Sherzodbek Tashbaev | Ecology | Best Researcher Award

Published on by Chemistry Awards

Assoc. Prof. Dr. Sherzodbek Tashbaev | Ecology | Best Researcher Award

Docent at Andijan State University, Uzbekistan

Sherzodbek Tashbaev is a prominent mathematician from Uzbekistan specializing in non-associative algebras. Currently an Associate Professor at Andijan State University, he earned his Doctorate from the University of Santiago de Compostela, Spain, in 2017 under the supervision of Prof. Bakhrom A. Omirov and Prof. Manuel Ladra. His research explores the structure and classification of Lie and Leibniz algebras, with significant contributions to algebraic geometry and cohomology. He has held positions as a Senior Researcher at the Institute of Microbiology, Academy of Sciences of Uzbekistan, and as a Postdoctoral Research Scientist in Spain. Sherzodbek has participated in several international conferences, contributed to numerous research projects, and published extensively in reputed journals. He is also an active reviewer for high-profile mathematical journals. His achievements reflect a strong commitment to advancing algebraic research and fostering international collaboration in mathematics.

Professional Profile

Scopus

Education 

Sherzodbek Tashbaev began his academic journey at Namangan State University, completing his bachelor’s studies in 2005, and subsequently earned his Bachelor degree officially from Andijan State University in 2007 with a thesis on stability in systems under Prof. A. Miladjanov. He pursued a Master of Science degree at the National University of Uzbekistan, graduating in 2009 under the guidance of Prof. Bakhrom A. Omirov, focusing on the application of Wolfram software to algebraic structures. His academic pinnacle was achieved at the University of Santiago de Compostela, Spain, where he earned his Doctorate in 2017. His Ph.D. thesis, supervised by Prof. Bakhrom A. Omirov and Prof. Manuel Ladra, was titled “Classification of Leibniz algebras with a given nilradical and with some corresponding Lie algebra.” His academic background encompasses strong foundations in both theoretical and computational aspects of algebra, forming the basis of his diverse research interests in non-associative algebras.

Professional Experience 

Sherzodbek Tashbaev’s professional path combines research, teaching, and international collaboration. Since 2020, he has served as Associate Professor at Andijan State University’s Department of Mathematics. Concurrently, he has been a Senior Researcher at the Institute of Microbiology, Academy of Sciences of Uzbekistan, since 2021. Between 2017 and 2019, he worked as a Postdoctoral Research Scientist at the Institute of Mathematics, University of Santiago de Compostela, Spain. Earlier, he held positions as a Scientific Fellow at the Institute of Mathematics and Information Technologies of the Uzbek Academy of Sciences from 2011 to 2015, and as a lecturer at the Institute of Pedagogical Staff Training and Retraining in Andijan from 2010 to 2011. Throughout his career, he has actively engaged in organizing international conferences and participated in significant research projects spanning Spain, Russia, and Uzbekistan. His career reflects a blend of scholarly research, teaching excellence, and cross-border scientific collaboration.

Awards and Honors

Sherzodbek Tashbaev has received multiple honors recognizing his scholarly achievements. Notably, he was awarded the prestigious Mirzo Ulug’bek Scholarship in Uzbekistan during 2006–2007, highlighting his academic potential early in his career. In 2014, he secured a grant to attend the International Congress of Mathematicians (ICM) in Seoul, Korea, underscoring his emerging prominence in the global mathematical community. Further, he became a grantee under the UNESCO-UNITWIN OCW/OER Initiative in 2016, sponsored by the Korean Ministry of Education, reflecting his commitment to educational innovation and international cooperation. Between 2017 and 2019, he was awarded a competitive postdoctoral fellowship at the Institute of Mathematics, University of Santiago de Compostela, Spain, allowing him to contribute significantly to research on non-associative algebras. These awards and honors testify to Sherzodbek’s impactful contributions to mathematics and his recognized role in fostering international scientific networks and collaborations.

Research Interests 

Sherzodbek Tashbaev’s research interests center around advanced topics in algebra, particularly non-associative algebras. His expertise encompasses Lie algebras, Leibniz algebras, associative algebras, and the structural theory underpinning these algebraic systems. He focuses on the classification and properties of these algebras, exploring their cohomology, derivations, and deformations, which are crucial for understanding their internal symmetry and structure. His work often intersects with algebraic geometry, where he investigates geometric and homological invariants related to algebraic structures. Evolution algebras also form part of his interest, linking abstract algebra to applications in biological and physical models. He actively engages in collaborative research projects internationally, particularly in Spain and Russia, contributing to global knowledge on algebraic systems. His extensive publication record in reputed journals demonstrates a commitment to advancing theoretical mathematics while exploring practical applications of algebraic frameworks in broader scientific contexts.

Research Skills 

Sherzodbek Tashbaev possesses comprehensive research skills spanning theoretical and computational mathematics. He excels in the structural analysis of Lie, Leibniz, and associative algebras, employing methods like classification techniques, cohomological analysis, and deformation theory. He is proficient in mathematical modeling and symbolic computation, leveraging tools like Wolfram Mathematica for algebraic exploration and visualization. His ability to connect algebraic theory with geometric and homological methods enables him to contribute significantly to the study of algebraic invariants and central extensions. As a referee for top-tier journals, he demonstrates critical evaluation skills and deep familiarity with current research frontiers. Sherzodbek has also developed strong collaborative skills through participation in international research projects and organizing scientific conferences. His technical proficiency, combined with his capacity to mentor and lead research, positions him as an influential figure in the field of algebra and a valuable contributor to mathematical sciences on a global scale.

Publication Top Notes

  1. Local and 2-local automorphisms of null-filiform and filiform associative algebras.

  2. Local and 2-local automorphisms of solvable Leibniz algebras with abelian and model nilradicals.

  3. Classification of naturally graded nilpotent associative algebras.

  4. A criterion of local derivations on the seven–dimensional simple Malcev algebra.

  5. Local and 2-local automorphisms of some solvable Leibniz algebras.

  6. Central extensions of filiform Zinbiel algebras.

  7. One generated nilpotent Novikov algebras.

  8. Central extensions of filiform associative algebras.

  9. The classification of 5-dimensional complex nilpotent associative algebras.

  10. Rota-type operators on 3-dimensional nilpotent associative algebras.

  11. Some classes of associative nilpotent algebras.

  12. Rota-type operators on null-filiform associative algebras.

  13. Minimal representations of filiform Lie algebras and their application for construction of Leibniz algebras.

  14. The algebraic and geometric classification of nilpotent Novikov algebras.

  15. Leibniz Algebras Constructed by Representations of General Diamond Lie Algebras.

  16. Leibniz Algebras Associated with Representations of the Diamond Lie Algebra.

  17. Leibniz algebras whose semi-simple part is related to sl2.

  18. Leibniz algebras associated with some finite-dimensional representation of Diamond Lie algebra.

  19. Solvable Leibniz algebras with triangular nilradicals.

  20. Naturally graded Zinbiel algebras with nilindex n-3.
































	


	

	






	
	

		


Zhexu Xi | Nanomaterials | Best Paper Award
			

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Dr. Zhexu Xi | Nanomaterials | Best Paper Award


Research assistant at University of Oxford, United Kingdom


Zhexu Xi is a doctoral researcher in Inorganic Chemistry at the University of Oxford, focusing on electrochemical sensors, exosomal capture, and nanomaterial interfaces. He earned his M.Sc. in Nanoscience and Functional Nanomaterials from the University of Bristol and holds a B.Sc. in Chemistry from Xiamen University, China. Throughout his academic journey, he has combined chemistry, nanotechnology, and data science, contributing significantly to electrocatalysis, nanostructure design, and machine learning applications in materials science. His work spans fundamental research and applied projects, such as low-fouling immunomagnetic platforms, quantum dot charge transfer studies, and porous pavement materials for smart cities. Zhexu has authored multiple publications in reputed journals and conferences and serves as an editorial board member and guest editor in nanoscience-focused journals. Recognized with numerous national and international awards in chemistry, physics, and mathematical modeling, he demonstrates a strong interdisciplinary skill set, merging experimental work with computational insights.


Professional Profile


Google Scholar


Scopus


Education 


Zhexu Xi is currently pursuing his D.Phil. in Inorganic Chemistry at the University of Oxford (2020–2024), focusing on electrochemical detection systems, exosomal assays, and nanoscale interface engineering. His research involves designing advanced electrochemical receptor interfaces, low-fouling nanobeads, and microfluidic platforms for sensitive biomolecular detection. Prior to Oxford, he completed his M.Sc. in Nanoscience and Functional Nanomaterials at the University of Bristol (2019–2020) with a GPA of 69.9%, covering nanoscience techniques, functional materials, and extended research projects. Zhexu holds a B.Sc. in Chemistry (by research) from Xiamen University (2015–2019), graduating with a GPA of 87.8%. He also participated in a short-term summer exchange program on self-assembled functional materials at the University of Michigan in 2018. Throughout his education, Zhexu balanced coursework, independent research, and leadership roles in academic and extracurricular activities, cultivating a robust interdisciplinary background spanning chemistry, nanotechnology, and data science.


Professional Experience 


Zhexu Xi has diverse research experience across nanomaterials synthesis, electrochemistry, photophysics, and data-driven materials science. At Oxford, his Ph.D. focuses on immunomagnetic platform development, electrochemical assay optimization, and microfluidic devices for biomolecule detection. He previously researched 2D molybdenum chalcogenides for hydrogen evolution, investigating structure-activity correlations and nanostructure design. At Bristol, he worked on hydrothermal synthesis of MoX₂ assemblies and their electrocatalytic properties. Earlier at Xiamen University, Zhexu explored electron/hole transfer dynamics in semiconductor quantum dots and developed porous concrete materials for water seepage control. His projects span from fundamental chemical synthesis to advanced spectroscopy, machine learning modeling for nanomaterials property prediction, and environmental material applications. Beyond laboratory research, Zhexu served as a founder of the Bioinformatics Club, a conference presenter, and a guest editor for nanoscience journals. His work demonstrates strong skills in experimental design, data analysis, computational modeling, and scientific communication across disciplines.


