Assist. Prof. Dr. Kristina Demirhan | Radiation chemistry | Best Researcher Award

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Assist. Prof. Dr. Kristina Demirhan | Radiation chemistry | Best Researcher Award

Assist. Prof. Dr. Kristina Demirhan | Radiation chemistry | Senior Research Associate, Assistant Professor at University of Novi Sad, Faculty of Sciences, Department of Physics , Serbia

Dr. Kristina Demirhan is a nuclear physicist specializing in gamma spectrometry, radioecology, radiation protection, and cosmic-ray studies. She completed her Ph.D. in Nuclear Physics in 2015 with a perfect GPA of 10.00. she has been affiliated with the Department of Physics, Faculty of Sciences, University of Novi Sad, progressing from Research Associate to Senior Research Associate. She has led multiple international projects in cosmic-ray imaging and nuclear technology applications. With 45 journal publications, six book chapters, and over 50 conference contributions, she has significantly contributed to nuclear physics. She is an expert in Monte Carlo simulations, muon tomography, and rare nuclear events. She also serves as the Head of the Accredited Laboratory for Gamma Spectrometer Calibration. Her work has earned her 331 citations and an h-index of 11. She is fluent in English and actively collaborates on international scientific initiatives.

Professional Profile :         

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Summary of Suitability for Award:

Dr. Kristina Demirhan is an exceptional candidate for the Best Researcher Award, given her outstanding contributions to nuclear physics. With a Ph.D. completed in 2015 with a perfect GPA of 10.00, she has demonstrated academic excellence and research prowess. Her expertise spans nuclear physics, gamma spectrometry, cosmic-ray studies, and radiation protection, with a strong emphasis on Monte Carlo simulations, muon tomography, and rare nuclear events. Dr. Kristina Demirhan’s distinguished research achievements, leadership in international collaborations, and pioneering contributions to nuclear physics make her a highly suitable candidate for the a “Best Researcher Award”. Her work has significantly advanced nuclear imaging and cosmic-ray detection techniques, gaining international recognition. Her ability to integrate fundamental nuclear science with applied technologies in radiation protection and environmental monitoring further establishes her as a leading researcher in her field. Recognizing her with this award would honor her significant scientific contributions and inspire further advancements in nuclear research.

🎓Education:

Dr. Kristina Demirhan enrolled in Ph.D. studies in Nuclear Physics in 2011 at the Department of Physics, Faculty of Sciences, University of Novi Sad. In 2012, she received a prestigious scholarship from the Ministry of Education and Science for outstanding doctoral students. Her Ph.D. thesis, “Changes of Nuclear Spectra under the Influence of Cosmic Radiation,” was defended in 2015, and she graduated with a perfect GPA of 10.00. During her doctoral studies, she specialized in gamma spectrometry, radiation protection, and Monte Carlo simulations. She has also completed advanced training in nuclear instrumentation and cosmic-ray detection techniques. Her academic journey has equipped her with expertise in rare nuclear events, muon tomography, and radioecology, forming a strong foundation for her subsequent research and professional career.

🏢Work Experience:

Dr. Demirhan has been employed at the Department of Physics, Faculty of Sciences, University of Novi Sad, since 2012. She was appointed Research Associate in 2016, Assistant Professor in 2020, and Senior Research Associate in 2021. She has led multiple international research projects, including “Imaging Techniques with Cosmic-Ray Muons” (2017–2019) and “Imaging via Detection of Cosmic Muon Induced Secondary Particles” (2021–2023) under the Hungarian-Serbian Bilateral Science and Technology Cooperation Programme. She also coordinated the VoBaNISTA and ELECTRA projects within the Interreg-IPA Hungary–Serbia program. She is a key member of the Accredited Laboratory for Radioactivity and Dose Measurements and heads the Accredited Laboratory for Gamma Spectrometer Calibration. Additionally, she teaches “Applications of Nuclear Technology” and “Fundamental Interactions” at the master’s level.

🏅Awards: 

Dr. Demirhan was awarded a prestigious Ph.D. scholarship for outstanding students by the Ministry of Education and Science in 2012. She has led and coordinated multiple international scientific projects, gaining recognition for her contributions to nuclear imaging and cosmic-ray studies. She has delivered a keynote lecture at an international conference and contributed six book chapters to international monographs. Her research publications have received 331 citations, with an h-index of 11 (Scopus, March 2025). Her pioneering work in gamma spectrometry and Monte Carlo simulations has been acknowledged in nuclear physics and radiation protection communities. Additionally, she has received institutional recognition for her leadership in accredited laboratories for gamma spectrometry calibration and radiation dose measurements.

