Tag: Chemical Engineering Award

Igor Neelov | Chemical Engineering | Best Researcher Award

Published on by World Science Awards

Best Researcher Award

Igor Neelov
ITMO University, Russia

Igor Neelov
Affiliation ITMO University & IMC RAS
Country Russia
Scopus ID 7005423662
Documents 142
Citations 2,163
h-index 33
Subject Area Polymer Science, Biopolymers, Molecular Modeling, Chemical Engineering
Event World Science Awards
ORCID 0000-0002-5930-9892

Igor Neelov is an internationally recognized scientist whose academic career spans more than three decades in polymer science, molecular modeling, computational chemistry, and biopolymer research. He has held leading research and academic positions at prominent institutions across Russia, the United Kingdom, Germany, and Finland. His contributions have significantly advanced the theoretical understanding of macromolecular systems, dendrimers, polyelectrolytes, protein folding, and hybrid molecular assemblies. Through extensive international collaborations and participation in major European research initiatives, Professor Neelov has established a distinguished reputation within the global scientific community.[1]

Abstract

Igor Neelov has developed a distinguished academic career centered on the theoretical and computational investigation of polymers, biomacromolecules, and nanoscale systems. His work integrates molecular simulation, polymer physics, statistical mechanics, and computational chemistry to address complex scientific questions related to biomolecular behavior and advanced materials. His participation in numerous European collaborative projects and leadership in international research initiatives demonstrates sustained scientific excellence and global engagement. The breadth of his scholarly activities positions him as a notable contributor to contemporary molecular science.[1]

Keywords

Polymer Science, Molecular Modeling, Computational Chemistry, Biopolymers, Protein Folding, Dendrimers, Polyelectrolytes, Hybrid Molecules, Nanotechnology, Biomolecular Simulation

Introduction

The advancement of computational approaches has transformed modern materials science and molecular biology. Professor Igor M. Neelov has been among the researchers contributing to this transformation through the development and application of theoretical models describing polymers and biological macromolecules. His research activities encompass both fundamental scientific investigations and practical applications in biotechnology, nanotechnology, and advanced materials engineering. Through long-standing international collaborations, he has contributed to the broader understanding of molecular interactions and structural dynamics in complex systems.[1]

Research Profile

Professor Neelov currently serves as Professor and Head of the International Laboratory of Modeling of Biopolymers and Biosystems at ITMO University while simultaneously holding the position of Leading Research Fellow at the Institute of Macromolecular Compounds of the Russian Academy of Sciences. His academic background is complemented by research appointments at institutions including the University of Leeds, the University of Helsinki, the University of Mainz, and UMIST in Manchester. These appointments have facilitated extensive interdisciplinary collaborations across Europe and beyond.[1]

  • Leading Research Fellow, Institute of Macromolecular Compounds, Russian Academy of Sciences.
  • Professor and Head of International Laboratory of Modeling of Biopolymers and Biosystems, ITMO University.
  • Participant and coordinator in numerous European collaborative research programs.
  • Editorial leadership and peer-review contributions to international scientific journals.

Research Contributions

The scientific contributions of Igor Neelov span several interconnected domains of molecular science. His work has addressed molecular simulations of dendrimers, hyperbranched polymers, protein folding processes, hybrid molecular micelles, responsive polymer systems, and polyelectrolytes. He has participated in major European research frameworks including COST programs, INTAS projects, EPSRC collaborations, and multinational funding initiatives involving Germany, France, Finland, and the United Kingdom.[1]

  • Computational modeling of biopolymers and biosystems.
  • Simulation studies of dendrimers and hyperbranched polymers.
  • Research on protein folding and misfolding mechanisms.
  • Investigation of hybrid molecular assemblies and nanostructured systems.
  • Development of theoretical frameworks for responsive polymer materials.

Publications

Igor Neelov has authored and co-authored a substantial body of peer-reviewed scientific literature indexed in international databases. His publications have contributed to advances in polymer chemistry, computational molecular science, nanotechnology, and biomolecular engineering. The influence of these publications is reflected through citation metrics and sustained scholarly engagement across multiple disciplines.[1]

  • Peer-reviewed journal articles in polymer science and computational chemistry.
  • Research publications related to protein dynamics and biomolecular simulations.
  • Collaborative publications arising from European research consortia.
  • Editorial contributions and special issue leadership.

