Song Ziwei | Catalysis | Research Excellence Award

Published on by Analytical Chemistry

Assoc. Prof. Dr. Song Ziwei | Catalysis | Research Excellence Award

Yanshan University | China

Ziwei Song is an Associate Professor of Chemical Engineering at Yanshan University, specializing in catalysis, reaction engineering, and sustainable chemical processes. His research focuses on designing advanced catalytic materials, including bimetallic nanostructures and metal–organic frameworks, for biomass valorization, CO₂ conversion, and electrochemical energy coupling. As an independent principal investigator, he has led national and provincial projects on HMF oxidation, water electrolysis, and environmental remediation. His work integrates kinetic modeling, mechanistic insights, and process optimization, with publications in leading international journals.

Citation Metrics (Scopus)

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   20
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Citations
268

Documents
11

h-index
9

Citations

Documents

h-index

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Featured Publications

Ting Han | Organic Chemistry | Young Scientist Award

Published on by Analytical Chemistry

Assist. Prof. Dr. Ting Han | Organic Chemistry | Young Scientist Award

Texas Woman’s University | United States

Dr. Ting Han is a dynamic early-career scientist whose research spans organic synthesis, porphyrin chemistry, photocatalysis, functional materials, and molecular sensing technologies. He completed his Ph.D. in Organic Chemistry at the University of North Texas, where he specialized in macrocyclic compounds, cross-coupling reactions, and the synthesis of π-extended porphyrins and semiconductor-like 2D organic materials. With six years of combined teaching and research experience, Dr. Han has developed strong expertise in experimental design, analytical instrumentation, method development, and advanced spectroscopic techniques, including fluorescence, phosphorescence, transient absorption, and spectroelectrochemistry. His research accomplishments include designing and synthesizing over 20 novel organic molecules, developing new porphyrin-based photocatalysts for environmental remediation, and advancing biosensor technologies for detecting pollutants, biomolecules, and hazardous chemicals. Dr. Han has published 15 peer-reviewed articles in prominent journals such as Chemical Communications, Materials Chemistry Frontiers, Journal of Materials Chemistry B, Analyst, ACS Sensors, and Microchimica Acta, with a cumulative citation count of 294 and an H-index of 8. His innovative work also led to three granted Chinese patents in sensing and nanomaterial applications. In addition to his research, he is an experienced educator skilled in teaching General and Organic Chemistry, mentoring students, and designing laboratory and online learning experiences. After serving as a Visiting Lecturer at Texas Woman’s University, Dr. Han joined the institution as an Assistant Professor, where he continues building an active research group focused on functional organic materials, sustainable chemistry, and next-generation sensing platforms. His multidisciplinary expertise and impactful contributions reflect significant promise as a rising scientist in the field of organic and materials chemistry.

Profiles : Scopus | ORCID | Google Scholar

Featured Publications

  • Han, T., Starrett, N., Martin, K., Bueno Arroyo, J., Wang, S., & Rawashdeh-Omary, M. (in press). Green synthetic strategies for porphyrins: Toward sustainable functional macrocycles. ChemistrySelect.

  • Han, T., Wang, S., Salazar, G. A., & Rawashdeh-Omary, M. (2025). Porous porphyrin-based photocatalysts: Recent progress and applications in environmental remediation. Materials Chemistry Frontiers.

  • Han, T., Sharma, P., Khetrapal, N., & Wang, H. (2024). Conjugated porphyrin trimers linked through benzo[4,5]imidazo[2,1-a]isoindole bridges. Chemical Communications, 60(77), 10696–10699.

  • Han, T., Jang, Y., Arvidson, J., D’Souza, F., & Wang, H. (2022). Optical and photophysical properties of platinum benzoporphyrins with C2v and D2h symmetry. Journal of Porphyrins and Phthalocyanines, 26(6–7), 458–468.

  • Han, T., & Wang, G. (2019). Peroxidase-like activity of acetylcholine-based colorimetric detection of acetylcholinesterase activity and inhibitor organophosphorus. Journal of Materials Chemistry B, 7(16), 2613–2618.