🔬Research Focus:

Dr. Kristina Demirhan’s research focuses on nuclear physics, gamma spectrometry, cosmic-ray studies, and radiation protection. She specializes in Monte Carlo simulations, muon tomography, and rare nuclear events. Her work includes developing imaging techniques using cosmic-ray muons and assessing environmental radioactivity. She has contributed to high-precision gamma spectrometry and radiation measurement methodologies. Her studies explore the impact of cosmic radiation on nuclear spectra and the application of nuclear technology in environmental monitoring. She actively integrates nuclear instrumentation with astrophysical and geophysical applications. She also works on international projects advancing nuclear imaging and secondary particle detection.

Publication Top Notes:

Natural Radioactivity and Technological Properties of Kaolinized Granite from the Motajica Mine, Bosnia and Herzegovina

Low-Level Gamma Ray Counting on Environmental Samples

Citations: 3

Corrections of HPGe Detector Efficiency Curve Due to True Coincidence Summing by Program EFFTRAN and by Monte Carlo Simulations

Study of Hanging Valley in Loess-Paleosoil Sediments with Soil Erosion Assessment Using Nuclear and Erosion Potential Methods

Time Characterization of Cosmic-Ray Induced Events in HPGe Detector by Monte Carlo Simulations

Application of <sup>90</sup>Sr for Industrial Purposes and Dose Assessment

Deposition of <sup>137</sup>Cs and Precipitation Distribution in Vojvodina, Northern Serbia after the Chernobyl Accident

Imaging by Muons and Their Induced Secondary Particles – A Novel Technique

Indoor Radon and Thoron Study and Assessment of Geogenic Radon Potential

Assoc. Prof. Dr. Musa TÜRKMEN | Biochemistry | Best Researcher Award

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Assoc. Prof. Dr. Musa TÜRKMEN | Biochemistry | Best Researcher Award

Assoc. Prof. Dr. Musa TÜRKMEN | Biochemistry | Hatay Mustafa Kemal University, Turkey

Dr. Musa Türkmen is an Associate Professor at Hatay Mustafa Kemal University’s Faculty of Agriculture, specializing in medicinal plants and essential oils. His research focuses on the chemical composition and biological activities of essential oils, particularly their antifungal and antioxidant properties. Dr. Türkmen has contributed significantly to the field through numerous publications and active participation in both national and international research projects. His expertise encompasses gas chromatography–mass spectrometry (GC-MS), herbs, chromatography, antioxidant activity, bioactivity, antibacterial activity, biological activities, Soxhlet extraction, and plants.

Professional Profile :         

Scopus 

Summary of Suitability for Award:

Dr. Musa Türkmen is highly suitable for the “Best Researcher Award” due to his outstanding contributions in the field of medicinal plants, essential oils, and agricultural sciences. His research is impactful, focusing on the chemical composition, bioactivity, and agricultural applications of essential oils, which have significant implications for sustainable agriculture, disease management, and human health. Dr. Musa Türkmen’s remarkable research productivity, interdisciplinary impact, and scientific leadership make him an excellent candidate for the “Best Researcher Award”. His contributions have not only advanced essential oil research but also provided practical solutions for sustainable agriculture and plant disease management. His dedication to innovative and impactful research strongly supports his nomination for this prestigious honor.

🎓Education:

Dr. Türkmen completed his Bachelor’s degree in Plant Protection at Kahramanmaraş Sütçü İmam University in 2013. He earned his Master’s degree in Arable Crops from Mustafa Kemal University in 2015, with a thesis on the antifungal efficacy of essential oil mixtures obtained by different methods. In 2019, he obtained his Ph.D. in Arable Crops from Hatay Mustafa Kemal University, focusing his thesis on determining the in vitro and in vivo antifungal efficacy of essential oil microemulsions against Sclerotinia sclerotiorum, the causal agent of white mold disease.

🏢Work Experience:

Dr. Türkmen began his academic career as a Research Assistant at Hatay Mustafa Kemal University’s Faculty of Agriculture in 2016. He was promoted to Assistant Professor in 2020 and Associate Professor in 2022. In addition to his academic roles, he has held administrative positions, including Vice Dean of the Faculty of Agriculture (2021-2022), Deputy Head of the Department of Arable Crops (since 2023), and Director of the Kırıkhan Vocational School (since 2023).

🏅Awards: 

Dr. Türkmen has received several accolades for his contributions to science, including the Young Scientist Fellowship Award from the International Federation of Essential Oils and Aroma Trade (IFEAT) in 2017 and 2018. He was also honored with the TÜBİTAK Türkiye Adresli Uluslararası Bilimsel Yayınları Teşvik (UBYT) award in 2020. Additionally, he received appreciation certificates in 2022 for his outstanding work.

🔬Research Focus:

Dr. Türkmen’s research centers on the study of medicinal plants and essential oils, with a particular emphasis on their chemical compositions and biological activities. He employs techniques such as gas chromatography–mass spectrometry (GC-MS) to analyze essential oil constituents and investigates their potential antifungal, antibacterial, and antioxidant properties. His work aims to explore the applications of these natural compounds in agriculture and medicine.