Awards and Honors


Zhexu Xi has earned numerous honors recognizing his interdisciplinary expertise. Nationally, he received the Excellent Prize in the Wanmen-Cup Physics Contest (2018), and multiple prizes in China’s innovation competitions, including the “Challenge Cup” and National College Student Extracurricular Academic Competitions for both scientific research and mathematical modeling. His project on eco-friendly cellulose-based adhesives was ranked among China’s top 100 public welfare projects. In mathematical modeling and programming, Zhexu earned second prizes in the “Science Innovation Cup” and the Shenzhen Cup Summer Camp. He also excelled in diverse fields, winning first prizes in national English translation and encyclopedia contests. At university level, he secured multiple awards, including the Xiamen University competition for energy-saving solutions. His contributions span from experimental chemistry to data science applications, underlining a commitment to both scientific innovation and effective communication. Zhexu’s broad recognition underscores his leadership, problem-solving, and cross-disciplinary research capabilities.


Research Interests 


Zhexu Xi’s research interests center on the intersection of nanoscience, electrochemistry, and advanced materials design. He focuses on developing electrochemical detection systems for biomedical applications, particularly exosomal and biomarker assays using microfluidic and low-fouling platforms. His work delves deeply into nanostructured electrocatalysts, especially 2D transition metal dichalcogenides, exploring structure–activity relationships to enhance hydrogen evolution reactions. Zhexu is also passionate about quantum dots and their charge transfer dynamics, investigating ultrafast photophysical processes for energy applications. Beyond experimental chemistry, he integrates machine learning into materials science for property prediction, high-throughput screening, and nanostructure optimization. His interests extend to sustainable materials, exemplified by studies on porous pavements for environmental engineering. Zhexu bridges disciplines by combining experimental synthesis, sophisticated spectroscopic techniques, electrochemical analysis, and computational modeling, aiming to design intelligent materials and systems for clean energy, diagnostics, and smart infrastructure applications.


Research Skills 


Zhexu Xi possesses a strong skill set combining experimental and computational methods. Experimentally, he is skilled in nanoparticle synthesis, hydrothermal methods, quantum dot fabrication, surface functionalization, and electrochemical techniques (e.g., voltammetry, impedance spectroscopy). He has expertise in characterizing nanomaterials using spectroscopy (UV-Vis, transient absorption), microscopy, and electrochemical analysis to study reaction kinetics and material interfaces. Zhexu is adept at designing low-fouling surfaces for immunoassays and integrating microfluidic systems for precise biomolecule capture and quantification. Computationally, he employs machine learning models for materials property prediction, data mining, and image-text analysis, handling complex datasets with advanced statistical methods. He is experienced in modeling electron transfer processes and correlating structural parameters with functional performance. Zhexu excels in scientific communication through publications, presentations, and editorial roles. His interdisciplinary skills allow him to navigate complex research challenges spanning chemistry, nanotechnology, bioanalytics, and computational materials science.


Publication Top Notes


    

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    Deep multi-view graph-based network for citywide ride-hailing demand prediction
    

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    Adaptive dual-view wavenet for urban spatial–temporal event prediction
    

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    Surgical repair of annulus defect with biomimetic multilamellar nano/microfibrous scaffold in a porcine model
    

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    Urban hotspot forecasting via automated spatio-temporal information fusion
    

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    Nanostructures Design: the Role of Cocatalysts for Hydrogen and Oxygen Generation in Photocatalytic Water Splitting
    

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    Functional Nanomaterials Design in the Workflow of Building Machine-Learning Models
    

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    Underlying Structure-Activity Correlations of 2D Layered Transition Metal Dichalcogenides-Based Electrocatalysts for Boosted Hydrogen Generation
    

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    Nanostructures of 2D Transition Metal Dichalcogenides for Hydrogen Generation Under Alkaline Conditions: from Theoretical Models to Practical Electrocatalysts
    

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    Spatial modelling and microstructural modulation of porous pavement materials for seepage control in smart cities
    

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    How can Humans Drive the Development of Ethical Artificial Intelligence?
    

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    Regional compartmentalization in multienzyme-related biomaterials system
    

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    Interfacial Colloidal Performance and Adhesive Strength of an Environmentally Friendly Cellulose-microcrystal-based Adhesive Substance
    

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    Study on Transient Spectrum Based on charge transfer of semiconductor quantum dots
    

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    Analysis and Research on Corrosion Law of Natural Environment of Materials
    

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    An Edge-Deployable Multi-Modal Nano-Sensor Array Coupled with Deep Learning for Real-Time, Multi-Pollutant Water-Quality Monitoring
    

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    Revisiting the Marcus Inverted Regime: Modulation Strategies for Photogenerated Ultrafast Carrier Transfer from Semiconducting Quantum Dots to Metal Oxides
    

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    Environmental Effect of Water-Permeable Pavement Materials in Sponge Cities
    

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    Tunable structure-activity correlations of molybdenum dichalcogenides (MoX2; X= S, Se, Te) electrocatalysts via hydrothermal methods: insight into optimizing the electrocatalytic performance for hydrogen generation
    

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    Intelligent digitalization and immersive experience in cross-border e-commerce environment (I): the formation pathway and underlying “mediator” of consumer brand attachment
    

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    Unlocking Hydrogen Evolution: Deciphering Structure-Activity Links in Two-Dimensional Molybdenum Dichalcogenides for Enhanced Electrochemical Catalysis
    

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Muhammad Rizwan | Environmental Chemistry | Best Researcher Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Dr. Muhammad Rizwan | Environmental Chemistry | Best Researcher Award


Postdoc Researcher, Changsha University of Science & Technology, China


Dr. Muhammad Rizwan is a seasoned soil and environmental scientist from Pakistan, specializing in sustainable green materials and engineered biochars for environmental management. With over a decade of experience, he has led research in nanomaterial synthesis, environmental chemistry, resource recovery, and climate change mitigation. Currently, he is a Senior Postdoctoral Fellow at Changsha University of Science and Technology, China, where he leads independent and collaborative research projects, mentors students, and contributes significantly to environmental science literature. He has held positions at Central South University, China Agricultural University, and the University of Okara, Pakistan. His scientific contributions include numerous high-impact publications, editorial roles, and peer-review activities for leading journals. Dr. Rizwan is dedicated to advancing environmental sustainability through innovative research solutions and maintains strong international collaborations, aiming to tackle global environmental challenges and improve ecological health worldwide.


Professional Profile


Google Scholar


Education 


Dr. Muhammad Rizwan began his academic journey with a Bachelor of Science degree from PMAS-Arid Agriculture University, Rawalpindi, Pakistan, between 2007 and 2011, where he excelled as a merit scholarship holder. He continued his studies at the same institution, completing a Master of Science in Soil and Environmental Sciences from 2011 to 2013, supported by the USAID Merit Scholarship. Eager to expand his expertise internationally, he pursued a Ph.D. in Soil and Environmental Sciences at China Agricultural University, Beijing, from 2015 to 2019, under a prestigious full scholarship from the Chinese Scholarship Council (CSC). In addition to his scientific training, he undertook a Chinese language course at China Agricultural University in 2014-2015 to support his academic and professional integration in China. His educational journey has equipped him with a deep multidisciplinary understanding of soil science, environmental remediation, and sustainable resource management.


Experience 


Dr. Muhammad Rizwan’s professional experience spans academia and research across Pakistan and China. As a Senior Postdoctoral Fellow at Changsha University of Science and Technology since December 2024, he designs experiments, conducts data analysis, publishes research, and teaches undergraduate courses in Environmental Sciences. From June 2021 to November 2024, he served as a Postdoctoral Fellow at Central South University, where he specialized in engineered biochars, experimental research, and student mentoring. Earlier, he worked as an IPFP Fellow (equivalent to Assistant Professor) at the University of Okara, Pakistan, teaching courses, securing research funding, and managing departmental responsibilities. His career began as a University Research Assistant at China Agricultural University from 2016 to 2019, focusing on biochar research and publication writing. He is also actively engaged in editorial roles for journals and peer-review activities, further strengthening his profile as a leading environmental scientist.


Awards and Honors 


Dr. Muhammad Rizwan has earned multiple accolades reflecting his research excellence and academic commitment. He was selected as a Distinguished Postdoctoral Fellow at Central South University in 2024, recognizing his impactful contributions to environmental science. During his doctoral studies, he held a full scholarship from the Chinese Scholarship Council (CSC) from 2015 to 2019, and he was honored with the “Excellent Research Achievement Award” by China Agricultural University for two consecutive years, 2015 and 2016. He won the Best Presentation Award at the 4th Asia Pacific Biochar Conference in Foshan, China, in 2018. Earlier in his academic journey, he consistently secured merit scholarships during his Bachelor’s and Master’s studies at PMAS-Arid Agriculture University, Rawalpindi, Pakistan, including the prestigious USAID Merit Scholarship between 2011 and 2013. These honors underscore his dedication, innovative research spirit, and contributions to sustainable environmental solutions.


Research Interests 


Dr. Muhammad Rizwan’s research interests span diverse yet interconnected fields within environmental science. His primary focus lies in the synthesis and engineering of advanced biochars for sustainable environmental management, addressing pollution remediation, soil health improvement, and resource recovery. He is deeply engaged in nanomaterial synthesis and exploring the environmental chemistry of pollutants and emerging contaminants. His work also emphasizes developing green materials and innovative sorbents for water and soil remediation, contributing to climate change mitigation strategies through carbon sequestration and circular economy approaches. He is keenly interested in using biochar-based composites and functional materials for removing heavy metals, organic pollutants, and emerging contaminants from ecosystems. His interdisciplinary research bridges environmental chemistry, materials science, sustainable agriculture, and environmental engineering, reflecting a strong commitment to sustainable development goals. Dr. Rizwan aims to pioneer solutions that advance environmental sustainability while addressing pressing global ecological challenges.


Research Skills 


Dr. Muhammad Rizwan possesses extensive research skills in experimental design, nanomaterial synthesis, and the engineering of biochar-based materials for environmental applications. He excels in advanced techniques for synthesis and characterization of biochars, including surface functionalization, magnetic modification, and steam explosion pretreatments. His expertise covers analytical methods like spectroscopy, electron microscopy, adsorption analysis, and thermal analysis for evaluating material properties and pollutant interactions. Dr. Rizwan is adept at data analysis using statistical tools and machine learning approaches, contributing to predictive modeling in environmental studies. He is skilled in writing high-quality research publications, preparing project proposals, and delivering scientific presentations. His experience includes supervising students, leading collaborative research projects, and coordinating multi-institutional studies. Additionally, he actively contributes to scientific journals as an editor and reviewer, ensuring rigorous peer-review standards. His research skills uniquely position him to develop innovative solutions for environmental sustainability and pollution remediation.


