Chang Soon Huh | Physical Chemistry | South Korea

Published on by Chemical Scientist

Assist. Prof. Dr. Chang Soon Huh | Physical Chemistry | South Korea

Assistant Professor | Dong-Eui University | South Korea

Dr. Chang-soon Huh is an emerging researcher recognized for his growing contributions to analytical chemistry, biosensing technologies, and nanomaterial-assisted detection systems. With 13 peer-reviewed publications, 50 citations, and an h-index of 3, he demonstrates a steadily rising academic influence supported by methodologically robust and application-driven studies. His work integrates fluorescence spectroscopy, biomolecular recognition, and engineered nanomaterials to create rapid, sensitive, and cost-efficient diagnostic platforms capable of addressing contemporary analytical challenges. One of his notable achievements includes the development of a fluorescent detection strategy for alkaline phosphatase based on gold nanoclusters and p-nitrophenyl phosphate, underscoring his ability to connect fundamental chemical principles with practical biosensing innovation. His research portfolio highlights strong interdisciplinary collaboration, engaging co-authors across materials science, biotechnology, and chemical engineering, which enriches the scientific depth and applicability of his studies. These collaborations support novel advancements in high-sensitivity detection systems, enabling precise monitoring of biochemical reactions and contributing to improved diagnostic and environmental assessment methodologies. Beyond quantitative publication metrics, his work demonstrates broader societal relevance, particularly in areas requiring early disease detection, quality assurance in bioprocessing, and real-time analysis of biochemical pathways. His commitment to scientific rigor, innovation, and problem-solving positions him as a promising researcher with expanding influence in the global analytical science community. Through consistent scholarly output and an expanding citation record, Dr. Huh continues to advance impactful research that aligns with emerging needs in biosensing, nanotechnology, and chemical diagnostics.

Profiles : Scopus | ResearchGate

Featured Publications

Kim, S.-H., Huh, C.-S., & Kim, M.-M. (2025). Rapid and sensitive detection of alkaline phosphatase based on fluorescent gold nanoclusters and p-nitrophenyl phosphate. Journal of Bioscience and Bioengineering. Citations: 1

Lee, S. E., & Huh, C.-S. (2025). Application of smartphones to measurements of reducing power related to antioxidant activity. Journal of Analytical Chemistry.

Kim, G. H., Huh, C.-S., & Kim, M.-M. (2024). Development of a smartphone-based method for measuring the antioxidant efficacy of commercial beverages. Current Analytical Chemistry.

Talapphet, N., & Huh, C.-S. (2024). A smartphone colorimetric development with TMB/H₂O₂/HRP reaction system for hydrogen peroxide detection and its applications. Journal of Analytical Chemistry. Citations: 10

Talapphet, N., & Huh, C.-S. (2024). Development of gold nanocluster complex for the detection of tumor necrosis factor-alpha based on immunoassay. Journal of Immunological Methods. Citations: 4

Chang-soon Huh’s work advances analytical science through innovative biosensing and nanomaterial-based detection systems that improve accuracy, speed, and accessibility in chemical and biochemical analysis. His research supports global innovation in health diagnostics and contributes to practical technologies that strengthen scientific, industrial, and societal advancements.

Mainak Saha | Materials Chemistry | Best Researcher Award

Published on by Chemical Scientist

Dr. Mainak Saha | Materials Chemistry | Best Researcher Award

Postdoctoral Researcher | National Institute for Materials Science | Japan

Dr. Mainak Saha is an emerging materials science researcher whose work demonstrates notable advancements in additive manufacturing, alloy development, and microstructural engineering, with a strong focus on designing high-performance metal matrix composites and understanding the intricate relationships between processing conditions, segregation behavior, and resulting mechanical properties. With a portfolio comprising 14 peer-reviewed publications and 86 citations, supported by an h-index of 5 , his contributions reflect a growing influence within the global materials research community. His studies frequently explore the development of lightweight, high-strength alloy systems, the thermodynamic and kinetic factors governing phase formation, and strategies for microstructural refinement that enhance strength, durability, and thermal stability in engineered metals. Notably, his research on segregation-induced microstructural refinement in FeMnAlC-TiB metal matrix composites produced via laser powder bed fusion  highlights his expertise in advanced manufacturing pathways and his ability to integrate metallurgical principles with cutting-edge fabrication technologies. Dr. Saha has collaborated with over 80 co-authors, illustrating his active participation in multidisciplinary research teams and underscoring his capacity to contribute significantly to collaborative scientific initiatives . His work intersects with critical industrial fields such as transportation, energy, and high-performance manufacturing, where the need for innovative, lightweight, corrosion-resistant, and structurally reliable materials is rapidly increasing. Through his research, he contributes to solving practical engineering challenges, improving manufacturing efficiency, and supporting global efforts toward sustainable, high-performance material solutions. His scientific output reflects both academic rigor and technological relevance, bridging fundamental metallurgical science with applied engineering innovation. As he continues to expand his research portfolio, Dr. Saha’s contributions are expected to further influence materials design methodologies, support the development of next-generation structural materials, and strengthen the broader scientific understanding of microstructure-property relationships in advanced alloys .