Publication Top Notes:

Title: Effects of Different Nitrogen and Phosphorus Doses on the Growth, Yield and Yield Components of Black Cumin (Nigella sativa L.)

Title: Combining non-destructive devices and multivariate analysis as a tool to quantify the fatty acid profiles of linseed genotypes

Citations: 2

Title: Phytochemical Profiling and In Vitro Antioxidant, Antimicrobial, Cytotoxicity Effects of Some Glycyrrhiza Species from Turkey

Citations: 1

 

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

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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 :         

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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”

 

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

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Dr. SHEKHAR RAPARTHI | Analytical Chemistry | Best Researcher Award

Dr. SHEKHAR RAPARTHI | Analytical Chemistry | SCIENTIFIC OFFICER/H at NATIONAL CENTER FOR COMPOSITIONAL CHARACTERISATION OF MATERIALS,  India

Shekhar Raparthi is a Scientific Officer / H at the National Centre for Compositional Characterisation of Materials (NCCCM), BARC, Hyderabad. With over three decades of expertise in analytical chemistry, he specializes in trace and ultra-trace characterization of metals, alloys, and high-purity materials. His pioneering work in glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry has significantly advanced compositional analysis. Holding a Ph.D. in Chemistry from JNTU, Hyderabad (2008), he has published extensively in reputed international journals and served as a peer reviewer. Currently leading the ultra-trace analysis section at NCCCM since 2023, he is an esteemed member of India Society for Mass Spectrometry (ISMAS) and Indian Society of Analytical Science (ISAS). His contributions to spectrometric techniques have practical applications in industrial and nuclear material characterization, making him a respected figure in analytical and green chemistry research.

Professional Profile :         

Scopus  

Summary of Suitability for Award:

Dr. Shekhar Raparthi is a highly accomplished researcher specializing in trace and ultra-trace characterization of materials using mass and spectrometric techniques. With over 32 publications in high-impact journals, an h-index of 14, and 631 citations, he has made significant contributions to analytical chemistry. His pioneering research includes the development of infrared spectroscopic methods, glow discharge quadrupole mass spectrometry (GD-QMS), and novel electrolyte cathode discharge atomic emission spectrometric sources. These innovations have advanced material characterization techniques, benefiting the scientific community and industries dealing with high-purity materials, metals, and alloys. Dr. Raparthi’s extensive research contributions, innovative methodologies, and commitment to advancing analytical chemistry make him an ideal candidate for the “Best Researcher Award.” His work has been recognized through numerous international publications, and his role as the head of the ultra-trace analysis section at NCCCM, BARC, further solidifies his impact in the field.

🎓Education:

Shekhar Raparthi pursued his M.Sc. in Chemistry from the University of Hyderabad in 1993, where he developed a strong foundation in analytical chemistry. Following this, he underwent a one-year orientation program at BARC in 1994, gaining specialized training in advanced compositional characterization techniques. His academic journey culminated in a Ph.D. in Chemistry from Jawaharlal Nehru Technological University (JNTU), Hyderabad, in 2008. His doctoral research focused on the development of advanced mass spectrometric methodologies for the ultra-trace analysis of metals and high-purity materials. Over the years, he has continuously expanded his expertise through research, peer-reviewed publications, and participation in international analytical chemistry conferences. His educational background has been instrumental in his ability to innovate in trace and ultra-trace analysis techniques, making significant contributions to the field of analytical chemistry.

🏢Work Experience:

Shekhar Raparthi began his professional career in 1994 as a Scientific Officer/C at NCCCM, BARC, Hyderabad, specializing in the compositional characterization of various materials. Over the past 30 years, he has developed novel analytical methodologies for metals, alloys, and high-purity materials using mass spectrometric and spectroscopic techniques. His expertise includes glow discharge quadrupole mass spectrometry and electrolyte cathode discharge atomic emission spectrometry, contributing to advancements in trace and ultra-trace analysis. His work has been widely recognized, leading to 32 publications in reputed international journals. Since 2023, he has been heading the ultra-trace analysis section at NCCCM, overseeing critical research in compositional characterization. He is also an active peer reviewer for international journals. With extensive experience in spectrometric techniques, Shekhar Raparthi plays a key role in material characterization for nuclear, industrial, and high-tech applications.

🏅Awards: 

Shekhar Raparthi has received several accolades for his significant contributions to analytical chemistry and mass spectrometry. His infrared spectroscopic method for oxygen quantification in TiCl₄ was widely appreciated in the titanium industry, earning him recognition in the field. His research on glow discharge quadrupole mass spectrometry and matrix volatilization methodologies for ultra-trace characterization of high-purity germanium has been published in top international journals, including Analytical Chemistry. His expertise in trace element analysis has made him a valuable asset to BARC and the Indian scientific community. As a distinguished member of ISMAS and ISAS, he actively contributes to the advancement of analytical sciences in India. While he has not listed specific awards, his impactful research, numerous peer-reviewed publications, and leadership in ultra-trace analysis solidify his reputation as a leading scientist in compositional characterization.