 

Myrtil Kahn | Coordination Chemistry | Best Researcher Award

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Dr. Myrtil Kahn | Coordination Chemistry | Best Researcher Award

CNRS | France

Profiles

Scopus
Orcid

Early Academic Pursuits

Dr. Myrtil L. Kahn began her academic journey with a PhD in molecular compounds, under the supervision of a renowned expert in the field of coordination chemistry. Her doctoral work laid a strong foundation in molecular chemistry, which she later expanded into interdisciplinary domains. Her postdoctoral research included advanced work on ferrite nanoparticles and intermetallic particles, which positioned her at the intersection of nanoscience, materials chemistry, and applied physics.

Professional Endeavors

Following her postdoctoral experience, Dr. Kahn joined CNRS and quickly rose through the ranks to become a Senior Scientist and Research Director. She currently leads the “Nano-chemistry, Organization, and Sensors” team at the Laboratory of Coordination Chemistry (LCC) and also co-directs a multidisciplinary research initiative in collaboration with another leading national laboratory. This joint effort culminated in the establishment of a CNRS-affiliated joint research laboratory, reflecting her leadership in managing strategic partnerships with key industrial and governmental stakeholders, including aerospace and space agencies.

Contributions and Research Focus

Dr. Kahn’s research centers on nanoscience and its application to broad societal challenges such as energy, environment, space, aeronautics, and health. She has significantly contributed to the design and synthesis of hybrid nano-objects and multifunctional coatings. Her work focuses on controlling the structural and functional properties of nanoparticles particularly semiconductor and magnetic oxides and integrating them into real-world devices. Utilizing a safe-by-design philosophy, she innovates at the interface of molecular chemistry, surface science, and nanotechnology. Her research also emphasizes understanding surface-ligand interactions through advanced techniques like NMR spectroscopy, which is crucial for ensuring colloidal stability and optimizing material behavior in biological and industrial environments.

Impact and Influence

Dr. Kahn has established herself as a leader in applied nanosciences, successfully bridging fundamental chemistry with device integration. Her research has attracted substantial funding through over thirty competitive contracts, nearly half of which involve industrial collaborations. These projects have led to multiple patents with international extensions, showcasing her commitment to innovation and knowledge transfer. Beyond scientific output, her leadership in organizing large-scale conferences and her role in interdisciplinary teams underscore her influence across both academic and industrial landscapes.

Academic Citations

Her research excellence is reflected in her strong citation metrics. With thousands of citations and an impressive h-index, her work enjoys sustained recognition in the global scientific community. She has authored more than a hundred publications in peer-reviewed international journals, contributed to several book chapters, and is actively involved in reviewing and editorial responsibilities within leading scientific events and journals.

Technical Skills

Dr. Kahn possesses deep technical expertise in organometallic synthesis, nanoparticle surface chemistry, colloidal stability, and functional coatings. She has extensive experience in spectroscopic analysis, particularly NMR, for the investigation of ligand dynamics and surface coordination. Her proficiency extends to hybrid material fabrication, integration of nanoparticles into sensors and devices, and the development of safe-by-design methodologies. This multidisciplinary toolkit enables her to work effectively at the interface of chemistry, physics, and biology.

Teaching Experience

While her primary role is research-intensive, Dr. Kahn actively contributes to mentoring young researchers and postdoctoral fellows. She fosters scientific development through collaborative research, co-authorship, and direct supervision. Her mentorship style is marked by encouraging innovation and interdisciplinary approaches, preparing early-career scientists for careers in both academia and industry.

Legacy and Future Contributions

Dr. Kahn’s legacy is one of impactful science, interdisciplinary collaboration, and societal relevance. Her commitment to applied nanoscience has led to the development of novel materials and processes with potential applications in biotechnology, aerospace, and environmental technology. As co-director of a cutting-edge joint research lab, she continues to expand her collaborative reach, ensuring that her contributions influence the next generation of researchers. Her ongoing projects in multifunctional nanocomposites and hybrid processes promise continued breakthroughs in high-performance materials.