Profiles : Google Scholar | Scopus | ORCID 

Featured Publications

Saha, M., & Mallik, M. (2021). Additive manufacturing of ceramics and cermets: Present status and future perspectives. Sādhanā, 46(3), 162.
Cited by: 40

Gault, B., Saksena, A., Sauvage, X., Bagot, P., Aota, L. S., Arlt, J., Belkacemi, L. T., … Saha, M. (2024). Towards establishing best practice in the analysis of hydrogen and deuterium by atom probe tomography. Microscopy and Microanalysis, 30(6), 1205–1220.*
Cited by: 30

Gururaj, K., Saha, M., Maurya, S. K., Nama, R., Alankar, A., Ponnuchamy, M. B., … (2022). On the correlative microscopy analyses of nano-twinned domains in 2 mol% zirconia-alloyed yttrium tantalate thermal barrier material. Scripta Materialia, 212, 114584.
Cited by: 17

Saha, M., Ponnuchamy, M. B., Sadhasivam, M., Mahata, C., Vijayaragavan, G., … (2022). Revealing the localization of NiAl-type nano-scale B2 precipitates within the BCC phase of Ni-alloyed low-density FeMnAlC steel. JOM, 74(8), 3181–3190.
Cited by: 15

 Mallik, M., & Saha, M. (2021). Carbon-based nanocomposites: Processing, electronic properties and applications. In Carbon nanomaterial electronics: Devices and applications (pp. 97–122).
Cited by: 15

Dr. Mainak Saha’s research advances the development of high-performance alloys and additive manufacturing technologies, driving innovations that strengthen modern engineering, enhance industrial efficiency, and support global progress in sustainable, next-generation materials. His work continues to bridge fundamental science with real-world technological impact.

Chung-Yin | Supramolecular Chemistry | Best Researcher Award

Published on by Chemical Scientist

Dr. Chung-Yin Lin | Supramolecular Chemistry | Best Researcher Award

Associated Principle Investigator | Chang Gung University | Taiwan

Dr. Chungyin Lin is a distinguished researcher whose work spans neuroscience, molecular biochemistry, and advanced diagnostic technologies, with a strong record of scientific influence demonstrated by 43 peer-reviewed publications and more than 1,817  citations. His research portfolio encompasses the molecular mechanisms underlying neurodegenerative disorders, with notable investigations into tau-related neuroinflammation, mitochondrial dysfunction, dysregulation of choline metabolism, and the therapeutic potential of bioactive compounds such as citicoline and kynurenic acid. Dr. Lin has also contributed significantly to translational diagnostic science through the development of paper-based molecularly imprinted sensing platforms designed for sensitive and accessible biomarker detection, reflecting a broader commitment to bridging biological insights with practical clinical tools. His publications in widely recognized journals highlight a sustained focus on disorders such as Huntington’s disease and Parkinson’s disease, where his findings support ongoing advancements in early diagnosis, therapeutic targeting, and neuroprotective intervention strategies. Dr. Lin’s work is further strengthened by extensive interdisciplinary collaboration, having co-authored studies with over 130 researchers from diverse scientific domains, including clinicians, pharmacologists, materials scientists, and biomedical engineers. These collaborations have accelerated progress in understanding disease-related biochemical pathways, developing innovative detection methods, and proposing new therapeutic hypotheses, thereby enhancing the societal and scientific impact of his research. With an h-index of 21, Dr. Lin continues to contribute meaningfully to global biomedical research through rigorous experimentation, integrative methodology, and a vision oriented toward improving human health through scientific innovation.