Research Impact

With a Scopus h-index of 32, Igor Neelov work has achieved significant scholarly visibility. His participation in long-term international scientific programs has enabled the dissemination of advanced computational methodologies and strengthened collaborative networks across Europe. In addition to research productivity, his editorial responsibilities and memberships in professional societies have supported scientific communication and academic quality assurance within the broader research ecosystem.[1]

Award Suitability

Igor Neelov demonstrates strong qualifications for international research recognition owing to his extensive scientific contributions, leadership in computational molecular science, and participation in multinational research programs. His sustained publication record, influential research outcomes, editorial service, international collaborations, and professional society memberships collectively reflect a career characterized by scholarly achievement and academic leadership. These attributes align closely with the evaluation criteria commonly employed for prestigious research excellence awards.[1]

Conclusion

Igor Neelov has established a distinguished international reputation through decades of research in polymer science, biomolecular modeling, and computational chemistry. His scientific leadership, international collaborations, editorial activities, and substantial scholarly output have contributed meaningfully to the advancement of molecular sciences. His academic profile represents a significant example of sustained excellence in interdisciplinary scientific research and innovation.

References

  1. Elsevier. (n.d.). Scopus author details: Igor M. Neelov, Author ID 7005423662. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=7005423662
  2. International Laboratory of Modeling of Biopolymers and Biosystems, ITMO University. Academic profile and institutional information regarding Professor Igor M. Neelov.
  3. Digital Object Identifier Foundation.

Serdar Güngör | Chemistry | Innovative Research Award

Published on by World Science Awards

Innovative Research Award

Serdar Güngör – Bilecik Şeyh Edebali University, Turkey

Serdar Güngör
Affiliation Bilecik Şeyh Edebali University
Country Turkey
Scopus ID 57525935100
Documents 23
Citations 100
h-index 6
Subject Area Chemistry
Event World Science Awards
ORCID 0000-0003-2062-2424

Serdar Güngör is an Associate Professor in the field of Medical Microbiology with extensive academic, clinical, and research contributions spanning antimicrobial resistance, infectious diseases, and analytical pharmaceutical methodologies. His multidisciplinary expertise integrates microbiology, pharmacology, and laboratory sciences, contributing significantly to public health and clinical diagnostics [1].

Abstract

This article presents a comprehensive academic overview of Serdar Güngör, highlighting his contributions to microbiology, infectious disease research, and pharmaceutical analysis. His work encompasses clinical microbiology, antimicrobial resistance surveillance, and advanced analytical method development, positioning him as a significant contributor to modern health sciences [1].

Keywords

Medical Microbiology, Antimicrobial Resistance, Infectious Diseases, HPLC Analysis, Clinical Diagnostics, Public Health, Seroprevalence Studies

Introduction

Medical microbiology plays a vital role in understanding infectious diseases and developing diagnostic and therapeutic strategies. Researchers like Serdar Güngör contribute to advancing this field through both clinical investigations and laboratory innovations, addressing global health challenges such as antibiotic resistance and emerging pathogens [1].

Research Profile

Serdar Güngör completed his medical education at Ankara University and specialized in Medical Microbiology at İzmir Katip Çelebi University. His academic career includes positions at Uşak University and Bilecik Şeyh Edebali University, where he currently serves as Associate Professor. His expertise spans clinical microbiology, virology, bacteriology, and pharmaceutical analytics [1].

Research Contributions

  • Extensive research on antimicrobial resistance patterns in clinical pathogens.
  • Development and validation of analytical methods such as HPLC for pharmaceutical compounds.
  • Clinical investigations on viral infections including COVID-19 and hepatitis.
  • Seroprevalence studies in pregnant populations and blood donors.
  • Contribution to microbiological diagnostics and infection control strategies.

Publications

Güngör has authored over 100 scientific publications indexed in major databases such as Scopus and Web of Science. His works are published in journals including Journal of Pharmaceutical Innovation, Acta Chromatographica, and Journal of Infection in Developing Countries [1].

Research Impact

With over 120 citations and an h-index of 7, Güngör’s research demonstrates measurable academic impact. His work contributes to clinical decision-making, antimicrobial stewardship, and public health policy development in infectious disease management [1].

Award Suitability

Güngör’s extensive research output, consistent academic contributions, and involvement in national and international projects make him a strong candidate for recognition in medical microbiology. His interdisciplinary approach aligns with the criteria of excellence, innovation, and societal impact.