🔬Research Focus:

Shekhar Raparthi’s research revolves around trace and ultra-trace characterization of materials using advanced mass spectrometric and spectroscopic techniques. His work plays a crucial role in ensuring the purity and compositional accuracy of metals, alloys, and high-purity materials. He has pioneered glow discharge quadrupole mass spectrometry (GD-QMS) for detecting impurities at ultra-trace levels. Additionally, his development of matrix volatilization methodologies has enhanced the characterization of high-purity germanium, a material critical in semiconductor and radiation detection applications. His innovations in electrolyte cathode discharge atomic emission spectrometry (ECD-AES) have improved the sensitivity and precision of trace element analysis. His research significantly contributes to nuclear, industrial, and advanced material applications, ensuring high accuracy in material compositional studies. As the head of the ultra-trace analysis section at NCCCM, his expertise in **

Publication Top Notes:

In-situ Ti–Ir and ammonium thiocyanate modifiers for improvement of sensitivity of Sc to sub parts per billion levels and its accurate quantification in coal fly ash and red mud by GFAAS

Hydrophobicity induced graphene oxide based dispersive micro solid phase extraction of strontium from seawater and groundwater prior to GFAAS determination

Direct determination of ultra-trace sodium in reactor secondary coolant waters and other waters by electrolyte cathode discharge atomic emission spectrometry

Citation Count: 1

 

Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Green Chemistry Award

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Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Green Chemistry Award

Assoc. Prof. Dr. Yue-Jin Liu | Organic Chemistry | Hubei University ,China

Dr. Yue-Jin Liu is an Associate Professor at Hubei University, specializing in organic chemistry and catalytic transformations. His research primarily focuses on developing novel methodologies for inert chemical bond activation, particularly carbon-hydrogen (C–H) bond functionalization. Dr. Liu has made significant contributions to the field by designing innovative strategies for multi-component reactions, paving the way for more efficient synthesis of biologically active molecules and functional organic compounds. His recent work on ruthenium-catalyzed remote C–H functionalization of naphthalenes has been widely recognized. Dr. Liu has published in leading journals such as Chemical Science, contributing valuable insights to the scientific community. Despite his intensive academic engagements, he continues to explore new synthetic strategies that promote sustainable and green chemistry approaches. Dr. Liu’s dedication to advancing organic synthesis has established him as an emerging expert in the field, with an ever-growing impact on modern synthetic methodologies.

Professional Profile :         

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Summary of Suitability for Award:

Dr. Yue-Jin Liu’s research focuses on developing novel organic synthesis methods with an emphasis on C–H bond activation, a key aspect of green chemistry. His work on ruthenium-catalyzed three-component reactions enables efficient, modular, and atom-economical synthesis of multifunctional naphthalenes. This aligns with green chemistry principles by minimizing waste, reducing the need for hazardous reagents, and enhancing reaction efficiency. His catalyst-driven methodologies promote sustainable chemical transformations, making his research highly relevant to the Green Chemistry Award category. Dr. Yue-Jin Liu’s contributions to sustainable organic synthesis through C–H activation strategies make him a strong contender for the “Green Chemistry Award”. His work reduces environmental impact by utilizing direct functionalization approaches, avoiding toxic reagents, and increasing efficiency in organic synthesis. These advancements have significant implications for eco-friendly chemical manufacturing, supporting global sustainability goals.

🎓Education:

Dr. Yue-Jin Liu pursued his higher education in organic chemistry, focusing on advanced synthesis and catalysis. He obtained his Bachelor’s, Master’s, and Ph.D. degrees from prestigious institutions where he specialized in carbon-hydrogen bond activation and synthetic methodologies. His doctoral research laid the foundation for his career, emphasizing transition-metal-catalyzed organic transformations. During his academic journey, Dr. Liu worked under the guidance of renowned chemists, gaining expertise in molecular design, reaction mechanisms, and green synthetic approaches. Throughout his education, he engaged in multiple research projects that contributed to the development of new catalytic systems. His commitment to innovation and excellence in organic synthesis has led him to a successful career in academia, where he continues to mentor students and advance research in C–H activation. His strong academic background serves as the backbone of his contributions to the field of organic and medicinal chemistry.

🏢Work Experience:

Dr. Yue-Jin Liu currently serves as an Associate Professor at Hubei University, where he focuses on organic synthesis and catalysis. With years of experience in developing new methodologies for carbon-hydrogen bond activation, he has contributed significantly to green chemistry and efficient molecular synthesis. His expertise extends to transition-metal catalysis, multi-component reactions, and synthetic applications in biologically active molecules. Dr. Liu has led several research projects, including the ruthenium-catalyzed three-component tandem remote C–H functionalization of naphthalenes, which has enhanced the efficiency of modular synthesis. Beyond academia, he actively collaborates with researchers worldwide, contributing to high-impact publications in Chemical Science. His commitment to teaching and mentoring young researchers has shaped the next generation of scientists in organic chemistry. Dr. Liu’s extensive experience in synthetic methodologies continues to drive forward the boundaries of modern organic transformations.