Featured Publications

Lin, T.-H., Tseng, P.-H., Chen, I.-C., & Chen, C.-M. (2025). The potential of mulberry (Morus alba L.) leaf extract against pro-aggregant Tau-mediated inflammation and mitochondrial dysfunction.

Lin, T.-C., Lin, C. Y., Hwang, Y.-T., & Tai, D.-F. (2025). Paper-based molecularly imprinted film designs for sensing human serum albumin.

Chang, K.-H., Cheng, M.-L., Tang, H.-Y., et al., & Chen, C.-M. (2024). Dysregulation of choline metabolism and therapeutic potential of citicoline in Huntington’s disease.

Chen, C.-M., Huang, C.-Y., Lai, C.-H., et al., & Lin, C. Y. (2024). Neuroprotection effects of kynurenic acid-loaded micelles for the Parkinson’s disease models.

Yang, P.-N., Chen, W.-L., Lee, J.-W., et al., & Lee-Chen, G.-J. (2023). Coumarin-chalcone hybrid LM-021 and indole derivative NC009-1 targeting inflammation and oxidative stress to protect BE(2)-M17 cells against α-synuclein toxicity.

Dr. Chungyin Lin’s research advances global understanding of neurodegeneration while driving innovative diagnostic and therapeutic strategies that address critical unmet needs in neurological health. His interdisciplinary work bridges molecular science, technology, and clinical application, contributing meaningful solutions that enhance healthcare outcomes and societal well-being.

Yanhe Han | Environmental Chemistry | Editorial Board Member

Published on by Chemical Scientist

Prof. Yanhe Han | Environmental Chemistry | Editorial Board Member

Dean | Beijing Institute of Petrochemical Technology | China

Han Yanhe is a highly cited researcher known for influential contributions in environmental engineering, catalytic materials development, advanced oxidation processes, and innovative wastewater treatment technologies. With a substantial record of 68 peer-reviewed publications, over 1,602 citations, and an h-index of 20, Han has established a strong global research presence characterized by consistent scientific impact and extensive multidisciplinary engagement. His work spans the design of integrated nitrogen and sulfur removal systems, including synergistic approaches combining sulfate reduction, sulfur-autotrophic denitrification, and micro-electrolytic pathways to achieve efficient treatment of complex and sulfate-rich wastewaters. Han has advanced understanding of the mechanistic interplay between sulfur-based electron donors and iron–carbon micro-electrolysis, contributing engineering strategies that enhance pollutant degradation and support scalable, sustainable water-treatment solutions. In the field of catalysis, he has contributed to the development of high-performance materials such as CeO₂/GO-co-doped MoS₂ composites, improving electrocatalytic hydrogen evolution and offering practical, cost-effective alternatives to noble-metal-based systems. His research portfolio further encompasses low-temperature plasma-driven oxidation for the mitigation of pharmaceutical and personal-care contaminants, environmental impact assessments of analytical detection methods, and intensified micro-electrolysis techniques tailored for highly toxic industrial waste streams. With collaborations spanning over 140 co-authors, Han has demonstrated a strong commitment to interdisciplinary research and scientific integration across chemistry, materials science, and environmental systems engineering. Many of his publications continue to accumulate significant citations, underscoring the relevance and applicability of his findings to both academic research and industrial practice. Through a combination of mechanistic insight, engineering innovation, and sustainability-focused design, Han Yanhe’s body of work contributes substantially to global efforts aimed at advancing clean-water technologies, enhancing catalytic efficiency, reducing environmental burdens, and supporting sustainable chemical engineering practices.

Profiles : Scopus

Featured Pulications

  1. Han, Y., Xu, H., Zhang, L., Ma, X., Man, Y., Su, Z., & Wang, J. (2023). An internal circulation iron–carbon micro-electrolysis reactor for aniline wastewater treatment: Parameter optimization, degradation pathways and mechanism. Chinese Journal of Chemical Engineering, 63(11), 96–107.

  2. Han, Y., Zhang, S., Zhang, X., Wu, C., & An, R. (2020). Optimization of the conditions for degradation of hydrolyzed polyacrylamide using electro-coagulation. Desalination and Water Treatment, 179, 148–159.

  3. Han, Y., Zhang, S., Xiaofei, Z., & Chen, J. (2020). Electrochemical oxidation of Hydrolyzed Polyacrylamide (HPAM) at Ti/SnO₂-Sb₂O₃/β-PbO₂ anode: Degradation kinetics and mechanisms. International Journal of Electrochemical Science, 15(4), 3382–3399.