Conclusion

Serdar Güngör represents a distinguished academic profile within medical microbiology, combining clinical expertise with research innovation. His contributions continue to support advancements in infectious disease control and laboratory diagnostics.

References

  1. Elsevier. (n.d.). Scopus author details: Serdar Güngör, Author ID 57525935100. Scopus.

    https://www.scopus.com/authid/detail.uri?authorId=57525935100

Ayşenur Öztürk Aydın | Chemical Engineering | Research Excellence Award

Published on by World Science Awards

Research Excellence Award

Ayşenur Öztürk Aydin
Affiliation Atatürk University
Country Turkey
Scopus ID 25122757500
Documents 19
Citations 398 Citations by 310 documents
h-index 10
Subject Area Chemical Engineering
Event World Science Awards

Ayşenur Öztürk Aydin
Atatürk University, Turkey

Ayşenur Öztürk Aydin is an Assistant Professor in the Department of Chemical Engineering at Atatürk University, Turkey. Her academic and scientific work focuses primarily on hydrogen energy technologies, proton exchange membrane (PEM) fuel cells, oxygen reduction reactions, catalyst development, and nanomaterials engineering. Her research contributions are associated with improving the efficiency, durability, and sustainability of fuel cell systems through advanced catalyst supports and hydrophobic material innovations.[1] She has contributed to multiple scientific publications, conference presentations, and scholarly book chapters related to electrochemical energy conversion and fuel cell technology.[2]

Abstract

This academic article presents the scholarly profile and research accomplishments of Ayşenur Öztürk Aydin in the fields of hydrogen energy systems, proton exchange membrane fuel cells, and nanomaterials engineering. Her research activities emphasize catalyst durability, carbon-based support structures, hydrophobic material integration, and electrochemical performance optimization for PEM fuel cells. Through interdisciplinary approaches involving chemical engineering and material science, she has contributed to the advancement of sustainable energy technologies and efficient hydrogen-powered systems.[3] Her scientific record includes SCI-indexed journal publications, conference presentations, and book chapters focused on improving fuel cell performance and long-term operational stability.[1]

Keywords

Hydrogen energy, PEM fuel cells, oxygen reduction reaction, nanomaterials, catalyst supports, electrochemical engineering, fuel cell durability, carbon nanostructures, hydrophobic materials, renewable energy systems.

Introduction

The increasing global demand for sustainable and environmentally responsible energy systems has intensified research efforts in hydrogen energy and fuel cell technologies. Proton exchange membrane fuel cells have emerged as a promising clean-energy solution due to their high efficiency and low emissions profile.[4] Research in this domain requires improvements in catalyst efficiency, material durability, and water management systems to achieve large-scale commercial feasibility.

Ayşenur Öztürk Aydin has contributed to these objectives through experimental and applied research focused on catalyst support materials, hydrophobic component development, and nanomaterial-based electrochemical systems. Her academic work reflects a combination of chemical engineering principles and material characterization methodologies designed to improve operational efficiency and performance longevity in PEM fuel cells.[2]

Research Profile

Ayşenur Öztürk Aydin completed her Bachelor of Science degree in Chemical Engineering at Hacettepe University in 2013 and later obtained a second Bachelor of Science degree in Chemistry from Atatürk University in 2022.[5] Her MSc research focused on hydrophobic materials for enhanced water management in PEM fuel cells, while her doctoral research investigated heat-treated carbon-based catalyst supports for platinum and platinum-cobalt catalysts in PEM fuel cells.

Since 2014, she has served within the Department of Chemical Engineering at Atatürk University and has participated in multiple research projects related to electrochemical energy systems and advanced material synthesis. Her academic profile includes six completed or ongoing research projects, fifteen SCI-indexed journal articles, twenty-two conference presentations, and five book chapters indexed in BKCI publications.[1]

  • Field of specialization: Hydrogen energy systems and PEM fuel cells
  • Research methodology: Electrochemical characterization and nanomaterial synthesis
  • Primary focus: Catalyst durability and energy efficiency enhancement
  • Academic outputs: SCI-indexed publications and scholarly book chapters

Research Contributions

The research contributions of Ayşenur Öztürk Aydin primarily involve the development of durable catalyst supports and hydrophobic materials for PEM fuel cell systems. Her investigations explored heat-treated carbon-based supports capable of enhancing catalytic activity and long-term operational stability in platinum-based catalysts.[6]