Publication Top Notes


    

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    Synthesis, characterization and application of magnetic and acid modified biochars following alkaline pretreatment of rice and cotton straws
    

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    A review of mechanism and adsorption capacities of biochar-based engineered composites for removing aquatic pollutants from contaminated water
    

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    Biochar as a green sorbent for remediation of polluted soils and associated toxicity risks: a critical review
    

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    Recent trends and economic significance of modified/functionalized biochars for remediation of environmental pollutants
    

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    Steam explosion of crop straws improves the characteristics of biochar as a soil amendment
    

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    Machine learning-aided prediction of nitrogen heterocycles in bio-oil from the pyrolysis of biomass
    

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    Potential value of biochar as a soil amendment: A review
    

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    Sustainable manufacture and application of biochar to improve soil properties and remediate soil contaminated with organic impurities: a systematic review
    

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    Exogenously applied melatonin enhanced chromium tolerance in pepper by up-regulating the photosynthetic apparatus and antioxidant machinery
    

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    Tuning active sites on biochars for remediation of mercury-contaminated soil: A comprehensive review
    

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    Biochar enhances the growth and physiological characteristics of Medicago sativa, Amaranthus caudatus and Zea mays in saline soils
    

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    Manganese-modified biochar promotes Cd accumulation in Sedum alfredii in an intercropping system
    

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    Lead-Immobilization, transformation, and induced toxicity alleviation in sunflower using nanoscale Fe°/BC: Experimental insights with Mechanistic validations
    

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    Innovative dual-active sites in interfacially engineered interfaces for high-performance S-scheme solar-driven CO2 photoreduction
    

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    Interfacially Modulated S‐Scheme Van der Waals Heterojunctional Photocatalyst for Selective CO2 Photoreduction Coupled with Organic Pollutant Degradation
    

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    Simultaneous dopants and defects synergistically modulate the band structure of CN in Z-scheme heterojunctional photocatalysts for simultaneous HER and OER production
    

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    Rational Design Strategy for High‐Valence Metal‐Driven Electronically Modulated High‐Entropy Co–Ni–Fe–Cu–Mo (Oxy) Hydroxide as Superior Multifunctional Electrocatalysts
    

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    Characteristics of Cd2+ sorption/desorption of modified oilrape straw biochar
    

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    Synergistic effect of biochar and intercropping on lead phytoavailability in the rhizosphere of a vegetable-grass system
    

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    COMPARISON OF PB2+ ADSORPTION AND DESORPTION BY SEVERAL CHEMICALLY MODIFIED BIOCHARS DERIVED FROM STEAM EXPLODED OIL-RAPE
    

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Shoulong	 Xu | Nuclear Radiation Detection | Best Researcher Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Dr. Shoulong Xu | Nuclear Radiation Detection | Best Researcher Award


University of South China, China


Shoulong Xu, born in June 1988, is an Associate Professor in the School of Resources, Environment and Safety Engineering at the University of South China. A member of the Communist Party of China, he holds a Doctorate in Engineering and supervises master’s students. Xu conducted his postdoctoral research at Tsinghua University and has built a prominent career in nuclear safety and radiation detection. He has authored over 50 academic papers, including significant publications in high-impact journals, and holds seven invention patents. He leads provincial-level demonstration courses and teams focused on integrating ideological and political education into engineering disciplines. Xu actively contributes to professional societies, serving on committees within the Chinese Nuclear Society and the Chinese Instrument and Control Society. His research emphasizes technologies for nuclear emergency safety, radiation-hardened systems, and monitoring solutions for extreme environments, advancing both scientific knowledge and practical safety standards in the nuclear sector.


Professional Profile


Scopus


Education 


Shoulong Xu embarked on his academic path in 2006 at North China Electric Power University, where he earned his Bachelor’s degree in Thermal Energy and Power Engineering in July 2010. Driven by a growing interest in nuclear technology, he continued his education at the University of South China from September 2011 to June 2017, pursuing a doctoral degree in Nuclear Technology and Applications under the supervision of Professor Shuliang Zou. His Ph.D. research focused on nuclear radiation detection and monitoring technologies essential for safety and emergency response in nuclear facilities. Following his doctorate, Xu undertook a prestigious postdoctoral fellowship from December 2017 to December 2019 at the Department of Engineering Physics, Tsinghua University. During this period, he deepened his expertise in radiation detection and radiation-hardened systems. This robust educational background has been foundational in establishing Xu as a leading researcher and educator in nuclear safety engineering and radiation technologies.


Professional Experience 


After earning his doctorate, Shoulong Xu began his academic career as a Lecturer in June 2017 at the University of South China’s School of Resources, Environment and Safety Engineering. In June 2021, he was promoted to Associate Professor. His administrative trajectory has been equally dynamic: he served as Deputy Director and subsequently Director of the Safety Engineering Department between 2021 and 2024. Xu then took on leadership roles as Vice Dean of the School of Resources, Environment and Safety Engineering and Vice Dean of the Graduate School from 2024 to early 2025. As of March 2025, he serves as Director of the Admissions Office and Career Guidance Center at the University of South China. Parallel to these administrative positions, Xu conducted postdoctoral research at Tsinghua University from 2017 to 2019. Throughout his career, he has combined research, teaching, and leadership, making significant contributions to nuclear safety and engineering education.


Awards and Honors


Shoulong Xu’s excellence in research and education has earned him significant recognition. He was selected as a Young Scholar under Hunan Province’s Furong Scholars Program, highlighting his potential and achievements in scientific innovation. Xu has been honored as a Model Teacher for Ideological and Political Education in Courses in Hunan Province, reflecting his dedication to integrating ideological values into technical education. He leads both a Model Teaching Team and a Model Course for Ideological and Political Education in the province, showcasing his influence in academic reform. Additionally, he directs a Demonstration Course for Graduate Students in Hunan Province. Professionally, he serves as a committee member of the Youth Committee of the Chinese Nuclear Society and the Nuclear Instrumentation and Control Technology Branch of the Chinese Instrument and Control Society. He is also Deputy Director of two major provincial research centers, underscoring his leadership in advancing nuclear safety technologies and education.


Research Interests


Shoulong Xu’s research interests lie at the intersection of nuclear safety, radiation detection, and emergency technologies. He specializes in nuclear radiation detection and monitoring systems designed for extreme environments, including high-radiation fields and complex operational conditions. His work focuses on developing nuclear emergency safety technologies and equipment, ensuring timely and precise responses to nuclear incidents. Another key area of his research is radiation-hardened reinforcement techniques, aiming to enhance the durability and reliability of sensing and control systems used in nuclear robots and facilities. Xu is deeply involved in studying nuclear facility decommissioning and spent fuel reprocessing safety, working on risk assessment and innovative monitoring approaches. His projects often combine cutting-edge sensor technologies, advanced algorithms for real-time data processing, and robust system engineering to address the challenges posed by nuclear accidents and radiation hazards, contributing both to national defense needs and civilian nuclear safety enhancements.


Research Skills 


Shoulong Xu possesses a robust set of research skills essential for advancing nuclear safety technologies. He is proficient in nuclear radiation detection methods, including using monolithic active pixel sensors (MAPS) and commercial off-the-shelf (COTS) CMOS sensors for both low- and high-dose-rate environments. Xu is skilled in radiation-hardening techniques, ensuring electronic systems can function reliably under intense radiation exposure. His expertise extends to atmospheric diffusion modeling using tools like CALPUFF, applied to simulate radionuclide dispersion in nuclear incidents. Xu is adept at risk assessment methodologies for nuclear facilities, including dynamic fault tree analysis and socio-technical modeling of accident scenarios. He has strong capabilities in real-time data acquisition, signal processing, and parallel computing for optimizing radiation monitoring systems. Xu also demonstrates proficiency in hardware-software integration for radiation detection equipment. His experience spans both fundamental research and collaborative industrial projects, combining theoretical analysis with practical system development for nuclear safety applications.


Publication Top Notes


    

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    Research on Radiation Damage and Reinforcement of Control and Sensing Systems in Nuclear Robots. Electronics 2024, 13, 1214.
    

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    Study on the Atmospheric Diffusion of Airborne Radionuclide under LOCA of Offshore Floating Nuclear Power Plants Based on CALPUFF. Sustainability 2023, 15(3): 2572.
    

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    Risk Analysis and Evaluation of Nuclear Security Radiation Events in Spent Fuel Reprocessing Plants. Sustainability 2023, 15(1): 781.
    

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    Parallel processing of radiation measurements and radiation video optimization. Optics Express 2022, 30(26): 46870-46887.
    

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    Evaluation of Emergency Response Measures for the LOCA of A Marine Reactor. Sustainability 2022, 14(21): 13873.
    

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    Research on Calculation Method of Radiation Response Eigenvalue of a Single-Chip Active Pixel Sensor. Sensors 2022, 22(13): 4815.
    

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    Real-time monitoring method for radioactive substances using monolithic active pixel sensors (MAPS). Sensors 2022, 22(10): 3919.
    

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    Strong Radiation Field Online Detection and Monitoring System with Camera. Sensors 2022, 22(6): 2279.
    

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    Ultrawide-range radiation detection based on dynamic identification and analysis of the response of a monolithic active pixel sensor. Optics Express 2022, 30: 14134-14145.
    

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    Safety analysis of marine nuclear reactor in severe accident with dynamic fault trees based on cut sequence method. Nuclear Engineering and Technology 2022, 54(12): 4560-4570.
    

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    Effect analysis of break size on source term release and radioactive consequences of marine nuclear reactor during loss of coolant accident. Energy Research 2022, 46(15): 23715-23729.
    

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    A Novel Approach for Radionuclide Diffusion in the Enclosed Environment of a Marine Nuclear Reactor During a Severe Accident. Nuclear Science and Techniques 2022, 33(2): 1-13.
    

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    Low dose rate γ-ray detection using a MAPS camera under a neutron radiation environment. Optics Express 2021, 29(22): 34913-34925.
    