Notable Publications

Competition between ordered morphologies of functionalized silver nanoparticles elucidated by a joint experimental and multiscale theoretical study

Authors: David Loffreda; Nathalie Tarrat; Corinne Lacaze‑Dufaure; Franck Rabilloud; Katia Fajerwerg; Myrtil L. Kahn; Vincent Collière; Christine Lepetit; Pierre Fau
Journal: Nano Today
Year: 2025

Understanding Ion‑Exchange Processes in the Synthesis of ZnSₓ@ZnO₁₋ₓ Heterostructures from Controlled Sulfidation of ZnO Nanocrystals

Authors: Ekaterina Bellan; Martin Jakoobi; Vincent Collière; Yannick Coppel; Julien Trébosc; Olivier Lafon; Pierre Lecante; Paul Fleurat‑Lessard; Céline Dupont; Jean‑Cyrille Hierso; Pierre Fau; Katia Fajerwerg; Lauriane Pautrot‑d’Alençon; Thierry Le Mercier; Myrtil L. Kahn
Journal: Chemistry of Materials
Year: 2024

Spontaneous Emulsification of Organometallic Complexes Applied to the Synthesis of Nanocapsules Active for H₂ Release from Ammonia‑Borane

Authors: Olivier Gazil; Ludivine Rault; Déborah Iglicki; Vincent Collière; Gizem Karacaoglan; Didier Poinsot; Moad Bouzid; Jean‑Cyrille Hierso; Myrtil L. Kahn; Nick Virgilio; Fabienne Gauffre
Journal: Langmuir (The ACS Journal of Surfaces and Colloids)
Year: 2024

Synthesis of TiO₂/SBA‑15 Nanocomposites by Hydrolysis of Organometallic Ti Precursors for Photocatalytic NO Abatement

Authors: Ons El Atti; Julie Hot; Katia Fajerwerg; Christian Lorber; Bénédicte Lebeau; Andrey Ryzhikov; Myrtil L. Kahn; Vincent Collière; Yannick Coppel; Nicolas Ratel‑Ramond; Philippe Ménini; Pierre Fau
Journal: Inorganics
Year: 2024

Conclusion

Dr. Myrtil L. Kahn stands as a prominent figure in nanoscience and coordination chemistry. Her pioneering research, strong industrial collaborations, and leadership in both national and international scientific communities demonstrate her eligibility for high-level scientific honors. Through her interdisciplinary vision and dedication to real-world impact, she continues to shape the future of materials science and remains an exemplary model for academic and industrial synergy.

 

Muthuraj Arunpandian | Catalysis | Excellence in Research Award

Published on by Analytical Chemistry

Dr. Muthuraj Arunpandian | Catalysis | Excellence in Research Award

Yeungnam University, India

👨‍🎓Profiles

👨‍🔬 Early Academic Pursuits

Dr. Muthuraj Arunpandian began his academic journey in Tamil Nadu, India, earning his Bachelor’s and Master’s degrees from Madurai Kamaraj University. He further pursued doctoral studies at Kalasalingam Academy of Research and Education, Krishnankoil, where he specialized in nanomaterials and catalysis. His academic training laid the foundation for his focused research in photocatalysis and electrocatalysis, aiming at environmental and energy-related solutions.

🌐 Professional Endeavors

Since 2023, Dr. Arunpandian has been serving as an International Research Professor at the School of Chemical Engineering, Yeungnam University, South Korea. In this role, he leads cutting-edge research in the field of catalysis, collaborating internationally to address challenges in sustainable energy and environmental remediation. His work bridges material science and chemical engineering, emphasizing interdisciplinary solutions.

🔬 Research Contributions and Focus

Dr. Arunpandian’s research is primarily focused on two interconnected areas: photocatalysis and electrocatalysis.