Another major area of contribution includes improving water management within PEM fuel cells through novel hydrophobic materials integrated into gas diffusion layers and catalyst layers. Efficient water management is essential to prevent flooding and optimize electrochemical reactions in fuel cells.[7]

Her future research direction involves designing multifunctional nanomaterials combining synthesized carbon structures with metallic and non-metallic catalysts to improve electrochemical efficiency, durability, and commercial applicability of hydrogen fuel cell technologies.[3]

Publications

Ayşenur ÖZTÜRK AYDIN has authored 15 SCI-indexed research articles focusing on hydrogen energy technologies, PEM fuel cells, catalyst supports, and nanomaterials engineering. Her publications emphasize improving electrochemical performance, catalyst durability, and water management systems in fuel cells. She has also contributed 5 BKCI-indexed book chapters and presented 22 papers at national and international scientific conferences.

Research Impact

The research activities of Ayşenur Öztürk Aydin contribute to the broader scientific objective of advancing clean-energy technologies and hydrogen-based energy systems. By improving catalyst performance and fuel cell durability, her work supports ongoing efforts toward sustainable transportation and renewable power generation.[4]

Her work on hydrophobic materials and catalyst support structures demonstrates practical engineering relevance for improving PEM fuel cell reliability and operational efficiency. These developments are significant for reducing energy losses, enhancing electrochemical stability, and supporting future industrial implementation of fuel cell systems.[7]

Award Suitability

Ayşenur Öztürk Aydin demonstrates strong suitability for the Research Excellence Award based on her sustained contributions to hydrogen energy technologies, catalyst engineering, and PEM fuel cell innovation. Her interdisciplinary research profile combines chemical engineering, nanotechnology, and electrochemical science with measurable scholarly outputs and scientific dissemination activities.[3]

The combination of peer-reviewed publications, conference participation, advanced materials research, and long-term academic engagement highlights her active role in the development of sustainable energy technologies. Her research aligns with global scientific priorities focused on renewable energy systems and environmentally responsible engineering solutions.[6]

Conclusion

Ayşenur Öztürk Aydin has established an academic profile centered on advanced fuel cell systems, catalyst materials, and hydrogen energy research. Her work contributes to ongoing scientific advancements in sustainable energy engineering through the development of durable catalyst supports and improved PEM fuel cell components. Her publication record, research activities, and future-oriented investigations reflect continued engagement with emerging energy technologies and nanomaterial applications within electrochemical engineering.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Ayşenur Öztürk Aydin, Author ID 25122757500. Scopus.https://www.scopus.com/authid/detail.uri?authorId=25122757500
  2. Google Scholar. (n.d.). Academic citation profile of Ayşenur Öztürk Aydin.https://scholar.google.com.tr/citations?user=GzRQ6QoAAAAJ&hl=tr
  3. ResearchGate. (n.d.). Research profile and publications of Ayşenur Öztürk Aydin.https://www.researchgate.net/profile/Aysenur-Oeztuerk-Aydin
  4. International Energy Agency. (2024). Hydrogen and fuel cell technology overview.https://www.iea.org/reports/global-hydrogen-review-2024
  5. Atatürk University. (n.d.). Department of Chemical Engineering academic information.https://www.atauni.edu.tr/
  6. Journal of Power Sources. (2019). Carbon-supported catalyst systems for PEM fuel cells.DOI: https://doi.org/10.1016/j.jpowsour.2019.226933
  7. Electrochimica Acta. (2020). Hydrophobic layer engineering and water management in PEM fuel cells.DOI: https://doi.org/10.1016/j.electacta.2020.136992

Assist. Prof. Dr. Minakshi | Chemistry | Women Researcher Award

Published on by World Science Awards

Assist. Prof. Dr. Minakshi | Chemistry | Women Researcher Award

Indira Gandhi University, Meerpur, Rewari Haryana, India

Featured Publications

Vircava, I.; Skapste, I.; Skutele, K.; Žaimis, U.; Grinberga-Zalite, G. (2026).
Substrate-Dependent Responses of Radish to Anaerobically Fermented Furcellaria lumbricalis Biostimulant Under Reduced Mineral Fertilization
Agronomy · 2026 · DOI: 10.3390/agronomy16080837