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    Obtaining High Dose rate γ-ray Detection with Commercial off-the-shelf CMOS Pixel Sensor Module. IEEE Sensors Journal 2019, 19(16): 6729.
    

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    Video Monitoring Application of CMOS 4T-PPD-APS Under γ-ray Radiation. Sensors 2019, 19(3): 359.
    

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    Effect of Commercial Off-The-Shelf MAPS on γ-Ray Ionizing Radiation Response to Different Integration Times and Gains. Sensors 2019, 19(22): 4950.
    

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    Study on the Availability of 4T-APS as a Video Monitor and Radiation Detector in Nuclear Accidents. Sustainability 2018, 10(7): 2172.
    

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    Radionuclide Transfer in the Zirconium Oxychloride Production Process and the Radiation Effect in a Typical Chinese Enterprise. Sustainability 2019, 11(21): 5906.
    

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    γ-ray Detection Using Commercial Off-The-Shelf CMOS and CCD Image Sensors. IEEE Sensors Journal 2017, 17(20): 6599-6604.
    

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    Study on Release and Migration of Radionuclides Under the Small Break Loss of Coolant Accident in a Marine Reactor. Science and Technology of Nuclear Installations.
    

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Victor Kozlov | Combustion | Best Paper Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Prof. Dr. Victor Kozlov | Combustion | Best Paper Award


Khristianovich Institute of Theoretical and Applied Mechanics SB RAS, Russia


Professor Viktor V. Kozlov is a globally renowned expert in fluid mechanics with a distinguished career spanning over five decades. He earned his Candidate of Sciences (Ph.D.) in Physics and Mathematics in 1976 and later completed his Doctoral Thesis in 1987, earning the title of Full Professor at Novosibirsk State University in 1992. He has led the Aero-Physical Studies of Subsonic Flows group at the Khristianovich Institute of Theoretical and Applied Mechanics (ITAM), Siberian Branch of the Russian Academy of Sciences, since 1979. Professor Kozlov has made pioneering contributions to the understanding of turbulence, boundary layers, and separated flows, and is also known for his innovations in aerodynamic flow control methods. A respected educator, he has taught at Novosibirsk State University since 1990 and conducted collaborative teaching and research across Europe, Asia, and the USA. His legacy includes foundational textbooks, numerous patents, and organizing key international conferences.


Professional Profile


Google Scholar


Scopus


Education 


Professor Viktor V. Kozlov received his Master’s degree from Novosibirsk State University, Russia, between 1964 and 1969. He went on to complete his Candidate’s Degree (Ph.D.) in Physics and Mathematics in 1976. His academic pursuits culminated in the successful defense of his Doctoral Thesis in 1987, granting him the rank of Doctor of Sciences. In recognition of his scholarly achievements and research contributions, he was awarded the title of Full Professor by Novosibirsk State University in 1992. Professor Kozlov’s educational background is rooted in a strong foundation in theoretical and applied physics, particularly focusing on fluid dynamics and turbulent flow phenomena. His deep academic training has empowered him to contribute significantly to the fields of laminar-turbulent transition and aerodynamics. His books and lectures have shaped generations of physicists and engineers both in Russia and internationally.


Professional Experience 


Professor Viktor V. Kozlov began his career as a Scientific Research Fellow at the Khristianovich Institute of Theoretical and Applied Mechanics (ITAM) from 1969 to 1979. Since 1979, he has served as the Group Leader of Aero-Physical Studies of Subsonic Flows at ITAM. He has also been a Professor at Novosibirsk State University since 1990, teaching undergraduate and graduate courses in fluid mechanics. His international experience includes extended research visits to prestigious institutions such as KTH (Sweden), Chalmers University (Sweden), Pusan State University (Korea), and DLR (Germany), as well as a research associate position at Virginia Tech (USA). He has organized and chaired numerous international symposia and workshops, including the IUTAM Symposiums and the Asian Symposium on Visualization. His extensive experience spans research, teaching, international collaboration, and scientific leadership in fundamental and applied fluid mechanics.


Awards and Honors 


Professor Viktor V. Kozlov has received numerous prestigious awards in recognition of his groundbreaking contributions to fluid dynamics and aerophysical research. In 1993, he was honored with the Silver Zhukovsky Medal by the Russian Academy of Sciences for his contributions to aviation theory. In 2008, he received the Petrov Medal for his work on hydrodynamic instability, and the Medal of the Order of Merit for the Motherland, II Class, acknowledging his services to Russian science. In 2015, he was awarded the Sedov Medal, further solidifying his status as a leading figure in the field. Beyond medals, he has led and participated in international scientific committees and symposia, such as the IUTAM Symposium on Separating Flow and Jets, and has been a consistent presence on the scientific committees of international conferences on aerophysical research and laminar-turbulent transition, making significant impacts in global scientific collaboration and innovation.


Research Interests 


Professor Kozlov’s primary research interests lie in fluid mechanics, particularly focusing on boundary-layer theory, turbulence onset, laminar-turbulent transition, instabilities in near-wall flows, and flow control techniques. His research explores the physical mechanisms of transition from laminar to turbulent flow in both internal and external aerodynamics. He has worked extensively on understanding and controlling flow separation in subsonic flows, the structure and evolution of coherent vortical structures, and instability development in jets and wall-bounded flows. More recently, his work has also included hydrogen microjet combustion, contributing insights into flame structure and transitional combustion phenomena. Through experimental fluid dynamics, Professor Kozlov has provided critical understanding into receptivity and non-linear wave development in boundary layers. His interdisciplinary approach connects fundamental physics with practical applications in aerospace, mechanical, and energy engineering.


Research Skills 


Professor Kozlov is highly skilled in experimental fluid dynamics, specializing in flow visualization, instability measurements, and aerodynamic flow control. He possesses extensive expertise in laminar-turbulent transition analysis, boundary-layer receptivity, subsonic and transitional shear flows, and hydrogen combustion. His proficiency includes designing and operating low-turbulence wind tunnels, implementing hot-wire anemometry, and conducting flow diagnostics using advanced visualization and measurement techniques. He also has deep experience in the design of aerodynamic test setups, jet dynamics, and separation control mechanisms. His applied research has led to several patents in aerodynamic flow control. Professor Kozlov’s leadership in long-term experimental programs and international collaborations showcases his organizational and analytical capabilities, making him a critical contributor to experimental and theoretical advancements in fluid mechanics.


Publication Top Notes


    

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    Westin KJA, Boiko AV, Klingmann BGB, Kozlov VV, Alfredsson PH, Experiments in a boundary layer subjected to free stream turbulence. Part 1, JFM, 1994
    

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    Dovgal AV, Kozlov VV, Michalke A, Laminar boundary layer separation: instability and associated phenomena, Progress in Aerospace Sciences, 1994
    

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    Boiko AV, The origin of turbulence in near-wall flows, Springer, 2002
    

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    Boiko AV et al., Experiments in a boundary layer subjected to free stream turbulence. Part 2, JFM, 1994
    

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    Boiko AV et al., Physics of transitional shear flows, Springer, 2011
    

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    Kachanov YS, Kozlov VV, Levchenko VY, Origin of turbulence in boundary layer, Nauka, 1982
    

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    Boiko AV et al., Возникновение турбулентности в пристенных течениях, Nauka, 1999
    

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    Saric W, Levchenko V, Kozlov V, Forced and unforced subharmonic resonance, AIAA, 1984
    

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    Bakchinov AA et al., Transition experiments in a boundary layer with embedded streamwise vortices, Physics of Fluids, 1995
    

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    Klingmann BGB et al., Experiments on the stability of Tollmien-Schlichting waves, European Journal of Mechanics B, 1993
    

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    Kozlov VV et al., Role of localized streamwise structures in the process of transition to turbulence, PMTF, 2002
    

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    Kozlov GV et al., Influence of initial conditions at the nozzle exit on the structure of round jet, Thermophysics and Aeromechanics, 2008
    

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    Bychkov NM, Dovgal AV, Kozlov VV, Magnus wind turbines as an alternative, Journal of Physics: Conf. Series, 2007
    

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    Zverkov I, Zanin B, Kozlov V, Disturbances growth in boundary layers on classical and wavy surface wings, AIAA Journal, 2008
    

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    Kozlov GR et al., Specific features of the flame structure of a pre-mixed hydrogen-oxygen mixture, Int. J. Hydrogen Energy, 2024
    

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    Kozlov VV et al., Diffusion combustion of microjets modulated by Dean vortices, Int. J. Hydrogen Energy, 2023
    

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    Kozlov VV et al., Features of the interaction of disturbances with the leading edge, Thermophysics and Aeromechanics, 2024
    

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    Kozlov VV et al., Diffusion Combustion of Hydrogen in a Microjet from a Curvilinear Channel, Doklady Physics, 2023
    

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    Kozlov VV et al., Distinctive Features of Plume Formation on Collision of Two Laminar Gas Jets, Fluid Dynamics, 2023
    

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    Kozlov VV et al., Scenarios of combustion of plane hydrogen microjets, Conference Proceedings, 2024
    

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Vladislav	Sadyko |  Hydrogen Energy | Outstanding Scientist Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Prof. Vladislav Sadyko | Hydrogen Energy | Outstanding Scientist Award


Professor of Novosibirsk State University, Russia


Prof. Vladislav A. Sadykov is Chief Scientist at the Boreskov Institute of Catalysis (SB RAS) and Professor at Novosibirsk State University, Russia. A Doctor of Science in Chemistry, he has devoted his career to heterogeneous catalysis, energy processes, and nanomaterials development. His research encompasses catalytic redox reactions, solid oxide fuel cells, catalytic membrane reactors, and advanced nanocomposites for clean energy and environmental technologies. Prof. Sadykov has authored over 640 peer-reviewed papers, six monographs, and numerous book chapters, and holds 46 Russian and international patents. He has collaborated widely in international projects funded by NATO, the EU, and Russian science foundations. His work has been recognized by prestigious awards including the Russian Government Prize in Science and Technology, the Balandin Award of RAS, and the Koptyug Award. He serves on editorial boards of leading journals like Applied Catalysis A and Membranes. He is an active member of professional societies worldwide.