  • In photocatalysis, his group develops visible-light-driven semiconductor nanostructures for environmental cleanup and solar hydrogen production. Their innovations in doping strategies, heterojunction design, and surface modifications have dramatically enhanced charge carrier separation, light absorption, and overall catalytic efficiency.

  • In electrocatalysis, he pioneers low-cost, high-efficiency electrocatalysts for water splitting. His work on transition metal-based materials and single-atom catalysts has produced systems with low overpotentials, high current densities, and outstanding durability, offering scalable paths toward clean hydrogen production.

📈 Impact and Influence

Dr. Arunpandian has published over 75 research and review articles in reputed national and international journals, garnering more than 1,200 citations to date. In addition to these publications, he has contributed 2 book chapters, underlining his scholarly productivity and domain authority. His research is widely cited in areas related to green chemistry, renewable energy, and environmental remediation, reflecting its global significance.

🧪 Technical Skills and Innovations

His core technical competencies include:

  • Nanomaterial synthesis (e.g., doped semiconductors, metal-based nanostructures)

  • Photocatalytic degradation systems for pollutant removal

  • HER/OER performance optimization through material design

  • Surface/interface engineering, heterojunction fabrication, and bandgap tuning
    These skills allow him to engineer materials that are both high-performing and scalable for real-world energy and environmental applications.

🎓 Teaching and Mentorship

As an International Research Professor, Dr. Arunpandian actively contributes to academic mentoring and international research training, guiding graduate students and postdoctoral researchers in the synthesis and characterization of nanomaterials. His cross-cultural mentorship fosters innovation and scientific communication at a global scale.

🌱 Legacy and Future Directions

Dr. Arunpandian’s research contributes directly to the United Nations Sustainable Development Goals, particularly in clean energy and environmental sustainability. His future endeavors will likely focus on integrating AI-based catalyst design, scalable synthesis methods, and industry partnerships for real-world deployment. His vision is to accelerate the transition to clean hydrogen economies and pollutant-free ecosystems, leaving a lasting scientific and societal impact.

📖Notable Publications

A rational design of novel Z-scheme N-rich g-C₃N₅ supported Ag₂WO₄/BiVO₄ ternary heterojunction for remarkably enhanced visible-light-driven photocatalytic activity of acebutolol antibiotic: Performance, mechanism insight and fragments pathway analysis
Authors: Muthuraj Arunpandian, Tae Hwan Oh, Karuppaiah Selvakumar
Journal: Journal of Alloys and Compounds
Year: 2025

Exceptional Visible-Light-Driven Photodegradation Performance Over N-Rich g-C₃N₅ Decorated Flower-like SrMoO₄ Nanohybrids: Analysis of Mechanism, Efficacy and Degradation Pathway
Authors: Muralidharan S., Arunpandian M., Nagarajan E. R., Oh Tae Hwan, Selvakumar K.
Journal: Journal of Inorganic and Organometallic Polymers and Materials
Year: 2025

Fabrication of dopamine/TiO₂ nanocomposite hydrogel using fenugreek gum for efficient photocatalytic degradation of organic pollutants under visible light irradiation
Authors: Nagaraja Kasula, Arunpandian Muthuraj, Oh Tae Hwan
Journal: Journal of Industrial and Engineering Chemistry
Year: 2025

Green synthesis of Zinc Sulfide doped Ag-Zn₃(PO₄)₂ nanocomposite using bael gum: Enhanced visible-light driven photocatalytic degradation of ciprofloxacin and trypan blue with potential antimicrobial and assessment
Authors: Nagaraja Kasula, Boya Mallika, Arunpandian Muthuraj, Oh Tae Hwan
Journal: Inorganic Chemistry Communications
Year: 2025

Nitrogen-Doped Hollow Carbon Spheres-Decorated Co₂SnO₄/WS₂ Heterostructures with Improved Visible-Light Photocatalytic Degradation of Organic Dye
Authors: Muthuraj Arunpandian, Tae Hwan Oh
Journal: Molecules
Year: 2025