Skapste, I.; Grinberga-Zalite, G.; Zvirbule, A.; Vircava, I.; Skutele, K. (2025).
A Comprehensive Analysis and Quantitative Assessment of the Regulatory Framework and Impacts of the Seaweed Sector in the Baltic Sea Region
SGEM Conference Proceedings · 2025 · DOI: 10.5593/sgem2025/5.1/s20.035

Skapste, I.; Vircava, I.; Skutele, K.; Žaimis, U.; Grinberga-Zalite, G.; Zvirbule, A. (2025).
Algae Digestate Biostimulants as an Innovative Solution for Food System Sustainability and Productivity Improvement
Frontiers in Sustainable Food Systems · 2025 · DOI: 10.3389/fsufs.2025.1656867

Skapste, I.; Grinberga-Zalite, G.; Zvirbule, A.; Vircava, I.; Skutele, K. (2025).
Commercialisation Potential of Algal Biostimulants in the Baltic Sea Region: Regulatory Implications and Economic Aspects
SGEM Conference Proceedings · 2025 · DOI: 10.5593/sgem2025/5.1/s20.041

Skapste, I.; Balina, K.; Žaimis, U.; Grinberga-Zalite, G.; Zvirbule, A. (2025).
Life Cycle Assessment of Furcellaria lumbricalis Biostimulant Production: Towards Circular Bioeconomy in the Baltic Sea Region
European Biomass Conference and Exhibition Proceedings · 2025

Mahendra Aryal | Chemical Engineering | Best Academic Researcher Award

Published on by World Science Awards

Dr. Mahendra Aryal | Chemical Engineering | Best Academic Researcher Award

Tribhuvan University | Nepal

Dr. Mahendra Aryal is a chemist and environmental biotechnology researcher with extensive experience in bioremediation, biosorption, water quality, waste valorization, and environmental sustainability. He holds a PhD from Aristotle University of Thessaloniki, Greece, and completed postdoctoral research on the valorization of winery wastes using eco-friendly technologies. Dr. Aryal has authored 30+ peer-reviewed publications in high-impact international journals, accumulating hundreds of citations, and has actively collaborated with researchers across Europe and South Asia. His work bridges fundamental chemistry with applied environmental solutions, contributing to safe water management, pollution mitigation, and circular bioeconomy practices. In addition to his research, he is an experienced academic, journal editor, and reviewer, and a recipient of national and international research awards, reflecting his sustained scientific and societal impact.

Citation Metrics (Scopus)

600
500
300
100

Citations
667

Documents
20

h-index
11

Citations

Documents

h-index

Scopus Profile

ORCID iD

Google Scholar

 

Featured Publications

 

 

Wang Haiyan | Chemistry | Research Excellence Award

Published on by World Science Awards

Assoc. Prof. Dr. Wang Haiyan | Chemistry | Research Excellence Award

Zhejiang Normal University | China

Assoc. Prof. Dr. Wang Haiyan is a member of the Communist Party of China, an Associate Professor, and a Master’s Supervisor at Zhejiang Normal University. He was selected to the Clarivate Analytics Top 2% Global Scientists list for 2022–2025. He earned his Ph.D. in Chemistry from Zhejiang University under the supervision of Prof. Yong Wang (National Outstanding Young Scientist). During his doctoral training, he also conducted joint research at the Institute of Metal Research, Chinese Academy of Sciences, guided by Researcher Feng Li (National Outstanding Young Scientist). Dr. Wang’s research lies at the intersection of inorganic nanomaterial synthesis and advanced energy storage and conversion systems, including electrocatalysis, hybrid capacitors, and energy-relevant nanostructures. He has authored more than 70 SCI-indexed publications in leading journals such as Nature Communications, Journal of the American Chemical Society, Advanced Energy Materials, Advanced Functional Materials, Nano Energy, ACS Catalysis, and Applied Catalysis B: Environmental. Among his publications, four have been recognized as ESI Hot Papers and eleven as ESI Highly Cited Papers, reflecting strong global influence. His work currently holds an h-index of 38. Dr. Wang has led nine research projects supported by national and provincial funding bodies, including the National Natural Science Foundation of China and the China Postdoctoral Science Foundation. His research contributions have been acknowledged through multiple honors, including a First Prize in the China Association of Inventions Entrepreneurship Innovation Award. Dr. Wang is also highly active in academic mentorship and innovation education. His students have earned numerous prestigious awards, including the Gold Medal at the China International College Student Innovation Competition and top honors in provincial “Challenge Cup” and “Internet+” competitions. He has been recognized as an Outstanding Innovation and Entrepreneurship Mentor and currently serves as Vice President of Technology for a carbon-neutrality-focused enterprise. Additionally, he serves on multiple editorial and technical committees and reviews for leading international journals.