  4. Han, Y., Wang, H., Wei, M., … Ma, X. (2025). Advanced low-temperature plasma-driven oxidation for mitigating pharmaceutical and personal care products in wastewater: Mechanisms, influencing factors, and reactor configurations.

    Prof. Yanhe Han advances sustainable environmental engineering through innovative electrochemical and micro-electrolysis technologies for efficient pollutant removal. His work delivers practical solutions for industry while contributing to global efforts toward cleaner water systems and a healthier environment.

Gunjan Jadon | Medicinal Chemistry | Women Researcher Award

Published on by Chemical Scientist

Dr. Gunjan Jadon | Medicinal Chemistry | Women Researcher Award

Professor | Pacific College of Pharmacy | India

Dr. Gunjan Jadon is an emerging researcher in pharmaceutical analysis and analytical chemistry, known for her contributions to quality-centered method development and scientific rigor. With a growing academic profile reflected through 3 peer-reviewed publications, 54 citations, and an h-index of 2, she has steadily established her presence within the analytical science community. Her research focuses on chromatographic method development, impurity assessment, pharmaceutical quality control, and the systematic application of Analytical Quality by Design (QbD) principles. One of her notable works includes the development and validation of a QbD-based RP-HPLC method for the quantification of dobutamine, demonstrating her expertise in experimental optimization, response-surface modeling, and regulatory aligned method validation. Dr. Jadon’s broader research interests integrate risk assessment, analytical robustness studies, and the enhancement of method precision and reproducibility to support high-quality pharmaceutical evaluation. She actively collaborates with multidisciplinary teams of pharmaceutical scientists and analytical chemists, strengthening the practical and translational impact of her findings. Her work contributes to improving drug-evaluation workflows, ensuring analytical reliability, and promoting safer therapeutic outcomes across the pharmaceutical sector. Beyond her research outputs, she remains engaged in scientific dialogue through collaborative networks, co-authored studies, and participation in academic platforms aimed at advancing analytical science. Her contributions hold societal relevance by supporting the development of robust analytical frameworks that enhance the quality, safety, and consistency of pharmaceutical products. Driven by a commitment to scientific integrity and continuous innovation, Dr. Jadon continues to explore emerging analytical challenges while expanding the methodological landscape of pharmaceutical research, demonstrating promise as a dedicated and impactful early-career scientist.

Profiles : Google Scholar | Scopus | ResearchGate

Featured Publications

1. Dahiya, R., Dahiya, S., Fuloria, N. K., Kumar, S., Mourya, R., Chennupati, S. V., et al. (2020). Natural bioactive thiazole-based peptides from marine resources: Structural and pharmacological aspects. Marine Drugs, 18(6), 329.

2. Joshi, S. K., Bhadauria, R. S., & Diwaker, A. K. (2012). Introduction to neoplasm: Tumor classification – A review article. International Journal of Advanced Research in Pharmaceutical & Bio Sciences, 22.

3. Jadon, G., & Kumawat, L. (2011). Synthesis, spectral and biological evaluation of some phenyl acetic acid hydrazone derivatives. International Journal of Pharmaceutical Sciences and Research, 2(10), 2572.

4. Gunjan, J., & Kumawat, L. (2011). Synthesis, spectral and biological evaluation of some hydrazone derivatives. International Journal of Pharmaceutical Sciences and Research, 2(9), 2408–2412.

5. Gunjan, J., Rahul, N., Divya, S., Praveen, K. S., & Diwaker, K. A. (2012). Antioxidant activity of various parts of Punica granatum: A review. Journal of Drug Delivery & Therapeutics, 2, 138–141.

Gunjan Jadon’s work advances analytical chemistry and pharmaceutical quality assurance by developing robust, regulatory-aligned methods that improve drug safety and evaluation. Her research contributes to more reliable therapeutic quality control, supporting innovation, precision, and societal well-being across the pharmaceutical sector.