A facile green synthesis of manganese oxide nanoparticles using gum karaya polymer as a bioreductant for efficient photocatalytic degradation of organic dyes and antibacterial activity
Authors: Nagaraja Kasula, Muthuraj Arunpandian, Oh Tae Hwan
Journal: International Journal of Biological Macromolecules
Year: 2024

 

Nini Wen | Catalysis | Best Researcher Award

Published on by Analytical Chemistry

Dr. Nini Wen | Catalysis | Best Researcher Award

Zhejiang Sci-Tech University, China

👨‍🎓Profiles

🎓 Early Academic Pursuits

Dr. Nini Wen began her academic journey with a strong foundation in chemical engineering and materials science, culminating in the award of her Ph.D. in 2023. Shortly thereafter, she joined Zhejiang Sci-Tech University as a lecturer, where she continues to advance research at the intersection of environmental catalysis and materials chemistry.

💼 Professional Endeavors

Since her appointment, Dr. Wen has dedicated her academic career to the study and development of Selective Catalytic Reduction-Hydrocarbon (SCR-HC) catalysts, particularly focusing on novel catalytic systems like metal oxides, pillared interlayered clays (PILC), layered double hydroxides (LDHs), and atomic clusters. Her methodical approach integrates catalyst design with advanced characterization techniques to uncover fundamental catalytic properties and reaction mechanisms. She has completed one foundational research project and currently leads two additional national-level foundation projects, underscoring her growing research independence and leadership.

🧪 Contributions and Research Focus

Dr. Wen’s cutting-edge research lies in environmental pollution control and catalytic materials, particularly LDH-based catalysts for SCR-HC reactions. LDHs, known as emerging 2D layered materials, have seldom been utilized in this field. Her innovative work includes designing binary and ternary LDH catalysts, which leverage the synergistic effects of multi-metal components to enhance catalytic activity. She has thoroughly explored the impact of synergy on both the intrinsic physicochemical properties and catalytic mechanisms. Furthermore, her studies address real-world challenges by investigating how poisoning species such as H₂O, SO₂, and alkali metals influence catalyst performance and structural stability, making her contributions highly relevant for industrial applications.

🌍 Impact and Influence

Dr. Wen has made a significant mark in the catalysis community with over 20 peer-reviewed publications in high-impact journals including the Chemical Engineering Journal, Fuel, Journal of Environmental Chemical Engineering, and Molecular Catalysis. Her work continues to inspire new approaches in designing resilient and efficient environmental catalysts, positioning her as a promising young scholar in the field of applied catalysis.

📈 Academic Citations

Although early in her independent career, Dr. Wen’s publications are gaining recognition in the academic world, with citations steadily increasing. Her focus on mechanistic insight and application-driven research makes her work valuable for both academic studies and industrial implementations in pollution mitigation technologies.

🛠️ Technical Skills

Dr. Wen possesses a broad suite of experimental and analytical techniques essential to modern catalysis research. These include X-ray diffraction (XRD), BET surface area analysis, Fourier-transform infrared spectroscopy (FTIR), temperature-programmed desorption/reduction (TPD/TPR), and X-ray photoelectron spectroscopy (XPS), among others. These tools support her rigorous examination of structure-performance relationships in catalytic systems.

👩‍🏫 Teaching and Mentorship

As a lecturer, Dr. Wen is actively involved in undergraduate and graduate instruction. She integrates her research findings into the classroom to foster scientific curiosity and train students in environmental engineering and materials chemistry, laying the groundwork for future researchers.

🤝 Professional Memberships

Dr. Wen is a member of the Chemical Industry and Engineering Society of China, through which she engages in professional development and collaborative opportunities, staying current with trends in catalysis and environmental remediation technologies.

🌱 Legacy and Future Contributions

Dr. Wen’s pioneering work in LDH-based SCR-HC catalysis and pollution control positions her at the forefront of sustainable environmental technologies. Her future plans include exploring atomically dispersed catalysts, enhancing low-temperature catalytic activity, and developing next-generation catalyst systems with improved tolerance to industrial poisons. Her work is expected to play a vital role in the global effort to reduce industrial emissions and transition toward greener technologies.