Profile: Scopus

Featured Publications

  1. (2026). In situ manipulation of interfacial water in Ni-Co₃O₄ for efficient neutral nitrate electroreduction to ammonia. Applied Catalysis B: Environmental.

  2. (2025). Reciprocal enhancement of iodine and manganese redox kinetics towards high-performance rechargeable zinc-iodine-manganese hybrid batteries. Journal of Energy Chemistry.

  3. (2025). Enhanced energy storage density and efficiency in A/B-site-engineered silver niobate ceramics. Ceramics International.

  4. Electrocatalysts in zinc-iodine batteries: Theoretical insights and material design..

  5. Recent progress in the inhibition of metal dendrites in sodium/potassium ion batteries..

 

Ayşe Aytaç | Chemical Engineering | Research Excellence Award

Published on by World Science Awards

Prof. Dr. Ayşe Aytaç | Chemical Engineering | Research Excellence Award

Kocaeli University | Turkey

Prof. Dr. Ayşe Aytaç is a distinguished academic recognized for her extensive contributions to materials science, polymer engineering, and advanced functional composites. Her research primarily focuses on the design and development of high-performance polymeric systems, smart coatings, nanostructured materials, and sustainable composites for applications spanning energy, environment, and industrial innovation. Over the course of her career, she has built a strong publication record, with 103 Scopus-indexed documents, 2,358 citations, and an h-index of 22, reflecting her sustained scientific impact and global research visibility. Her work integrates advanced polymer synthesis, structure–property optimization, interfacial engineering, and multifunctional material design, offering innovative solutions that enhance mechanical resilience, thermal stability, and environmental performance. She has played leading roles in national and international research projects, collaborating with universities, industry partners, and research centers across Europe and other regions. These collaborations have strengthened interdisciplinary knowledge exchange and contributed to the development of materials that address real-world challenges, from eco-friendly polymers to biomedical and engineering applications. In addition to her research achievements, Prof. Dr. Ayşe Aytaç is actively involved in academic leadership, supervising graduate students, participating in editorial and reviewing activities, and contributing to scientific committees. Her commitment to mentorship and scientific excellence has helped shape the next generation of researchers. Through her innovative research, international partnerships, and dedication to societal advancement, she continues to make significant contributions to the global scientific community.

Profiles: Scopus | ORCID | Google Scholar

Features Publications

Karsli, N. G., & Aytac, A. (2013). Tensile and thermomechanical properties of short carbon fiber reinforced polyamide 6 composites. Composites Part B: Engineering, 51, 270–275.

Kemaloglu, S., Ozkoc, G., & Aytac, A. (2010). Properties of thermally conductive micro and nano size boron nitride reinforced silicon rubber composites. Thermochimica Acta, 499(1–2), 40–47.

Karsli, N. G., & Aytac, A. (2011). Effects of maleated polypropylene on the morphology, thermal and mechanical properties of short carbon fiber reinforced polypropylene composites. Materials & Design, 32(7), 4069–4073.

Aydın, M., Tozlu, H., Kemaloglu, S., Aytac, A., & Ozkoc, G. (2011). Effects of alkali treatment on the properties of short flax fiber–poly (lactic acid) eco-composites. Journal of Polymers and the Environment, 19(1), 11–17.

Ozkan, C., Karsli, N. G., Aytac, A., & Deniz, V. (2014). Short carbon fiber reinforced polycarbonate composites: Effects of different sizing materials. Composites Part B: Engineering, 62, 230–235.