Shraddha Yadav | Green Chemistry | Women Researcher Award

Published on by Chemical Scientist

Dr. Shraddha Yadav | Green Chemistry | Women Researcher Award

Postdoctoral Fellow |Indian Institute of Technology Bombay | India

Dr. Shraddha Yadav is a distinguished researcher known for her impactful work in environmental catalysis, electrochemical remediation, and sustainable materials engineering. With 21 publications, 263 citations, and an h-index of 8, her research demonstrates strong scientific productivity and interdisciplinary significance. Her recent studies, published in high-impact journals such as Chemical Engineering Journal and Electrochimica Acta, explore advanced nanostructured catalyst systems, including Fe₃C-infused hydrochar-based cathodes and MIL-53(Fe)-derived Fe₃O₄ MWCNT composites, for the efficient degradation of persistent organic pollutants. By integrating green chemistry, nanomaterial synthesis, and electrochemical process optimization, she contributes to developing sustainable wastewater treatment and pollution control technologies. Her comparative analyses of bio-electro-Fenton and bio-electro-peroxone systems provide key insights into improving catalytic efficiency and environmental compatibility. Through collaborations with more than 25 co-authors from diverse scientific backgrounds, she advances interdisciplinary approaches to address global environmental challenges. Collectively, her work supports the advancement of catalytic and electrochemical pathways for pollutant degradation, aligning with sustainable development goals on clean water, responsible production, and climate action while reinforcing the role of scientific innovation in promoting a cleaner, greener future.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

Featured Publications

Limin Gu | Medicinal Chemistry | Best Research Article Award

Published on by Chemical Scientist

Prof. Dr. Limin Gu | Medicinal Chemistry | Best Research Article Award

Associate Professor | Hebei University of Science and Technology | China

Prof. Dr. Limin Gu is a distinguished Associate Professor and a leading researcher in the field of flame retardant materials and materials science and engineering. She has made significant contributions to advancing sustainable flame-retardant technologies through her work at the College of Chemical and Pharmaceutical Engineering, Hebei University of Science & Technology, and as an active member of the Research Center for Chemical Safety & Security and Verification Technology. Her research focuses on intrinsically flame-retardant polymer synthesis, bio-based halogen-free flame retardants, graphene functionalization, and computer vision-assisted chemical analysis. With strong expertise in analytical techniques such as GC, GC-MS, HPLC, TGA, and TG-IR, she effectively integrates experimental and applied approaches in her studies. Prof. Gu has authored more than 20 scientific publications in prestigious journals including European Polymer Journal, Journal of Thermal Analysis and Calorimetry, and Journal of Applied Polymer Science, and has also published a scholarly monograph on flame-retardant waterborne polyurethane materials. Her innovative research has led to over ten awarded Chinese patents related to bio-based flame retardants, phosphonium compounds, and multifunctional polymeric materials, highlighting her dedication to developing eco-friendly and high-performance flame-retardant systems. Recognized for her scientific excellence and contributions to sustainable materials development, Prof. Gu continues to influence the advancement of green chemistry and polymer innovation. Her growing academic impact is demonstrated by 227 citations, 17 documents, and an h-index of 8, reflecting her emerging leadership and meaningful contributions to the global materials science community.

Profiles : Scopus | ORCID | ResearchGate

Featured Publications

Gu, L., Shi, Y., Liu, W., Zhang, L., & Ge, Y. (2025). Synthesis and characterization of the hemicellulose-based “three sources into one” intumescent flame retardant and its modification on cellulose. Journal of Thermal Analysis and Calorimetry, 150(12), 9105-9119.

Sabyasachi Sarkar | Bioinorganic Chemistry | Best Researcher Award

Published on by Chemical Scientist

Prof. Dr. Sabyasachi Sarkar | Bioinorganic Chemistry | Best Researcher Award 

Honorary Distinguished Professor | Ramakrishna Mission Vidyamandira | India

Prof. Dr. Sabyasachi Sarkar is a distinguished chemist whose pioneering work bridges fundamental and applied research, combining enzymatic and nanocarbon innovations to create transformative solutions for science and society. He has led and contributed to advanced research in bioinorganic chemistry, catalysis, and nanomaterial systems, with a focus on enzyme-inspired catalysis, sustainable chemical processes, and nanocarbon-based energy conversion. His interdisciplinary research integrates biochemical principles with material science, resulting in significant advancements in metalloenzyme modeling, biomimetic catalyst development, and functional nanomaterials. Prof. Sarkar’s contributions are further exemplified by multiple groundbreaking patents in drug delivery, ambient energy conversion, and catalytic ammonia synthesis, demonstrating both innovation and real-world applicability. His academic influence extends through the training and mentoring of scientists, fostering collaborations across chemistry, biology, and materials science. Prof. Sarkar has received numerous honors and recognitions for his excellence in research and education, reflecting his role as a global leader in advancing sustainable chemistry. His scholarly impact is evident in his 6,444 citations, 229 documents, and an h-index of 39, underscoring the enduring significance and reach of his work in chemical sciences.