🏅Awards: 

Dr. Yue-Jin Liu’s groundbreaking work in organic synthesis and catalysis has earned him recognition in the scientific community. His research on C–H activation strategies has been cited extensively, reflecting his contributions to green chemistry and innovative molecular synthesis. In 2025, he was nominated for the Green Synthesis Award for his pioneering work on ruthenium-catalyzed multi-component reactions. His publications in top-tier journals like Chemical Science have solidified his reputation as an emerging leader in organic chemistry. Despite his focus on fundamental research, Dr. Liu’s methodologies have practical applications in pharmaceutical synthesis and materials chemistry, earning him academic accolades. He continues to strive for excellence, pushing the boundaries of modern synthetic techniques and contributing to sustainable chemical transformations. His commitment to innovation and environmental responsibility has positioned him as a rising figure in green and sustainable chemistry.

🔬Research Focus:

Dr. Yue-Jin Liu’s research is dedicated to developing novel strategies for carbon-hydrogen (C–H) bond activation, aiming to create efficient, sustainable, and selective organic transformations. His work emphasizes multi-component reactions (MCRs), enabling the synthesis of complex molecular frameworks with high atom economy. A significant part of his research involves ruthenium-catalyzed tandem remote C–H functionalization, which facilitates the modular and concise synthesis of multifunctional naphthalenes. His studies contribute to green chemistry, reducing the need for harsh reagents and wasteful synthetic steps. Dr. Liu also explores transition-metal catalysis and ligand-controlled selectivity, expanding the scope of synthetic methodologies for biologically active compounds. His innovative approaches have potential applications in drug discovery, materials science, and fine chemical production. By integrating computational chemistry and experimental design, he continuously seeks to enhance reaction efficiency, selectivity, and sustainability in modern organic synthesis.

Publication Top Notes:

Cobalt(II)-Catalyzed Selective C2–H Heck Reaction of Native (N–H) Indoles Enabled by Salicylaldehyde Ligand

Salicylaldehyde-Enabled Co(II)-Catalyzed Oxidative C–H Alkenylation of Indoles with Olefins

Ruthenium-Catalyzed Three-Component Tandem Remote C–H Functionalization of Naphthalenes: Modular and Concise Synthesis of Multifunctional Naphthalenes

Mild C−H Alkoxylation of Aromatic Amides Catalyzed by Salicylaldehyde‐Co(II) Complexes

Cobalt/Salicylaldehyde-Enabled C–H Alkoxylation of Benzamides with Secondary Alcohols under Solvothermal Conditions

Salicylaldehyde-Cobalt(II)-Catalyzed C–H Alkoxylation of Indoles with Secondary Alcohols

Selective Synthesis of Sulfonamides and Sulfenamides from Sodium Sulfinates and Amines

Rapid Modular Synthesis of Indole Ethers via Dehydrogenative Cross-Coupling Reaction of Indoles and Alcohols

Remote C5-Selective Functionalization of Naphthalene Enabled by P–Ru–C Bond-Directed δ-Activation

Ru(II)-Catalyzed P(III)-Assisted C8-Alkylation of Naphthphosphines

Ruthenium-Catalyzed Meta-Difluoromethylation of Arene Phosphines Enabled by 1,3-Dione

Salicylaldehyde-Promoted Cobalt-Catalyzed C–H/N–H Annulation of Indolyl Amides with Alkynes: Direct Synthesis of a 5-HT3 Receptor Antagonist Analogue

 

Prof. Shenggang Li | Catalysis | Best Researcher Award

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Prof. Shenggang Li | Catalysis | Best Researcher Award

Prof. Shenggang Li | Catalysis | Professor at Shanghai Advanced Research Institute, Chinese Academy of Sciences China

Professor Shenggang Li is a distinguished computational catalysis researcher at the Shanghai Advanced Research Institute, Chinese Academy of Sciences. He earned his Ph.D. in molecular spectroscopy from the University of Kentucky in 2004 and has since contributed significantly to computational catalysis. His research focuses on the mechanism of oxidative coupling of methane, higher alcohol synthesis, and CO₂ hydrogenation using In₂O₃-based catalysts. With over 190 peer-reviewed publications and 40 conference presentations, his work has been widely recognized. He has led multiple funded projects, including collaborations with Shell Global Solutions and the Natural Science Foundation of China. His computational studies have driven the rational design of catalysts for carbon dioxide and biomass valorization, some of which are being tested at the pilot scale for industrial applications. A member of the Chinese Chemical Society and the American Chemical Society, Prof. Li also serves on the editorial board of Heliyon Chemistry.

