production and Li-ion batteries. Dr. Wu’s work advances nanostructured materials for batteries, capacitors, and fuel cells. His pioneering research includes high-performance cathodes, graphene-based composites, and eco-friendly synthesis techniques. With numerous publications in top journals like Advanced Energy Materials and Carbon, Dr. Wu’s innovations impact sustainable energy technologies. He is passionate about scaling novel energy solutions for global sustainability. šŸ“šāš”šŸŒ

 

Publication Profile

Scopus

Educational Background šŸŽ“šŸ”¬šŸ“š

Prof. Dr. Kaipeng Wu holds a Ph.D. from the School of Metallurgy and Environment, Central South University, China (2010ā€“2016). His doctoral research focused on developing innovative materials for Li-ion batteries and designing scalable approaches for graphene production. Prior to this, he earned his Bachelor’s degree in Material Science and Engineering from Ji Lin University, China (2005ā€“2009), where he built a strong foundation in material science. His academic journey reflects a deep commitment to advancing energy storage technologies and sustainable materials, paving the way for impactful contributions to the field. āš”šŸŒ±āœØ

 

Research Experiences šŸ§Ŗāš”šŸŒ

Prof. Dr. Kaipeng Wu has extensively explored graphene and its composites for energy conversion and storage since 2015. His work includes scalable graphene oxide purification and the synthesis of nitrogen-doped and porous graphene. He developed nanosized transition metal oxides for high-capacity LIB anodes and advanced LiMnPO4/C cathodes using innovative techniques. His studies improved LiFePO4 cathode performance through Mn and Co substitution and optimized its rate capability using graphene-coated precursors. These projects, supported by prestigious grants, highlight his dedication to advancing battery technologies and sustainable energy solutions. šŸ”‹šŸŒŸāœØ

 

Research Interests šŸ”¬āš”šŸ”‹

Prof. Dr. Kaipeng Wuā€™s research focuses on designing and applying nanostructured materials for cutting-edge energy storage systems, including lithium-ion batteries (LIBs) and capacitors. He explores alternative battery technologies such as sodium/magnesium batteries, metal-air batteries, and fuel cells. A key aspect of his work involves developing innovative methods for the large-scale synthesis of graphene and its derivatives, with precise control over their shapes and properties. His contributions aim to revolutionize energy storage solutions, promoting efficiency, sustainability, and scalability in advanced energy technologies. šŸŒšŸŒŸšŸ“ˆ

 

Publication Top Notes

  • Synergistic Corrosion Engineering on Metallic Manganese Toward High-Performance Electrochemical Energy Storage (2024, 5 citations) šŸ”‹āš™ļøšŸ“š
  • Optimizing the Electrochemical Performance of Olivine LiMnxFe1-xPO4 Cathode Materials (2024, 3 citations) āš”šŸ”šŸ“ˆ
  • Thermodynamic Equilibrium Theory-Guided Design and Synthesis of Mg-Doped LiFe0.4Mn0.6PO4/C Cathode (2024, 5 citations) šŸ“šŸ”‹šŸ§Ŗ
  • Ultra-Thin Hydrogen-Organic-Framework (HOF) Nanosheets for Ultra-Stable Alkali Ions Battery Storage (2024, 9 citations) šŸŒŒšŸ”¬šŸŖ™
  • Regeneration Behavior of FePO4Ā·2H2O from Spent LiFePO4 Under Extremely Acidic Conditions (2024, 7 citations) šŸ”„šŸŒ±āš”
  • Rationalizing Na-Ion Solvation Structure for High-Voltage Sodium Metal Batteries (2023, 14 citations) šŸ§ŠšŸŖ™āš™ļø
  • Quenching-Induced Construction of Graphene-Wrapped Fe3O4 Composite (2023, 3 citations) šŸ”‹šŸ–¤šŸ“Š
  • Interface Engineering of Space-Confined Fe3O4/FeS Heterostructures (2023, 2 citations) šŸŒšŸ§²šŸ“‰
  • Recent Progress in Advanced Organosulfur Cathode Materials for Rechargeable Lithium Batteries (2023, 13 citations) āš›ļøšŸ”¬šŸŒæ
  • V-Substituted Pyrochlore-Type Polyantimonic Acid for Lithium-Ion Storage (2023, 1 citation) šŸ’”šŸ”‹šŸ”µ