📖Notable Publications

Preparation and de-NOₓ performance of C₃H₆-SCR over Cu-SAPO-44 catalyst
Authors: Zhou, H.; Zhang, H.; Wen, N.; Wang, X.; Xu, L.; Li, W.; Su, Y.
Journal: Chemical Industry and Engineering Progress
Year: 2023

Research on resistance of CuxNiyFez-LDHs derived catalysts to poisoning components and insight into the complex role of SO₂ on C₃H₆-SCR performance
Authors: Wen, N.; Zhou, H.; Ning, S.; Hu, M.; Deng, W.; Zhao, B.; Su, Y.
Journal: Journal of Environmental Chemical Engineering
Year: 2023

Research progress on supported Cu-based zeolite catalysts for the selective catalytic reduction of NOₓ with hydrocarbons
Authors: Ning, S.; Su, Y.; Yang, H.; Wen, N.
Journal: Chemical Industry and Engineering Progress
Year: 2023

Selective catalytic reduction of nitric oxide with propylene over one-step synthesized Cu-SAPO-44 catalysts
Authors: Zhang, H.; Zhou, H.; Wen, N.-N.; Wang, X.-R.; Xu, L.; Su, Y.-X.
Journal: Journal of Fuel Chemistry and Technology
Year: 2022

Study on CH₄-SCR performance by Ga-Fe catalysts supported on Ti-pillared interlayered clays (Ti-PILC)
Authors: Xu, G.-Q.; Su, Y.-X.; Wen, N.-N.; Zhang, H.; Liu, Q.; Deng, W.-Y.; Zhou, H.
Journal: Journal of Molecular Catalysis
Year: 2022

Synergy of CuNiFe-LDH based catalysts for enhancing low-temperature SCR-C₃H₆ performance: Surface properties and reaction mechanism
Authors: Wen, N.; Su, Y.; Deng, W.; Zhou, H.; Hu, M.; Zhao, B.
Journal: Chemical Engineering Journal
Year: 2022

 

Halil Ibrahim Efkere | Photochemistry | Best Researcher Award -1666

Published on by Analytical Chemistry

Mr. Halil Ibrahim Efkere | Photochemistry | Best Researcher Award

Gazi University, Turkey

👨‍🎓Profiles

🎓 Early Academic Pursuits

Halil Ibrahim Efkere’s academic journey began with a Bachelor's degree in Physics from Selçuk University in 2009. His passion for materials science and physics led him to pursue a Master's degree in Physics (with thesis) from Erciyes University, which he completed on January 7, 2014. Demonstrating exceptional dedication to research and innovation, he further advanced his studies with a Ph.D. in Metallurgical and Materials Engineering at Gazi University, completing his thesis in 2013. His doctoral research, supervised by Süleyman Özçelik and Tuncay Karaaslan, focused on the growth and characterization of InGaAs/GaAs superlattice structures using the Molecular Beam Epitaxy (MBE) technique, showcasing his expertise in advanced material synthesis.

🏢 Professional Endeavors

In 2020, Mr. Efkere was appointed as a Lecturer at the Gazi University Photonics Application and Research Center, where he significantly contributed to cutting-edge advancements in photonics and materials engineering. He has also played a key role in multiple research projects, such as: Leading the study on CeO2 thin films produced via RF Magnetron Sputtering for photocatalytic water purification applications. Collaborating on a project investigating TiO2 films produced using ultrasonic chemical spray methods for photocatalytic water splitting and cleaning applications. These endeavors reflect his commitment to addressing real-world challenges in water purification and renewable energy using innovative material solutions.

🧪 Contributions and Research Focus

Mr. Efkere’s research centers on thin-film materials and their application in photocatalysis, water purification, and photonics. His contributions include: Developing CeO2 and TiO2 thin films with enhanced photocatalytic activity for environmental applications. Utilizing advanced deposition techniques like RF Magnetron Sputtering and ultrasonic chemical spray to optimize material properties for energy and water treatment applications. Investigating the interaction of thin-film structures for practical industrial and scientific applications. His groundbreaking research not only contributes to the scientific community but also has significant environmental and technological implications.