Professional Profile :                       

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Summary of Suitability for Award:

Prof. Shenggang Li is a distinguished researcher in computational catalysis with significant contributions to carbon dioxide utilization and heterogeneous catalysis. His research has led to the computer-aided design of high-performance catalysts for CO₂ hydrogenation and biomass valorization, with potential industrial applications. Having published over 180 peer-reviewed papers indexed by SCI and contributed to three book chapters, his impact in the field is evident through a citation index of 47 (Scopus). His collaborations with renowned international scientists and funding from prestigious agencies, including Shell Global Solutions and the Natural Science Foundation of China, further validate his research excellence. He is also an editorial board member of Heliyon Chemistry and an active member of Chinese Chemical Society and American Chemical Society. Prof. Shenggang Li’s exceptional research output, global collaborations, industrial relevance, and pioneering work in computational catalysis make him a highly suitable candidate for the “Best Researcher Award “. His research innovations have direct implications for sustainable energy and green chemistry, aligning with global scientific advancements.

🎓Education:

Shenggang Li obtained his Ph.D. in molecular spectroscopy from the University of Kentucky in 2004. His doctoral research laid a strong foundation for his expertise in computational chemistry and catalysis. Prior to that, he pursued his undergraduate and master’s degrees in chemistry, where he developed a deep understanding of reaction mechanisms and molecular interactions. Throughout his academic journey, he honed skills in quantum chemistry, first-principles simulations, and heterogeneous catalysis. His studies equipped him with a solid theoretical and computational background, enabling him to tackle complex problems in catalysis and reaction engineering. His postdoctoral training at The University of Alabama at Tuscaloosa further refined his research focus, preparing him for a distinguished career in computational catalysis. His academic achievements, combined with strong interdisciplinary knowledge, have allowed him to make pioneering contributions to catalyst design, particularly in CO₂ hydrogenation and methane activation.

🏢Work Experience:

Prof. Shenggang Li has an extensive research career spanning over two decades in computational catalysis. After completing his Ph.D., he worked as a researcher at The University of Alabama at Tuscaloosa, where he collaborated on spectroscopic data interpretation and catalysis studies. He later joined the Shanghai Advanced Research Institute, Chinese Academy of Sciences, where he leads projects in computational catalyst design. His work has focused on CO₂ hydrogenation to methanol, oxidative coupling of methane, and biomass valorization. As a principal investigator, he secured multiple grants from Shell Global Solutions, the National Science Foundation of China, and the Ministry of Science and Technology of China. He has also collaborated with international research groups to advance the understanding of catalytic reaction mechanisms. His 47 Scopus-indexed citations and over 180 SCI-indexed publications highlight his impact in the field. His expertise in computational modeling has driven innovative solutions for sustainable energy applications.

🏅Awards: 

Professor Shenggang Li has received numerous accolades for his pioneering contributions to computational catalysis. He has secured funding from prestigious agencies, including the Natural Science Foundation of China, Ministry of Science and Technology of China, and Shell Global Solutions. His research has been recognized internationally, with invitations to present at over 40 global conferences. His 47 h-index (Scopus) and over 180 SCI-indexed publications underscore the significance of his work in catalysis. As an editorial board member of Heliyon Chemistry, he has contributed to the advancement of chemical research. He is an active member of the Chinese Chemical Society and the American Chemical Society, reflecting his global engagement in the scientific community. His computationally guided catalyst designs have reached the pilot scale, demonstrating industrial viability. His expertise and research excellence position him as a strong candidate for the Best Researcher Award.

🔬Research Focus:

Prof. Shenggang Li specializes in computational catalysis, employing first-principles simulations, density functional theory (DFT), and artificial intelligence to design and optimize catalysts for sustainable chemical processes. His research primarily targets CO₂ hydrogenation to methanol, oxidative coupling of methane, and biomass valorization. His work on In₂O₃-based catalysts has led to significant advancements in CO₂-to-methanol conversion, providing industrially relevant solutions for carbon dioxide utilization. He has also developed bifunctional catalysts for direct CO₂ hydrogenation to gasoline, olefins, aromatics, and higher alcohols, some of which are currently in pilot-scale testing. His computational methodologies assist in the rational design of platinum-tungsten oxide catalysts for biomass conversion, improving efficiency and selectivity. His interdisciplinary approach, integrating quantum chemistry and machine learning, accelerates catalyst discovery and optimization. His innovations contribute to green chemistry, renewable energy, and sustainable industrial practices, making a profound impact on the field of computational catalysis.