Profiles : Google Scholar | Scopus | ORCID | ResearchGate | LinkedIn

 

Featured Publications

Müller, A., Sarkar, S., Shah, S. Q. N., Bögge, H., Schmidtmann, M., & Sarkar, S., et al. (1999). Archimedean synthesis and magic numbers: “Sizing” giant molybdenum‐oxide‐based molecular spheres of the keplerate type. Angewandte Chemie International Edition, 38(21), 3238–3241. Cited by: 503.

Tripathi, S., Sonkar, S. K., & Sarkar, S. (2011). Growth stimulation of gram (Cicer arietinum) plant by water soluble carbon nanotubes. Nanoscale, 3(3), 1176–1181. Cited by: 358.

Goswami, S., Das, S., Aich, K., Pakhira, B., Panja, S., Mukherjee, S. K., & Sarkar, S. (2013). A chemodosimeter for the ratiometric detection of hydrazine based on return of ESIPT and its application in live-cell imaging. Organic Letters, 15(21), 5412–5415. Cited by: 263.

Das, S. K., Chaudhury, P. K., Biswas, D., & Sarkar, S. (1994). Modeling for the active site of sulfite oxidase: Synthesis, characterization, and reactivity of [MoVIO₂(mnt)₂]²⁻ (mnt²⁻ = 1,2-dicyanoethylenedithiolate). Journal of the American Chemical Society, 116(20), 9061–9070. Cited by: 217.

Tripathi, S., & Sarkar, S. (2015). Influence of water soluble carbon dots on the growth of wheat plant. Applied Nanoscience, 5(5), 609–616. Cited by: 200.

Moussa Ouakki | Electrochemistry | Best Researcher Award

Published on by Chemical Scientist

Prof. Moussa Ouakki | Electrochemistry | Best Researcher Award

Ibn Tofail University| Morocco

Prof. Moussa Ouakki is a distinguished Moroccan chemist and academic scholar serving as Maître de Conférence en Chimie at the École Nationale Supérieure de Chimie, Université Ibn Tofaïl, Kénitra, Maroc. He holds a doctorate in Fundamental and Applied Chemistry with a specialization in the valorization of imidazole compounds for corrosion inhibition of steel in acidic media through theoretical, electrochemical, and spectroscopic studies. His academic background also includes advanced training in physicochemical materials, organic and environmental chemistry, and life sciences. In addition, he has pursued professional development in chemical education, patent systems, and chemical safety in collaboration with the Organisation for the Prohibition of Chemical Weapons (OPCW). Throughout his academic career, Prof. Ouakki has contributed extensively to teaching, research supervision, and curriculum design across undergraduate, engineering, and doctoral programs. His teaching expertise spans electrochemical kinetics, materials science, corrosion mechanisms, and electrolyte chemistry. His research interests focus on corrosion inhibition, green chemistry, electrochemical analysis, materials development, and theoretical modeling of corrosion systems. His research skills include density functional theory (DFT), electrochemical impedance spectroscopy, electrodeposition, dielectric characterization, and molecular dynamics simulations. He has co-supervised several doctoral candidates, published more than a hundred international research papers, contributed multiple book chapters, and secured a patent for novel imidazole-based corrosion inhibitors. As a respected member of editorial boards and a reviewer for leading scientific journals, Prof. Ouakki continues to make remarkable contributions to advancing sustainable chemistry and materials protection. His academic impact is further reflected in his growing recognition with 3,836 citations, 125 documents, and an h-index of 41.

Profiles: Google Scholar | Scopus | ORCID

Featured Publications

Ouakki, M., Galai, M., Rbaa, M., Abousalem, A. S., Lakhrissi, B., Rifi, E. H., & Ebn Touhami, M. (2019). Quantum chemical and experimental evaluation of the inhibitory action of two imidazole derivatives on mild steel corrosion in sulphuric acid medium. Heliyon, 5(11), e02716. Cited by: 147

Rbaa, M., Ouakki, M., Galai, M., Berisha, A., Lakhrissi, B., Jama, C., Warad, I., & Touhami, M. E. (2020). Simple preparation and characterization of novel 8-hydroxyquinoline derivatives as effective acid corrosion inhibitor for mild steel: Experimental and theoretical studies. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 602, 125094. Cited by: 144