Professional Profile


Scopus


Orcid


Education


Prof. Vladislav Sadykov studied Chemistry at Novosibirsk State University, graduating in 1973. He subsequently undertook his Ph.D. and later earned his Doctor of Science degree (the highest scientific degree in Russia) in Chemistry, specializing in catalysis and solid-state chemistry. His academic training focused on materials science, solid-state ionics, and catalytic processes, forming the basis for his career in developing catalysts and functional materials for energy conversion and environmental applications. Throughout his education, he was immersed in rigorous theoretical and experimental research, gaining expertise in solid oxide materials, surface science, and chemical engineering principles. His academic path at Novosibirsk State University provided a strong foundation for his later leadership roles in research and academia, and his continuing role as a Professor there allows him to mentor the next generation of scientists in advanced catalysis and materials science.


Professional Experience


Prof. Vladislav Sadykov began his career at the Boreskov Institute of Catalysis in 1973 and has since progressed to Chief Scientist, heading research in heterogeneous catalysis and advanced materials. Simultaneously, he has served as a Professor at Novosibirsk State University since 1979, delivering lectures and supervising doctoral research in catalysis and materials science. Over five decades, he has led numerous national and international projects, including NATO Science for Peace, INTAS, EU FP6/FP7, and Russian Science Foundation initiatives. His experience spans fundamental studies of catalytic mechanisms to applied industrial projects, notably developing monolithic catalysts for ammonia oxidation in nitric acid production, implemented in Russian plants. He has contributed significantly to solid oxide fuel cell technologies, catalytic membrane reactors, and nanostructured materials. He also serves on editorial boards of prominent journals, participates in national scientific committees, and maintains active collaborations worldwide, solidifying his role as a leader in catalytic science.


Awards and Honors


Prof. Vladislav Sadykov’s research excellence has been recognized through numerous awards. Notably, he received the Award of the Russian Federation Government in Science and Technology (1999) for developing and industrializing a two-stage technology for ammonia oxidation under pressure, applied in nitric acid production. He was honored with the prestigious Balandin Award (2007) from the Russian Academy of Sciences for fundamental work on the defect structures of red-ox catalysts. Additionally, he earned the Koptyug Award (2012) from the National Academy of Sciences of Belarus and the Siberian Branch of RAS for groundbreaking contributions to designing composite and nanostructured materials for hydrogen energy applications. His contributions are further recognized through memberships in respected scientific organizations, such as the Materials Research Society (USA) and the Mendeleev Chemical Society (Russia). These accolades reflect his outstanding influence on the fields of catalysis, nanotechnology, and clean energy research.


Research Interests


Prof. Vladislav Sadykov’s research focuses on heterogeneous catalysis of redox processes for energy production and environmental applications. Key areas include solid oxide fuel cells, catalytic membrane reactors, and the transformation of biofuels into syngas and hydrogen. He is deeply involved in developing nanophase and nanocomposite materials with advanced functionalities, exploring solid-state ionics, and engineering structured catalysts for high-temperature processes. His work extends to catalytic processes at short contact times, enabling efficient conversions under extreme conditions. Additionally, he explores the design of thermal barrier coatings for turbines and permselective membranes for gas separation. Prof. Sadykov’s interests bridge fundamental studies—such as oxygen mobility and surface defect chemistry—with practical applications, including hydrogen production and emission reduction. His multidisciplinary approach integrates materials science, catalysis, and reactor engineering, positioning his work at the forefront of clean energy and sustainable chemical technologies.


Research Skills 


Prof. Sadykov possesses an extensive skill set spanning experimental and theoretical catalysis. He is proficient in the design, synthesis, and characterization of nanostructured catalysts, employing techniques like XRD, TEM, SEM, IR, Raman, and in situ spectroscopy. He specializes in solid-state chemistry and ionics, developing complex oxide systems, perovskites, fluorites, and pyrochlores for catalytic and electrochemical applications. His skills include kinetic studies and mechanistic modeling of catalytic processes, reactor design, and performance evaluation under industrially relevant conditions, such as high temperatures and short contact times. He is experienced in catalytic membrane reactor engineering, integrating catalytic function with separation processes for syngas and hydrogen production. Additionally, he has significant expertise in patent development and industrial technology transfer, evidenced by commercialized catalysts in nitric acid production. His collaborative skills are demonstrated by leadership in multinational projects, and he is adept at scientific communication through publications, patents, and editorial service.


Publication Top Notes


    

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    Catalysts for ethanol dry reforming based on high-entropy perovskites – Nikita F. Eremeev, Semon A. Hanna, Ekaterina M. Sadovskaya, Aleksandra A. Leonova, Olga A. Bulavchenko, Arcady V. Ishchenko, Igor P. Prosvirin, Vladislav A. Sadykov, Yuliya N. Bespalko, 2025
    

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    Synthesis, optical properties, and oxide ionic transport features in Mn-Li-, Mn-Ru-, Mn-Ru-Li-codoped bismuth niobate pyrochlores – M.S. Koroleva, N.F. Eremeev, E.M. Sadovskaya, V.A. Sadykov, I.V. Piir, 2025
    

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    Structural and transport properties of La tungstate and its composite with nickel (II) and copper (II) oxides – Nikita Eremeev, Yulia Bespalko, Ekaterina Sadovskaya, Tamara Krieger, Svetlana Cherepanova, Evgeny Suprun, Arcady Ishchenko, Mikhail Mikhailenko, Mikhail Korobeynikov, Vladislav Sadykov, 2025
    

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    Advances in alternative metal oxide materials of various structures for electrochemical and catalytic applications – Vladislav A. Sadykov, Nikita F. Eremeev, Anna V. Shlyakhtina, Elena Yu Pikalova, 2024
    

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    Impact of calcium and copper co-doping on the oxygen transport of layered nickelates: a case study of Pr1.6Ca0.4Ni1–yCuyO4+δ and a comparative analysis – Vladislav Sadykov, Nikita Eremeev, Ekaterina Sadovskaya, Tatiana Zhulanova, Sergey Pikalov, Yulia Fedorova, Elena Pikalova, 2024
    

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    Alternative Oxide-Based Materials for Electrochemical and Catalytic Applications: A Review – Vladislav Sadykov, Nikita Eremeev, Anna Shlyakhtina, Elena Pikalova, 2024
    

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    Efficient and Stable Nanocomposite Catalysts of Ethanol Steam Reforming Prepared via Inexpensive Procedure with Pluronic P123 Copolymer: Characterization and Testing – Bakytgul Massalimova, Vladislav Sadykov, Nurzada Totenova, Tatyana Glazneva, Tamara Krieger, Vladimir Rogov, Arcady Ishchenko, 2024
    

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    Methods for producing hydrogen: a brief overview – V.A. Sadykov, M.N. Simonov, A. Hassan, 2024
    

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    Approaches to the design of efficient and stable catalysts for biofuel reforming into syngas: doping the mesoporous MgAl2O4 support with transition metal cations – Vladislav A. Sadykov, Nikita F. Eremeev, Ekaterina Sadovskaya, Julia E. Fedorova, Marina V. Arapova, Ludmilla N. Bobrova, Arkady V. Ishchenko, Tamara A. Krieger, Maksim S. Melgunov, Tatyana S. Glazneva, et al., 2023
    

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    Design of Mixed Ionic-Electronic Materials for Permselective Membranes and Solid Oxide Fuel Cells Based on Their Oxygen and Hydrogen Mobility – Vladislav Sadykov, Elena Pikalova, Ekaterina Sadovskaya, Anna Shlyakhtina, Elena Filonova, Nikita Eremeev, 2023
    

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    Methane Dry Reforming Catalysts Based on Pr-Doped Ceria–Zirconia Synthesized in Supercritical Propanol – Marina Arapova, Ekaterina Smal, Yuliya Bespalko, Konstantin Valeev, Valeria Fedorova, Amir Hassan, Olga Bulavchenko, Vladislav Sadykov, Mikhail Simonov, 2023
    

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    Synthesis and Oxygen Mobility of Bismuth Cerates and Titanates with Pyrochlore Structure – Yuliya Bespalko, Nikita Eremeev, Ekaterina Sadovskaya, Tamara Krieger, Olga Bulavchenko, Evgenii Suprun, Mikhail Mikhailenko, Mikhail Korobeynikov, Vladislav Sadykov, 2023
    

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    Dry Reforming of Methane over 5%Ni/Ce1-xTixO2 Catalysts Obtained via Synthesis in Supercritical Isopropanol – Ekaterina Smal, Yulia Bespalko, Marina Arapova, Valeria Fedorova, Konstantin Valeev, Nikita Eremeev, Ekaterina Sadovskaya, Tamara Krieger, Tatiana Glazneva, Vladislav Sadykov, et al., 2023
    

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    Ethanol Dry Reforming over Bimetallic Ni‐Containing Catalysts Based on Ceria‐Zirconia for Hydrogen Production – Valeria Fedorova, Yulia Bespalko, Marina Arapova, Ekaterina Smal, Konstantin Valeev, Igor Prosvirin, Vladislav Sadykov, Ksenia Parkhomenko, Anne‐Cécile Roger, Mikhail Simonov, 2023
    

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    Advances in Hydrogen and Syngas Generation – Vladislav Sadykov, 2023
    

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    Structural and transport properties of Nd tungstates and their composites with Ni0.5Cu0.5O obtained by mechanical activation – Nikita F. Eremeev, Yuliya N. Bespalko, Ekaterina M. Sadovskaya, Pavel I. Skriabin, Tamara A. Krieger, Arcady V. Ishchenko, Vladislav A. Sadykov, 2022
    

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    Ni and Ni–Co Catalysts Based on Mixed Ce–Zr Oxides Synthesized in Isopropanol Medium for Dry Reforming of Methane – Yu. N. Bespalko, V. E. Fedorova, E. A. Smal, M. V. Arapova, K. R. Valeev, T. A. Krieger, A. V. Ishchenko, V. A. Sadykov, M. N. Simonov, 2022
    

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    Efficient Catalysts of Ethanol Steam Reforming Based on Perovskite-Fluorite Nanocomposites with Supported Ni: Effect of the Synthesis Methods on the Activity and Stability – Marina Arapova, Symbat Naurzkulova, Tamara Krieger, Vladimir Rogov, Vladislav Sadykov, 2022
    

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    Carbon Formation during Methane Dry Reforming over Ni-Containing Ceria-Zirconia Catalysts – Ekaterina Smal, Yulia Bespalko, Marina Arapova, Valeria Fedorova, Konstantin Valeev, Nikita Eremeev, Ekaterina Sadovskaya, Tamara Krieger, Tatiana Glazneva, Vladislav Sadykov, et al., 2022
    