Moshe Mello | Chemical Engineering | Editorial Board Member

Published on by World Science Awards

Mr. Moshe Mello | Chemical Engineering | Editorial Board Member

Chemical Engineering | South Africa

Mr. Moshe Mello is an emerging scholar and multidisciplinary engineering professional with expertise spanning chemical engineering, metallurgical production, waste management, and renewable energy systems. He holds a Master of Technology (MTech) in Chemical Engineering from the Vaal University of Technology (VUT), where his postgraduate research focused on the desulfurization of tire pyrolytic oil using adsorption and photodegradation—contributing to ongoing global efforts in sustainable fuel development and circular waste-to-energy technologies. His research outputs include peer-reviewed articles published in the Journal of Air and Waste Management (Taylor & Francis) and Chemical Engineering Transactions, reflecting his growing academic impact within waste valorization and environmental process engineering. Mr. Mello’s professional experience integrates academia, laboratory practice, and metallurgical engineering. As a Junior Lecturer at VUT, he has played a pivotal role in curriculum development for Diploma, Advanced Diploma, BEngTech, and postgraduate programs, particularly in Heat and Mass Transfer, Separation Technologies, and Petroleum Engineering electives. He has supervised undergraduate research projects, contributed to teaching and learning innovation, and supported departmental outreach activities. His earlier work as a Laboratory Technician strengthened his proficiency with analytical equipment, experimental method design, and student mentorship. In industry, Mr. Mello served as a Metallurgical Production Engineer (Training) at Samancor Middelburg Ferrochrome, where he led process optimization initiatives, metallurgical control, electrode management, and mass–energy balance assessments. His notable achievements include reducing coke consumption to 17% in SAF operations, saving the company over 50 million rands annually, and developing a recyclable mould-coating product that expanded production capacity and created new employment opportunities. He also contributed to a Blue Drop certification milestone for a public water treatment facility through collaborative undergraduate research.

Profile: Scopus

Featured Publications

  1. (2023). Semi-empirical modelling for dissolution of calcium from ironmaking slag in ammonium acetate for CO₂ utilization. Engineering Proceedings

 

Yasmin Shabeer | Chemical Engineering | Best Researcher Award

Published on by World Science Awards

Ms. Yasmin Shabeer | Chemical Engineering | Best Researcher Award

University of Waterloo, Canada

Yasmin Shabeer is a highly motivated Ph.D. candidate in Chemical Engineering with a specialization in Electrochemical Engineering and Battery Systems, currently pursuing her doctorate at the University of Waterloo under the supervision of Dr. Michael Fowler. She holds a B.Tech in Rubber and Plastics Technology from Anna University, India, and has gained extensive research experience in high-energy-density aluminum-air batteries, lithium-ion thermal modeling, metal-air battery comparative studies, and corrosion analysis of Al6061 electrodes. Her research focuses on integrating experimental electrochemical techniques, such as electrochemical impedance spectroscopy (EIS), distribution of relaxation time (DRT) analysis, linear sweep voltammetry (LSV), and cyclic voltammetry (CV), with advanced data-driven approaches including machine learning models for predicting polarization behavior, corrosion current density, and impedance parameters, alongside life cycle assessment (LCA) for environmental sustainability. She has contributed to the design, prototyping, and optimization of battery systems through systematic experimental studies, collaboration with industry partners like AlumaPower and Stellantis, and applied modeling using MATLAB, COMSOL, Python, and simulation software for design-of-experiments (DoE). Yasmin has authored five peer-reviewed publications with 111 citations and an h-index of 4, reflecting the impact of her work on the field of sustainable energy storage. She has been recognized with awards including the Bhattacharyya Award, Mitacs Graduate Fellowship, Devani Charities Graduate Award, and International Master’s Award of Excellence, highlighting her academic excellence, innovation, and leadership potential. Beyond research, she has served as a teaching assistant, laboratory manager, Mitacs mentor, and graduate student leader, demonstrating her commitment to education, mentorship, and community engagement. With expertise spanning electrochemical systems, material characterization, battery optimization, AI-assisted modeling, and sustainability analysis, Yasmin combines scientific rigor, interdisciplinary collaboration, and practical innovation, positioning her as a promising future leader in clean energy technology, electrochemical research, and sustainable battery solutions.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

  1. Mevawalla, A., Shabeer, Y., Tran, M. K., Panchal, S., Fowler, M., & Fraser, R. (2022). Thermal modelling utilizing multiple experimentally measurable parameters. Batteries, 8(10), 147

  2. Madani, S. S., Shabeer, Y., Allard, F., Fowler, M., Ziebert, C., Wang, Z., & Panchal, S. (2025). A comprehensive review on lithium-ion battery lifetime prediction and aging mechanism analysis. Batteries, 11(4), 127.

  3. Shabeer, Y., Madani, S. S., Panchal, S., Mousavi, M., & Fowler, M. (2025). Different metal–air batteries as range extenders for the electric vehicle market: A comparative study. Batteries, 11(1), 35.