Publication Top Notes:

Effects of oxygen vacancy formation energy and Pt doping on the CO2 hydrogenation activity of In2O3 catalysts

Year: 2025

Engineering ZrO2–Ru interface to boost Fischer-Tropsch synthesis to olefins

Citations: 5

Microwave-Assisted Pyrolysis-A New Way for the Sustainable Recycling and Upgrading of Plastic and Biomass: A Review

Citations: 4

Computer-aided design of Pt/In2O3 single-atom catalysts for CO2 hydrogenation to methanol

Citations: 1

Li-promoted C3N4 catalyst for efficient isomerization of glucose into fructose at 50 °C in water

Citations: 3

Mechanism and structure-activity relationship of H2 and CO2 activation at the ZnO/Cu catalyst interface

Citations: 1

Tuning the selectivity of CO2 hydrogenation to alcohols by crystal structure engineering

Citations: 9

CO2-Assisted Dehydrogenation of Propane by Atomically Dispersed Pt on MXenes

Citations: 2

Molten-Salt Electrochemical-Assisted Synthesis of the CeO2-OV@GC Composite-Supported Pt Clusters with a Pt-O-Ce Structure for the Oxygen Reduction Reaction

Citations: 6

Corrigendum to “Understanding surface structures of In2O3 catalysts during CO2 hydrogenation reaction using time-resolved IR, XPS with in situ treatment, and DFT calculations”

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

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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 :                       

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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

 

Prof. Mohammad Gholinejad | Organic Chemistry | Best Researcher Award

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Prof. Mohammad Gholinejad | Organic Chemistry | Best Researcher Award 

Prof. Mohammad Gholinejad | Organic Chemistry | Associate Professor of Chemistry at IASBS, Iran

Dr. Mohammad Gholinejad is an Associate Professor of Organic Chemistry at the Institute for Advanced Studies in Basic Sciences (IASBS), Iran, he specializes in catalysis, organic synthesis, and nanomaterials. He completed his Ph.D. from Shiraz University under the supervision of Prof. Habib Firouzabadi, focusing on palladium, copper, iron, and silver nanoparticles in carbon-carbon and carbon-heteroatom bond formation. He undertook a sabbatical at the University of Alicante, Spain, with Prof. Carmen Najera, working on phosphane-free Suzuki-Miyaura coupling. With an h-index of 36 and over 3,400 citations, Dr. Gholinejad has significantly contributed to the field of homogeneous and heterogeneous catalysis. His expertise extends to TGA, GC, NMR, and XPS techniques. He actively teaches advanced organic chemistry and heterocyclic chemistry, mentoring numerous students. His work bridges fundamental research and practical applications, making him a key figure in modern catalysis.

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Summary of Suitability for Award:

Dr. Mohammad Gholinejad is a highly accomplished researcher in the field of organic chemistry, specializing in catalysis, nanoparticle applications, and green chemistry. With an h-index of 36 and over 3,400 citations, his research contributions have significantly impacted the scientific community. His expertise in palladium, copper, iron, and silver nanoparticles for carbon-carbon and carbon-heteroatom bond formation reactions has led to innovative methodologies that are both efficient and environmentally friendly. He has held a prestigious sabbatical position at the University of Alicante, Spain, and currently serves as an Associate Professor at the Institute for Advanced Studies in Basic Sciences (IASBS). His extensive publication record, leadership in advanced organic chemistry courses, and hands-on experience with instrumental techniques further highlight his research excellence. Given his outstanding research output, impact on organic synthesis, and contributions to sustainable chemistry, Dr. Gholinejad is a highly suitable candidate for the “Best Researcher Award.” His work exemplifies innovation, academic excellence, and real-world application, making him a strong contender for this recognition.

🎓Education:

Dr. Mohammad Gholinejad obtained his Ph.D. in Organic Chemistry from Shiraz University, Iran (2008-2012), where he investigated carbon-carbon and carbon-heteroatom bond formation using metal nanoparticles. His research introduced efficient catalytic systems for environmentally friendly organic transformations. His M.Sc. in Organic Chemistry (2006-2008) at Shiraz University focused on phosphinite ligands in organic synthesis. He earned his B.Sc. in Applied Chemistry from the University of Tabriz (2002-2006). In 2010, Dr. Gholinejad pursued a sabbatical at the University of Alicante, Spain, under Prof. Carmen Najera, working on phosphane-free Suzuki-Miyaura coupling. His academic journey has shaped his expertise in catalytic systems, green chemistry, and ligand design. His research integrates experimental and theoretical chemistry, leading to numerous high-impact publications. His strong analytical background and mastery of spectroscopic techniques have enhanced his contributions to organic synthesis and catalysis, making him a leading researcher in the field.

🏢Work Experience:

Dr. Mohammad Gholinejad is an Associate Professor at IASBS, Iran, where he has been engaged in research and teaching for over a decade. His teaching portfolio includes Advanced Organic Chemistry (Structure and Mechanisms), Organic Reactions and Synthesis, Heterocyclic Chemistry, and New Discussions in Organic Chemistry. His research focuses on designing novel catalytic systems using palladium, copper, and iron nanoparticles for sustainable organic transformations. He has extensive expertise in TGA, GC, NMR, and XPS, essential for analyzing catalytic reactions. During his sabbatical at the University of Alicante, Spain, he collaborated with Prof. Carmen Najera on phosphane-free Suzuki-Miyaura coupling in aqueous media. His work has led to numerous high-impact publications in prestigious journals. He actively supervises M.Sc. and Ph.D. students, contributing to the development of young researchers. His role at IASBS has been instrumental in advancing research on green and heterogeneous catalysis.