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    Structural and Transport Properties of E-Beam Sintered Lanthanide Tungstates and Tungstates-Molybdates – Vladislav Sadykov, Yuliya Bespalko, Ekaterina Sadovskaya, Tamara Krieger, Vladimir Belyaev, Nikita Eremeev, Mikhail Mikhailenko, Alexander Bryazgin, Mikhail Korobeynikov, Artem Ulihin, et al., 2022
    

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    Simple Approach to the Fabrication of Lanthanum Orthoniobates and Nanocomposites with Ni, Cu, and Co Metal Nanoparticles Using Supercritical Isopropanol – Dinara Altynbekova, Yulia Bespalko, Konstantin Valeev, Nikita Eremeev, Ekaterina Sadovskaya, Tamara Krieger, Artem Ulihin, Arina Uhina, Bakytgul Massalimova, Simonov M.N., et al., 2022
    

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    Model-Based Performance Analysis of Membrane Reactor with Ethanol Steam Reforming over a Monolith – Ludmilla Bobrova, Nadezhda Vernikovskaya, Nikita Eremeev, Vladislav Sadykov, 2022
    

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    High-Temperature Behavior, Oxygen Transport Properties, and Electrochemical Performance of Cu-Substituted Nd1.6Ca0.4NiO4+δ Electrode Materials – Tatiana Maksimchuk, Elena Filonova, Denis Mishchenko, Nikita Eremeev, Ekaterina Sadovskaya, Ivan Bobrikov, Andrey Fetisov, Nadezhda Pikalova, Alexander Kolchugin, Alexander Shmakov, et al., 2022
    

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    Elimination of Composition Segregation in 33Al–45Cu–22Fe (at.%) Powder by Two-Stage High-Energy Mechanical Alloying – Serguei Tikhov, Konstantin Valeev, Svetlana Cherepanova, Vladimir Zaikovskii, Aleksei Salanov, Vladislav Sadykov, Dina Dudina, Oleg Lomovsky, Sergey Petrov, Oleg Smorygo, et al., 2022
    

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    Design of materials for solid oxide fuel cells, permselective membranes, and catalysts for biofuel transformation into syngas and hydrogen based on fundamental studies of their real structure, transport properties, and surface reactivity – Vladislav A. Sadykov, Nikita F. Eremeev, Ekaterina M. Sadovskaya, Anna V. Shlyakhtina, Elena Yu Pikalova, Denis A. Osinkin, Aleksey A. Yaremchenko, 2022
    

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Bibhas Kumar	Dutta | Spectroscopy | Best Researcher Award
			

				Published on  by Chemistry Awards			

		
	


	

		
 Assist. Prof. Dr. Bibhas Kumar Dutta | Spectroscopy | Best Researcher Award


Assistant Professor at Sree Chaitanya College, India


Dr. Bibhas Kumar Dutta is an Assistant Professor in the Department of Physics at Sree Chaitanya College, Habra, affiliated with West Bengal State University. With over two decades of experience in theoretical and experimental physics, Dr. Dutta has made significant contributions to quantum optics, nonlinear optics, atomic physics, and coherent control in atomic systems. He earned his Ph.D. in Physics from Vidyasagar University in 2010, after completing B.Sc. and M.Sc. degrees from the University of Calcutta. Dr. Dutta has authored more than 40 research papers published in reputed international journals, with an h-index of 9 and over 330 citations. He is an active collaborator in interdisciplinary research and regularly mentors undergraduate and postgraduate students. Known for his depth in multi-wave-mixing processes and quantum coherence, Dr. Dutta continues to influence the field with pioneering work in optical phase control and atom localization.


Professional Profile


Scopus


Education 


Dr. Bibhas Kumar Dutta has a strong academic background in physics. He completed his B.Sc. in Physics from the University of Calcutta in 1995, followed by an M.Sc. in Physics from the same university in 1997. His postgraduate education was marked by a solid foundation in theoretical and experimental physics. In recognition of his academic excellence, he was awarded the National Scholarship at both the 10+2 and graduation levels. In 2000, he qualified for the CSIR-NET with Junior Research Fellowship (JRF), a highly competitive national-level examination in India. He subsequently earned his Ph.D. in Physics from Vidyasagar University in 2010, where his research focused on quantum optics and coherent atomic systems. His educational journey reflects a consistent trajectory of academic excellence and deep engagement in frontier areas of physics.


Professional Experience


Dr. Bibhas Kumar Dutta has served as an Assistant Professor in the Department of Physics at Sree Chaitanya College, Habra, for over a decade. Affiliated with West Bengal State University, his academic role includes teaching undergraduate physics, mentoring research projects, and guiding students in their academic development. Prior to his Ph.D., he was actively involved in collaborative research projects in spectroscopic analysis and optical physics. His academic career is distinguished by his research on light-matter interaction, multi-wave mixing, and coherent control in atomic and optical systems. Over the years, Dr. Dutta has collaborated with numerous eminent scientists and published extensively in international peer-reviewed journals. He also contributes as a reviewer for journals and frequently participates in national and international physics conferences. His balanced commitment to both teaching and research makes him a respected figure in the academic community.


Awards and Honors 


Dr. Bibhas Kumar Dutta has received several academic honors throughout his career. Notably, he was awarded the National Scholarship at both the higher secondary and undergraduate levels, recognizing his exceptional academic performance in early education. He qualified for the prestigious CSIR-NET with Junior Research Fellowship (JRF) in 2000, which enabled him to pursue advanced research in theoretical physics. Over the years, his scholarly work has gained attention in the scientific community, with more than 330 citations and an h-index of 9. His contributions to quantum optics and nonlinear phenomena have been acknowledged through his involvement in high-impact journals like Scientific Reports, Physical Review, Journal of Physics B, and Optics Communications. He has also served as a co-author and collaborator with various prominent physicists in India. While not yet a recipient of large-scale research grants, his consistent publication record and collaborative work mark him as a recognized expert in his field.


Research Interests 


Dr. Bibhas Kumar Dutta’s research interests lie in the domains of quantum optics, atomic and molecular physics, nonlinear optics, and coherent control techniques in atomic systems. He is particularly focused on studying multi-wave mixing phenomena, atom localization, quantum interference effects, and optical phase modulation. His work also includes the development of novel methods for spatial light modulation using structured light fields, vortex beams, and four-wave mixing processes. Dr. Dutta has investigated phase-coherent processes for controlling absorption, dispersion, and spontaneous emission in various atomic configurations. His interests extend to applications in quantum information science, high-precision spectroscopy, and optical communication technologies. With a deep understanding of atomic coherence, he aims to develop new techniques for manipulating quantum states in both cold and hot atomic ensembles. His research is both theoretical and semi-experimental, involving simulations and modeling based on realistic quantum systems and nonlinear media.


Research Skills 


Dr. Dutta possesses a diverse set of research skills centered around theoretical modeling and computational simulations in quantum optics and atomic physics. He has expertise in density matrix formalism, perturbative and non-perturbative methods, and solving complex differential equations related to atom-light interactions. He is proficient in using scientific programming tools such as MATLAB and Mathematica for simulating absorption spectra, coherence effects, and spatial localization patterns. Dr. Dutta is skilled in analyzing spontaneous emission, multi-photon interactions, and nonlinear optical effects in multi-level atomic systems. He also demonstrates strong analytical skills in phase engineering, optical trapping, and waveguide dynamics. His collaborative research has involved simulating phenomena like Autler-Townes splitting, Fano resonance, and PT symmetry breaking. With a background that includes experimental spectroscopy, he can bridge theoretical predictions with potential experimental verification, making his research highly impactful and practically oriented.


Publication Top Notes


    

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    Dutta B.K. & Panchadhyayee P. (2025) – A new mechanism of off-axis helical phase engineering in spatial four-wave-mixing light at frequency up-conversion regime
    

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    Panchadhyayee P., Banerjee A., & Dutta B.K. (2024) – Vortex beam induced spatial modulation of quantum-optical effects in a coherent atomic medium
    

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    Banerjee A., Panchadhyayee P., & Dutta B.K. (2024) – Efficient control of three-dimensional atom localization via probe absorption in a phase-coherent atomic medium
    

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    Banerjee A., Panchadhyayee P., & Dutta B.K. (2024) – Efficient control of high-precision three-dimensional atom localization via probe absorption in a five-level phase-coherent atomic system
    

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    Dutta B.K. & Panchadhyayee P. (2023) – Generation of optical PT-antisymmetry in a coherent N-type atomic medium
    

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    Panchadhyayee P. & Dutta B.K. (2022) – Spatially structured multi-wave-mixing induced nonlinear absorption and gain in a semiconductor quantum well
    

    7. 

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    Dutta B.K. et al. (2020) – Optical absorption microscopy of localized atoms at microwave domain
    

    8. 

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    Dutta B.K. et al. (2020) – Multi-wave-mixing-induced nonlinear modulation of diffraction peaks in an opto-atomic grating
    

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    Dutta B.K. & Panchadhyayee P. (2020) – Fano-like interference induced modification of Autler-Townes doublet spectrum
    

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    Panchadhyayee P. et al. (2019) – Field-induced superposition effects on atom localization via resonance fluorescence spectrum
    

    11. 

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    Dutta B.K. & Panchadhyayee P. (2018) – Modification of optical properties by adiabatic shifting of resonances in a four-level atom
    

    12. 

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    Dutta B.K. et al. (2018) – Role of tunneling induced coherence in modulation of absorption and dispersion in a quantum dot molecule
    

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    Panchadhyayee P. et al. (2018) – Resonance fluorescence microscopy via three-dimensional atom localization
    

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    Dutta B.K. & Panchadhyayee P. (2016) – Modification and control of coherence effects in spontaneous emission spectrum
    

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    Bayal I. et al. (2015) – Multiphoton-process-induced coherence effects in a dissipative quantum system
    

    16. 

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    Bayal I. et al. (2015) – Simulation of coherently controlled population dynamics in a three-level atomic system
    

    17. 

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    Dutta B.K. (2014) – Fano-like line shape of spontaneous emission spectrum in a weakly driven two-level atom
    

    18. 

  18. 