  4. Madani, S. S., Allard, F., Shabeer, Y., Fowler, M., Panchal, S., & Ziebert, C. (2025). Exploring the aging dynamics of lithium-ion batteries for enhanced lifespan understanding. Journal of Physics: Conference Series, 2968(1), 01201.

  5. Shabeer, Y., Madani, S. S., Panchal, S., & Fowler, M. (2025). Performance optimization of high energy density aluminum–air batteries: Effects of operational parameters and electrolyte composition. Future Batteries, 100082.

Yasmin Shabeer’s work advances the development of high-performance, sustainable energy storage systems by integrating experimental electrochemistry, machine learning, and life cycle assessment. Her research directly contributes to cleaner energy technologies, efficient battery design for electric vehicles, and environmentally responsible industrial applications, driving innovation in both science and industry.

Tian Wang | Chemical Engineering | Best Researcher Award

Published on by World Science Awards

Dr. Tian Wang | Chemical Engineering | Best Researcher Award

Kyung Hee University, China

Dr. Tian Wang is a distinguished researcher in the field of electrochemistry and energy storage materials, holding a Ph.D. in Electronics and Information Convergence Engineering from Kyung Hee University, Korea, with prior M.Sc. and B.Sc. degrees in Materials Physics, Chemistry, and Materials Chemistry from Shaanxi University of Science and Technology, China. He has focused his research on optimizing the Zn electrode/electrolyte interface in aqueous Zn metal batteries, revealing critical effects of interfacial mass and electron transfer on Zn electrochemistry, and successfully developing long-term stable Zn anodes and high-energy quasi-solid-state anode-free Zn metal batteries for potential wearable device applications. His earlier work includes research on MoO2, MoS2, and biomass carbon as anode materials for Li/Na-ion batteries, demonstrating his broad expertise in advanced energy materials. Dr. Wang possesses strong research skills in materials synthesis, electrochemical characterization, interface engineering, nanodevice fabrication, and performance evaluation, complemented by capabilities in experimental design and problem-solving for energy storage applications. He has published 32 documents with over 1,017 citations and holds an h-index of 16, reflecting the high impact of his work in the scientific community. His awards and honors, though not detailed here, recognize his innovation and contributions to energy materials research, highlighting both national and international recognition. Throughout his professional experience, Dr. Wang has demonstrated excellence in leading research projects, collaborating with interdisciplinary teams, mentoring students, and contributing to advancements in battery technologies. In conclusion, Dr. Wang’s combination of theoretical knowledge, experimental expertise, and practical innovation positions him as a leading researcher in the field of energy storage, with significant potential to drive breakthroughs in sustainable energy solutions, wearable electronics, and next-generation battery technologies, reinforcing his role as a visionary contributor to global scientific and technological advancement.

Profiles: Scopus | ORCID

Featured Publications

Wang, T., Tang, S., Xiao, Y., Xiang, W., & Yu, J. S. (2025). Strategies of interfacial chemistry manipulated zinc deposition towards high-energy and long-cycle-life aqueous anode-free zinc metal batteries. Energy & Environmental Science.

Wang, T., Xiao, Y., Xiang, W., Tang, S., & Yu, J. S. (2025, August). Stable zinc electrode/separator interface enabled by phthalocyanine-modified separator for advanced zinc metal batteries. Small.

Wang, T., Xiao, Y., Tang, S., Xiang, W., & Yu, J. S. (2025, June). Unlocking quasi-solid-state anode-free zinc metal batteries through robust bilayer interphase engineering. Advanced Energy Materials.

Wang, T., & Yu, J. S. (2024). Stabilized lithium metal nanocomposite anode for high-performance lithium–sulfur batteries. In Engineering Materials (pp. 1–??). Springer.

Wang, T., Xu, L., Xiang, W., Tang, S., Xiao, Y., & Yu, J. S. (2024, December). Interfacial lattice strain-induced vacancy evolution facilitating highly reversible dendrite-free zinc metal anodes. Advanced Energy Materials.

Dr. Tian Wang’s work on optimizing Zn metal batteries and developing high-energy, stable anode-free systems advances sustainable energy storage technologies, enabling safer and more efficient batteries for wearable devices and grid applications, thereby contributing to global energy innovation, environmental sustainability, and next-generation electronics.