Ouakki, M., Galai, M., Rbaa, M., Abousalem, A. S., Lakhrissi, B., Touhami, M. E., & Cherkaoui, M. (2020). Electrochemical, thermodynamic and theoretical studies of some imidazole derivatives compounds as acid corrosion inhibitors for mild steel. Journal of Molecular Liquids, 319, 114063. Cited by: 140

Ouakki, M., Galai, M., & Cherkaoui, M. (2022). Imidazole derivatives as efficient and potential class of corrosion inhibitors for metals and alloys in aqueous electrolytes: A review. Journal of Molecular Liquids, 345, 117815. Cited by: 123

Oubaaqa, M., Ouakki, M., Rbaa, M., Abousalem, A. S., Maatallah, M., Benhiba, F., & Touhami, M. E. (2021). Insight into the corrosion inhibition of new amino acids as efficient inhibitors for mild steel in HCl solution: Experimental studies and theoretical calculations. Journal of Molecular Liquids, 334, 116520.

 

Nezar H Khdary | Organic Chemistry | Best Researcher Award

Published on by Chemical Scientist

Prof. Dr. Nezar H Khdary | Organic Chemistry | Best Researcher Award

Research Professor | King Abdulaziz City for Science and Technology | Saudi Arabia

Prof. Dr. Nezar H. Khdary is a distinguished Saudi scientist at the King Abdulaziz City for Science and Technology (KACST), Riyadh, where he serves as a senior researcher and expert in nanotechnology, analytical chemistry, and environmental science. He earned his Ph.D. from the University of Southampton, UK , specializing in Silica Nano-Scavengers for the Determination of Environmental Pollutants. His academic journey also includes professional certification as a Public Health Consultant from the Saudi Commission for Health Specialties and visiting research appointments at Northwestern University and the University of Central Florida. Dr. Khdary possesses a broad interdisciplinary expertise encompassing nanomaterials, photocatalysis, green chemistry, CO₂ capture and conversion, hydrogen evolution, and public health research. He has undergone advanced professional training in over twenty international courses and workshops, including those from Duke University, Johns Hopkins University, the University of Michigan, and KAUST, covering topics from climate change and environmental health to advanced microscopy, data analytics, and intellectual property. His prolific research output spans more than 45 publications in high-impact journals such as Catalysts, RSC Advances, Nanomaterials, Sustainability, and Journal of Molecular Liquids, contributing significantly to the fields of nanocatalysis, photoreduction, and sustainable energy conversion. Dr. Khdary’s extensive technical proficiency includes advanced analytical techniques such as GC-MS, LC-MS, XRD, FE-SEM, UV-Vis, BET surface area analysis, and potentiostat methods. Throughout his career, he has demonstrated leadership in scientific innovation and mentoring, earning recognition through national and international collaborations aimed at addressing environmental and energy challenges. His contributions reflect a deep commitment to advancing sustainable technologies and public health. Dr. Khdary’s academic impact is further reflected in his growing recognition with 905 citations, 45 documents, and an h-index of 18.

Profiles: Google scholar | scopus | ORCID |ReasearchGate | LinkedIn

Featured Publications

1. Alsarhan, L. M., Alayyar, A. S., Alqahtani, N. B., & Khdary, N. H. (2021). Circular carbon economy (CCE): A way to invest CO₂ and protect the environment, a review. Sustainability, 13(21), 11625. Cited by: 118

2. Khdary, N. H., Alayyar, A. S., Alsarhan, L. M., Alshihri, S., & Mokhtar, M. (2022). Metal oxides as catalyst/supporter for CO₂ capture and conversion: A review. Catalysts, 12(3), 300. Cited by: 103

3. Khdary, N. H., Almuarqab, B. T., & El Enany, G. (2023). Nanoparticle-embedded polymers and their applications: A review. Membranes, 13(5), 537. Cited by: 81

4. Khdary, N. H., Abdesalam, M. E., & El Enany, G. E. L. (2014). Mesoporous polyaniline films for high performance supercapacitors. Journal of The Electrochemical Society, 161(9), G63–G68. Cited by: 79

5. Howard, A. G., & Khdary, N. H. (2007). Spray synthesis of monodisperse sub-micron spherical silica particles. Materials Letters, 61(8–9), 1951–1954. Cited by: 53