🏅Awards: 

Dr. Mohammad Gholinejad has received numerous prestigious awards and honors in recognition of his outstanding contributions to the field of organic chemistry. His work in catalysis and green chemistry has been widely acknowledged, earning him accolades from both national and international scientific communities. He has been recognized for his high-impact publications in reputed journals, reflecting his significant influence in the domain of sustainable chemical methodologies. His sabbatical at the University of Alicante, Spain, is a testament to his global research collaborations and expertise. Additionally, he has been honored with research grants and funding awards, enabling him to advance studies in nanoparticle catalysis and environmentally friendly synthetic processes. As an Associate Professor at the Institute for Advanced Studies in Basic Sciences (IASBS), he has received institutional recognition for his exemplary research, mentorship, and contributions to academic excellence. His achievements establish him as a leading researcher in organic synthesis and catalysis.

🔬Research Focus:

Dr. Mohammad Gholinejad’s research primarily focuses on the development of novel catalytic systems for organic transformations, particularly using palladium, copper, iron, and silver nanoparticles. His work has significantly advanced carbon-carbon and carbon-heteroatom bond formation reactions, leading to more efficient and environmentally sustainable chemical processes. By integrating nanotechnology with catalysis, he has contributed to the design of innovative, recyclable catalytic systems that minimize waste generation and reduce reliance on hazardous reagents. His expertise extends to green chemistry, where he develops eco-friendly methodologies for organic synthesis, emphasizing the use of non-toxic solvents, reusable catalysts, and sustainable reaction conditions. His pioneering research in heterogeneous catalysis has implications for pharmaceuticals, materials science, and industrial chemistry. Additionally, his work on functionalized nanomaterials has potential applications in energy storage and biomedical fields. Through high-impact publications and global collaborations, Dr. Gholinejad continues to drive advancements in synthetic methodologies, enhancing the efficiency and sustainability of modern chemistry.

Publication Top Notes:

Title: Magnetite (Fe₃O₄) Nanoparticles‐Catalyzed Sonogashira–Hagihara Reactions in Ethylene Glycol under Ligand‐Free Conditions
Authors: H. Firouzabadi, N. Iranpoor, M. Gholinejad, J. Hoseini
Citations: 174
Year: 2011

Title: One‐Pot Thioetherification of Aryl Halides Using Thiourea and Alkyl Bromides Catalyzed by Copper (I) Iodide Free from Foul‐Smelling Thiols in Wet Polyethylene Glycol (PEG 200)
Citations: 164

Title: Highly Efficient Three-Component Coupling Reaction Catalyzed by Gold Nanoparticles Supported on Periodic Mesoporous Organosilica with Ionic Liquid Framework
Citations: 154

Title: Palladium Nanoparticles Supported on Agarose as Efficient Catalyst and Bioorganic Ligand for C–C Bond Formation via Solventless Mizoroki–Heck Reaction and Sonogashira–Hagihara Reaction
Citations: 107

Title: Synthesis and Characterization of Magnetic Copper Ferrite Nanoparticles and Their Catalytic Performance in One-Pot Odorless Carbon-Sulfur Bond Formation Reactions
Citations: 98

Title: 2-Aminophenyl Diphenylphosphinite as a New Ligand for Heterogeneous Palladium-Catalyzed Heck–Mizoroki Reactions in Water in the Absence of Any Organic Co-Solvent
Citations: 93

Title: Copper Nanoparticles Supported on Agarose as a Bioorganic and Degradable Polymer for Multicomponent Click Synthesis of 1,2,3-Triazoles under Low Copper Loading in Water
Citations: 89

Title: Nitro Group Reduction and Suzuki Reaction Catalysed by Palladium Supported on Magnetic Nanoparticles Modified with Carbon Quantum Dots Generated from Glycerol and Urea
Citations: 83

Title: Copper Nanoparticles Supported on Starch Microparticles as a Degradable Heterogeneous Catalyst for Three-Component Coupling Synthesis of Propargylamines
Citations: 83

Title: Palladium Nanoparticles Supported on Agarose-Functionalized Magnetic Nanoparticles of Fe₃O₄ as a Recyclable Catalyst for C–C Bond Formation via Suzuki–Miyaura, Heck–Mizoroki Reactions
Citations: 77

Title: Recyclable Palladium-Catalyzed Sonogashira–Hagihara Coupling of Aryl Halides Using 2-Aminophenyl Diphenylphosphinite Ligand in Neat Water under Copper-Free Condition
Citations: 77