🌍 Impact and Influence

Mr. Efkere’s work on molecular beam epitaxy, thin films, and photocatalytic applications has created a profound impact in the fields of materials science and photonics. His projects aim to advance sustainable energy solutions and water purification technologies, addressing some of the most pressing global challenges. His leadership in national-level projects further establishes him as a key figure in Turkey's scientific landscape.

📚 Academic Citations

Mr. Efkere’s research outputs are gaining traction in the academic community, with his published works being widely cited in areas such as thin-film technology, photocatalysis, and renewable energy materials. His meticulous approach to experimentation and publication ensures the reliability and reproducibility of his findings.

🛠️ Technical Skills

Mr. Efkere has honed several advanced technical skills, including: Material Synthesis Techniques: Molecular Beam Epitaxy (MBE), RF Magnetron Sputtering, Ultrasonic Chemical Spray. Characterization Methods: Scanning Electron Microscopy (SEM), X-ray Diffraction (XRD), Atomic Force Microscopy (AFM), and UV-Vis Spectroscopy. Data Analysis and Optimization: Utilizing software and modeling techniques to analyze experimental results. These skills enable him to design, implement, and analyze complex experiments effectively.

🧑‍🏫 Teaching Experience

As a lecturer at Gazi University, Mr. Efkere is actively involved in mentoring students and training young researchers in advanced material synthesis and photonics. His approachable teaching style and expertise in state-of-the-art techniques inspire his students to pursue excellence in their academic and professional careers.

🌟 Legacy and Future Contributions

Looking forward, Mr. Efkere is poised to make significant contributions in sustainable materials for environmental and energy applications. His commitment to advancing photocatalytic technologies holds the potential to revolutionize water purification and clean energy generation. Through his ongoing research, teaching, and collaborations, he continues to build a legacy of innovation and scientific excellence.

📖Notable Publications

Effect of TiO2-Surfactant Interface on the Electrical and Dielectric Properties of a Metal–Insulator–Semiconductor (MIS) Structure
Authors: Azizian-Kalandaragh, Y.; Efkere, H.I.; Barkhordari, A.; Pirgholi-Givi, G.R.; Altındal, Ş.
Journal: Journal of Electronic Materials
Year: 2025

Analysis of Nb-doped and undoped TiO2 nanocoatings with varying dopant concentrations
Authors: Arslan, Ö.; Efkere, H.İ.; Çokduygulular, E.; İldeş, C.; Kınacı, B.
Journal: Journal of Materials Science: Materials in Electronics
Year: 2025

Structural, morphological, optical and electrical characterization of MgO thin films grown by sputtering technique on different substrates
Authors: Toprak, B.Ç.; Efkere, H.İ.; Aydın, S.Ş.; Tataroğlu, A.; Özçelik, S.
Journal: Journal of Materials Science: Materials in Electronics
Year: 2024

Electrical and dielectric behaviors of Al/SiO2-surfactant/n-Si Schottky structure in wide range of voltage and frequency
Authors: Efkere, H.İ.; Barkhordari, A.; Marmiroli, B.; Altındal, Ş.; Azizian-Kalandaragh, Y.
Journal: Physica Scripta
Year: 2024

Detailed analysis of the structural, morphological, optical, electrical, and dielectric properties of the reactively produced WO3 nanostructure
Authors: Efkere, H.İ.; Özçelik, S.
Journal: Journal of Materials Science: Materials in Electronics
Year: 2023

Evaluation of dielectric properties of Au/TZO/n–Si structure depending on frequency and voltage
Authors: Kınacı, B.; Bairam, C.; Yalçın, Y.; Efkere, H.İ.; Özçelik, S.
Journal: Journal of Materials Science: Materials in Electronics
Year: 2022