    Dutta B.K. (2013) – Coherent control of narrow structures in absorption, transparency and dispersion
    

    19. 

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    Bayal I. et al. (2013) – Modulation of spatial propagation dynamics in a three-core linear directional coupler
    

    20. 

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    Dutta B.K. et al. (2013) – Coherent control of localization of a three-level atom
    

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Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Prof. Dr. Shin’ya Obara | Thermochemistry | Green Chemistry Award


Prof. Dr. Shin’ya Obara , Thermochemistry , Factory of Engineering at Kitami Institute of Technology, Japan


Prof. Shin’ya Obara is a renowned academic in the field of energy systems, currently serving as Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido, Japan. He earned his B.S. and M.S. degrees in Mechanical Engineering from Nagaoka University of Technology in 1987 and 1989, respectively, and completed his Ph.D. in Mechanical Science at Hokkaido University in 2000. His career bridges academia and industry, including key roles in energy-focused companies and various educational institutes. Dr. Obara has dedicated his research to optimizing energy systems, advancing microgrid technologies, and enhancing the integration of renewable energy sources. He has authored or co-authored over 130 journal articles and is widely respected for his contributions to energy efficiency and sustainable systems. His diverse background brings a unique blend of theoretical insight and practical experience to the field of renewable energy and power systems engineering.


Professional Profile : 


Scopus 


Summary of Suitability for Award:


rof. Shin’ya Obara is a distinguished researcher whose career focuses on energy systems optimization, including microgrids, renewable energy integration, and efficient operation of compound energy systems. His expertise lies primarily in mechanical and electrical engineering aspects of energy infrastructure, with strong emphasis on sustainability, reducing carbon emissions, and improving energy efficiency. While his work significantly contributes to green technologies and the broader goals of environmental sustainability, it is important to distinguish that Green Chemistry—as defined in scientific contexts—focuses specifically on designing chemical products and processes that reduce or eliminate the use and generation of hazardous substances. Green Chemistry deals with areas like greener synthesis pathways, safer solvents, bio-based feedstocks, waste minimization in chemical manufacturing, and environmentally benign chemical processes. Prof. Obara’s research aligns more directly with green energy engineering and sustainable energy systems rather than the core discipline of chemical process innovation or molecular-level chemistry transformations. His publications and projects involve energy networks, system modeling, and engineering solutions for renewable integration, rather than chemical synthesis or green chemical processes. Prof. Shin’ya Obara is an outstanding researcher in sustainable energy systems and green technology engineering, but he would not be a strong fit for a “Green Chemistry Award” focused strictly on chemistry. innovations.


🎓Education:




Prof. Shin’ya Obara pursued his academic journey in Japan, laying a solid foundation in mechanical and energy sciences. He received his Bachelor of Science in Mechanical Engineering from Nagaoka University of Technology in 1987. Continuing at the same institution, he completed his Master of Science in Mechanical Systems in 1989, delving deeper into the intricacies of machine design and thermal systems. While actively involved in industry and research, he furthered his education and earned a Ph.D. in Mechanical Science from Hokkaido University in 2000. His doctoral work focused on energy systems, contributing to the growing field of energy optimization. This unique trajectory—balancing rigorous academic study with practical research—helped shape his systems-based approach to power and energy engineering. His educational background provides a strong interdisciplinary platform for his ongoing research in renewable energy, microgrids, and system-level energy management.


🏢Work Experience:


Prof. Obara began his professional career with an eight-year tenure in industry, holding engineering and research positions at Takasago Thermal Engineering Co., Ltd. and Aisin AW Co., Ltd., where he gained hands-on experience in thermal systems and energy technologies. In 2000–2001, he served as a researcher in the Department of Mechanical Science at Hokkaido University. He transitioned to academia as an Associate Professor at Tomakomai National College of Technology in 2001 and became Professor of its Department of Mechanical Engineering in 2008. Since 2008, he has been Professor in the Department of Electrical and Electronic Engineering at Kitami Institute of Technology, Hokkaido. Throughout his academic career, he has led numerous research projects and mentored students in areas related to energy systems and renewable integration. His combined industrial and academic experience strengthens his expertise in optimizing energy networks and deploying sustainable energy solutions.


🏅Awards: 


























Prof. Shin’ya Obara has been recognized nationally and internationally for his contributions to energy systems and renewable technologies. Though specific awards are not listed in the given information, his authorship of over 130 peer-reviewed papers itself reflects a high level of academic and research excellence. He has likely received recognition through invitations to speak at international conferences, serve as a reviewer for prestigious journals, and lead funded projects in Japan. His role in shaping energy-efficient systems and microgrid optimization places him among influential researchers in sustainable engineering. Professors at his level in Japan often receive internal university awards, Japan Society for the Promotion of Science (JSPS) support, and government-funded grants. For a detailed list of specific honors and awards, his institutional CV or research profile would provide further insights. His enduring academic journey illustrates a career marked by consistent achievement and innovation.


🔬Research Focus:


Prof. Obara’s research centers on energy systems engineering, specifically involving the optimization of power and heat energy systems. He focuses on enhancing energy efficiency, integrating renewable energy sources, and developing microgrid technologies to support decentralized power generation. His work extends into energy network systems, where he explores the operation and simulation of compound energy systems, combining multiple energy sources for robust, resilient networks. He employs both theoretical modeling and experimental verification to refine the operational performance of hybrid energy systems. His contributions are highly relevant in addressing global sustainability challenges, particularly in designing green energy infrastructures that reduce carbon footprints. His research has practical implications for smart cities, off-grid communities, and industrial energy systems. Prof. Obara’s focus on interdisciplinary solutions—blending mechanical, electrical, and system sciences—makes his work highly impactful in the context of global energy transition.


Publication Top Notes:


1. Planning for local production and consumption of energy and electricity storage systems in regional cities, focusing on offshore wind power generation


2. Economic performance of combined solid oxide fuel cell system with carbon capture and storage with methanolation and methanation by green hydrogen


 3. Capacity planning of storage batteries for remote island microgrids with physical energy storage with CO2 phase changes


Citations: 4


4. Comparative study of methods of supplying power to the lunar base


5. Development of energy storage device by CO2 hybridization of CO2 heat pump cycle and CO2 hydrate cycle


 6. Fluctuation Mitigation Control of Wind Farm with Battery Energy Storage System and Wind Turbines’ Curtailment Function


 7. Economic Analysis of SOFC Combined Cycle with CCS Accompanied by Methanation and Methanol Production


 8. Equipment Sizing of a SOFC Triple Combined Cycle and a Hydrogen Fuel Generation System


9. Formation temperature range expansion and energy storage properties of CO2 hydrates


Citations: 4































	


	

	






	
	

		


Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award
			

				Published on  by Chemistry Awards			

		
	


	

		
Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award


Dr. Faranak Hatami , Computational Chemistry , PhD at University of massachuessetes Lowell, United States


Faranak Hatami (Fara) is a dedicated physicist and researcher specializing in molecular dynamics simulations, machine learning, and nuclear materials science. Currently pursuing her Ph.D. in Physics at the University of Massachusetts Lowell, she focuses on transport property analysis and multi-objective optimization for molecular systems like Tri-Butyl-Phosphate (TBP). Faranak holds two master’s degrees—one in Physics from UMASS Lowell, where she explored force fields for TBP, and another in Nuclear Engineering from Shahid Beheshti University, where she investigated radiation damage in metals. With a robust background in computational physics, AI, and advanced simulation tools, she has authored multiple publications across nuclear materials and computational chemistry. Her teaching experience spans both the U.S. and Iran, reflecting her passion for education. Beyond academia, she completed a research internship at the University of Montreal. Faranak’s work bridges fundamental physics and practical applications, contributing innovative insights to the fields of material science and chemical engineering.


Professional Profile : 


Google Scholar 


Summary of Suitability for Award:


Faranak Hatami is a highly suitable candidate for a “Best Researcher Award”. She demonstrates exceptional multidisciplinary expertise spanning physics, molecular dynamics, machine learning, and nuclear materials science. Her Ph.D. work at UMASS Lowell innovatively combines atomic-scale simulations with AI to optimize force field parameters for Tri-Butyl-Phosphate, addressing both fundamental science and practical applications.  She has authored several impactful publications in reputable journals and preprints, covering diverse topics from radiation damage in metals to machine learning models predicting thermodynamic properties. Her research portfolio includes complex computational modeling, multi-objective optimization, and advanced materials analysis. Additionally, Faranak’s teaching record and successful research internship in Canada reflect her commitment to knowledge dissemination and international collaboration. Her ability to merge computational physics with machine learning showcases originality and forward-thinking, key attributes for top research honors. Faranak Hatami embodies the qualities of a best researcher: scientific rigor, innovative thinking, multidisciplinary skillset, and impactful publications. Her contributions significantly advance computational methods in physical sciences and engineering, making her a strong and deserving candidate for a “Best Researcher Award”.


🎓Education:




 Faranak Hatami is completing her Ph.D. in Physics at the University of Massachusetts Lowell (2021–2025), with her thesis focused on transport property analysis and optimization of force field parameters for Tri-Butyl-Phosphate (TBP), combining atomic-scale simulations with machine learning. Prior to this, she earned her M.Sc. in Physics from the same university in 2023, where she conducted a comparative study of force fields for liquid TBP using molecular dynamics. Earlier, she obtained her M.Sc. in Nuclear Engineering from Shahid Beheshti University in Iran (2016), where she examined radiation damage effects on zirconium and iron grain boundaries through simulations. Her academic journey began with a B.S. in Electrical Engineering from Kurdistan University in 2013. Throughout her studies, Faranak has integrated advanced computational methods, AI, and experimental data analysis, building a multidisciplinary foundation that connects physics, materials science, and engineering disciplines.


🏢Work Experience:


Faranak Hatami brings diverse experience across research, teaching, and technical projects. At UMASS Lowell, she serves as a Teaching Assistant in Physics while pursuing her Ph.D., guiding students through complex concepts. Previously, she lectured on Computational Methods and Statistical Methods and Physics courses at Shahid Beheshti University between 2014 and 2018. Her research career includes an internship at the University of Montreal (2019–2021), exploring hydrogen’s effects on iron grain boundaries using the kinetic activation relaxation technique (k-ART). Faranak has led significant academic projects spanning molecular dynamics simulations, multi-objective optimization, and machine learning applications in material science. She has deep expertise in computational tools such as LAMMPS, MCNP, VASP, and Python-based AI frameworks. Her work reflects a unique blend of fundamental physics research, practical problem-solving, and advanced data analysis, contributing to fields like chemical engineering, nuclear materials, and computational modeling.


🏅Awards: 


























 Faranak Hatami has built an impressive research portfolio during her academic career, reflected in multiple publications and conference presentations. While specific named awards were not explicitly listed in her profile, her contributions have earned her recognition through invited presentations such as at the AIChE Annual Meeting, showcasing her expertise in molecular dynamics simulations and force field optimization. Completing dual M.Sc. degrees in Physics and Nuclear Engineering highlights her dedication and academic excellence. Her selection as a research intern at the University of Montreal, working on advanced computational studies in materials science, further underscores her capability and esteem in her field. Through her multidisciplinary approach integrating AI, molecular modeling, and nuclear materials science, she stands out as a rising scholar contributing valuable insights to computational physics and chemical engineering. As she advances her Ph.D., she is poised for further accolades in research innovation and scientific community engagement.


🔬Research Focus:


 Faranak Hatami focuses her research on the intersection of molecular dynamics simulations, machine learning, and materials science. Her Ph.D. work centers on analyzing transport properties and optimizing force field parameters for Tri-Butyl-Phosphate (TBP) using multi-objective optimization algorithms like NSGA-II/III. She applies molecular dynamics to predict critical thermodynamic and transport properties, integrating neural networks for parameter tuning. Additionally, she explores AI-based classification of microscopy and atomic-scale images, blending physics with cutting-edge data science. Faranak’s earlier research in nuclear engineering examined radiation damage in metals such as zirconium and nickel, utilizing techniques like climbing image nudged elastic band (CI-NEB) for defect analysis. She’s also investigated hydration free energies, grain boundary behaviors, and primary knock-on atom (PKA) spectra in irradiated materials. Her work bridges computational physics with practical engineering challenges, advancing predictive models and simulation methods to better understand complex molecular and material systems.


Publication Top Notes:


Comparative Analysis of Machine Learning Models for Predicting Viscosity in Tri-n-Butyl Phosphate Mixtures Using Experimental Data


Citations: 6


Quantification of Methane Hydration Energy Through Free Energy Perturbation Method


Comparison of Different Machine Learning Approaches to Predict Viscosity of Tri-n-Butyl Phosphate Mixtures Using Experimental Data


Citations: 3


Properties of Tri-Butyl-Phosphate from Polarizable Force Field MD Simulations


Citations: 1


A Revision of Classical Force Fields for Tri-N-Butyl Phosphate Molecular Dynamics Simulations


Interaction of primary cascades with different atomic grain boundaries in α-Zr: An atomic scale study


Citations: 34


An energetic and kinetic investigation of the role of different atomic grain boundaries in healing radiation damage in nickel


Citations: 31































	


	

	






	
	

		


Dr. Shoaib Nazir | Nanotechnology | Excellence in Research
			

				Published on  by Chemistry Awards			

		
	


	

		
Dr. Shoaib Nazir | Nanotechnology | Excellence in Research


Dr. Shoaib Nazir , Nanotechnology , Postdoctoral Researcher at Shenzhen University, China


🎓 Shoaib Nazir is a passionate physicist and materials researcher from Pakistan, currently pursuing his Ph.D. at Shaanxi Normal University, Xi’an, China. With expertise in nanomaterials synthesis and characterization, Shoaib’s academic journey reflects a strong dedication to cutting-edge research in materials science. Before moving to China, he earned his M.Phil. in Physics from Riphah International University and a BS (Hons.) from COMSATS, Lahore. Beyond his academic pursuits, he has significantly contributed to education as a senior lecturer and department head in multiple institutions across Pakistan, shaping future scientists with enthusiasm and leadership. His research primarily focuses on nanotechnology, magnetic materials, and materials for electronics and photonics, resulting in several reputable publications. Shoaib is actively engaged on academic platforms like ResearchGate and Google Scholar and stays connected globally via social media and professional networks. His multilingual abilities and cultural adaptability further enrich his academic and professional endeavors.


Professional Profile : 


Google Scholar 


Summary of Suitability for Award:


Shoaib Nazir demonstrates strong potential for recognition under an “Excellence in Research” award. He has built a focused research profile in nanomaterials and material sciences, publishing multiple papers in reputable journals such as Ceramics International and the Arabian Journal of Chemistry. His Ph.D. research in synthesizing and characterizing pure and doped nanomaterials aligns well with high-impact, cutting-edge fields relevant to electronics, photonics, and magnetic applications, contributing valuable insights to advanced material development. His ability to handle complex experimental techniques and multidisciplinary topics like structural, optical, and magnetic characterization underlines his technical proficiency and research depth. Moreover, his proactive academic engagement, including international study and multilingual skills, signifies adaptability and global research vision. Shoaib Nazir is a suitable candidate for an “Excellence in Research” award, particularly in the early-career researcher or emerging scientist categories. His specialized expertise in nanomaterials synthesis and characterization, coupled with quality publications and an international academic background, demonstrates clear merit and potential for significant contributions to materials science and physics. With further research output and collaborations, Shoaib is well-positioned to achieve even greater recognition in his field.


🎓Education:




Shoaib Nazir embarked on his academic journey in physics with a BS (Hons.) degree from COMSATS Institute of Information & Technology Lahore, Pakistan (2011–2015), where he completed a final-year report on space weather events and Earth’s magnetosphere. He then pursued his Master’s (M.Phil.) in Physics at Riphah International University, Islamabad, Pakistan (2015–2017), focusing his dissertation on the synthesis and characterization of hexaferrites. Passionate about expanding his horizons, Shoaib moved to China for his Ph.D. in Physics (2020–2024) at Shaanxi Normal University, Xi’an, where he specializes in synthesizing and characterizing pure and doped nanomaterials. In addition, he studied the Chinese language (HSK 4) from 2019–2020 to facilitate his integration into the academic environment in China. His educational path reflects a strong foundation in physics and a keen focus on materials science, enabling him to bridge theoretical insights with practical applications in nanotechnology.


🏢Work Experience:


Shoaib Nazir boasts diverse professional experience as an educator and academic leader. He served from 2017 to 2022 as the Head of the Physics Department and Senior Lecturer at Punjab Group of Colleges, P.D. Khan Campus, Jhelum, where he led curriculum planning, teaching, and extracurricular initiatives. Prior to that, he worked at Government Degree College CSS, Chakwal (2016–2017), as a Senior Lecturer and Head of the Science Committee, overseeing both academic and student engagement activities. From 2015 to 2016, he was a Physics Lecturer at Govt. Albiruni Degree College, P.D. Khan, Jhelum, where he handled teaching and administrative responsibilities. Earlier in his career, he taught physics and mathematics at The Cambridge Group of Education, Lahore (2013–2015), as a Senior Science Teacher. Throughout his teaching journey, Shoaib has honed his skills in delivering complex scientific concepts with clarity, fostering curiosity and academic excellence among his students.


🏅Awards: 


























While specific formal awards are not listed in Shoaib Nazir’s CV, his career reflects significant achievements and honors through his progressive roles and academic contributions. Serving as Head of Department and Senior Lecturer in multiple prestigious colleges in Pakistan highlights his professional recognition and trust as a leader and educator. His successful admission and ongoing pursuit of a Ph.D. in Physics at a respected Chinese university underscore his academic excellence and competitiveness on the international stage. Additionally, his ability to publish in high-impact journals like Ceramics International and Arabian Journal of Chemistry demonstrates scholarly merit. Shoaib’s active engagement in extracurricular activities and leadership roles throughout his career points to his multifaceted contributions and the respect he commands in academic circles. His linguistic achievement in completing HSK 4 in Chinese further indicates his dedication and adaptability, positioning him as an accomplished scholar and educator with global aspirations.


🔬Research Focus:


Shoaib Nazir’s research lies at the fascinating intersection of nanotechnology and materials science, focusing on synthesizing and characterizing advanced materials for electronics and photonics. His interests encompass the development of nanoparticles, magnetic materials such as ferrites, and materials tailored for electronic device applications. He delves into studying structural, magnetic, optical, and electrical properties of both pure and doped nanomaterials to explore potential technological applications. By doping materials like ZnO nanoparticles with transition metals, Shoaib investigates ways to enhance material performance for electronic devices. His work contributes to understanding magneto-optical phenomena, crucial for photonic and magnetic storage technologies. His Ph.D. research centers on pure and doped nanomaterials synthesis, a field poised to revolutionize next-generation electronic components, sensors, and energy applications. With publications in respected journals, Shoaib’s research aims to bridge the gap between fundamental physics and practical innovations, driving advancements in nanotechnology and modern material engineering.


Publication Top Notes:


1. Modification in structural, optical, morphological, and electrical properties of zinc oxide (ZnO) nanoparticles (NPs) by metal (Ni, Co) dopants for electronic device applications
Citations: 104


2. Structural, magnetic, and electrical evaluations of rare earth Gd3+ doped in mixed Co–Mn spinel ferrite nanoparticles
Citations: 57


3.Magneto-optical properties and physical characteristics of M-type hexagonal ferrite (Ba₁₋ₓCaₓFe₁₁.₄Al₀.₆O₁₉) nanoparticles (NPs)
Citations: 46


4.Green synthesis of AgNPs from leaves extract of Saliva Sclarea, their characterization, antibacterial activity, and catalytic reduction ability
Citations: 45


5.Metal-based nanoparticles: basics, types, fabrications and their electronic applications
Citations: 43


6. Techno-economic and environmental perspectives of solar cell technologies: a comprehensive review
Citations: 30


7.Modification of physicochemical and electrical characteristics of lead sulfide (PbS) nanoparticles (NPs) by manganese (Mn) doping for electronic device and applications
Citations: 13


8. A comparative study of structural, vibrational mode, optical and electrical properties of pure nickel selenide (NiSe) and Ce-doped NiSe nanoparticles for electronic device applications
Citations: 13


9. Improvements in the physicochemical and electrical characteristics of BaO nanoparticles by Cu doping for electronic device applications
Citations: 12


10. Synthesis and characterization of Fe-substituting BaO nanoparticles by sol-gel method
Citations: 11