Ouyang Jing | MicroGrid | Best Researcher Award

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Dr. Ouyang Jing | MicroGrid | Best Researcher Award

Doctor at ZheJiang University Of Technology, China

Jing Ouyang was born in Hubei Province, China, in 1984. She has pursued a distinguished career in electrical and mechanical engineering, contributing significantly to research and development in her field. Currently, she works at the Key Laboratory of E&M, Ministry of Education & Zhejiang Province, Zhejiang University of Technology. Her expertise spans renewable energy, micro-grid systems, and power electronics, making her a key figure in advancing sustainable energy solutions.

Profile

ORCID

EDUCATION

Jing Ouyang obtained her B.S. and M.S. degrees in Electrical Engineering from Wuhan University, China, in 2006 and 2008, respectively. She later pursued her Ph.D. at Zhejiang University of Technology, earning the degree in 2017 from the College of Mechanical Engineering. Her academic journey has provided her with a strong foundation in electrical and mechanical engineering, allowing her to integrate multidisciplinary approaches in her research.

EXPERIENCE

Following her Ph.D., Jing Ouyang engaged in postdoctoral research at Zhejiang University of Technology from 2017 to 2019. Her professional career has been centered at the Key Laboratory of E&M, where she contributes to cutting-edge advancements in renewable energy and micro-grid technologies. Her experience encompasses both theoretical research and practical applications, leading to innovative developments in energy management and power electronics.

RESEARCH INTEREST

Jing Ouyang’s research focuses on renewable energy, micro-grid systems, and power electronics. She explores efficient energy conversion, grid integration of renewable sources, and optimization of distributed energy systems. Her work aims to improve the stability, efficiency, and sustainability of power systems, addressing critical challenges in modern energy infrastructure.

AWARD

Jing Ouyang has been recognized for her outstanding contributions to electrical and mechanical engineering, receiving prestigious accolades for her work in renewable energy systems. Her research in micro-grid technologies and power electronics has earned her academic and industry recognition, reinforcing her status as a leading researcher in sustainable energy development.

PUBLICATION

Jing Ouyang has contributed to numerous scientific journals, focusing on renewable energy and power electronics. Some of her notable publications include:

“Optimization of Micro-grid Energy Management Systems” (2018, Journal of Renewable Energy, cited by 45 articles)

“Advances in Power Electronics for Renewable Energy Integration” (2019, IEEE Transactions on Power Electronics, cited by 60 articles)

“Smart Grid Technologies and Their Future Prospects” (2020, Energy Reports, cited by 30 articles)

“Hybrid Energy Storage Systems for Micro-grids” (2021, Journal of Power Sources, cited by 55 articles)

“Control Strategies for Renewable Energy Systems” (2022, Applied Energy, cited by 40 articles)

“Dynamic Modeling of Distributed Energy Systems” (2023, International Journal of Electrical Power & Energy Systems, cited by 50 articles)

“Optimization Techniques in Power Electronics for Sustainable Energy” (2024, Renewable & Sustainable Energy Reviews, cited by 35 articles)

CONCLUSION

With her extensive expertise in Renewable Energy, Micro-grid systems, and Power Electronics, Jing Ouyang is highly suitable for the Best Researcher Award. Her contributions to sustainable energy solutions and advanced power systems place her among the leading researchers in her field, making her a strong candidate for this prestigious recognition.

Eliseu Monteiro | Energy | Best Researcher Award

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Assist. Prof. Dr Eliseu Monteiro | Energy | Best Researcher Award

Asssitant Professor, University of Porto, Portugal

Eliseu Leandro Magalhães Monteiro is a distinguished academic and researcher in the field of mechanical engineering and energy systems. With a strong background in combustion, gasification, and renewable energy technologies, he has made significant contributions to the field of sustainable energy solutions. Currently serving as an Assistant Professor at the Universidade do Porto Faculdade de Engenharia, Portugal, Eliseu has a rich history of teaching and research across various prestigious institutions in Portugal. His work focuses on the development of innovative energy recovery systems, particularly through gasification processes, aiming to address global energy challenges and promote environmental sustainability.

Professional Profile

Orcid

Scopus

Education 🎓

Eliseu Monteiro holds a Ph.D. in Engineering Sciences from the Universidade de Trás-os-Montes e Alto Douro, Portugal, where he conducted groundbreaking research on the combustion of mixtures resulting from the gasification of forest biomass. He also earned a Master’s degree in Engineering Technologies, specializing in numerical modeling of solidification in casting, and a Bachelor’s degree in Mechanical Engineering from the same university. His academic journey is marked by a commitment to excellence, earning distinctions and accolades for his research and academic performance.

Experience 💼

Eliseu Monteiro has a wealth of experience in both academia and research. He has held various teaching positions, including Assistant Professor roles at the Universidade do Porto and Universidade de Coimbra. Additionally, he has served as an Adjunct Teacher at the Instituto Politécnico de Portalegre. His research career includes significant contributions to projects funded by the Fundação para a Ciência e a Tecnologia, focusing on gasification processes and renewable energy systems. His work has been instrumental in advancing the understanding and application of gasification technologies for sustainable energy production.

Awards and Honors 🏆

Eliseu Monteiro has received numerous awards and honors throughout his career, recognizing his contributions to the field of engineering and renewable energy. His Ph.D. thesis was awarded with distinction and praise, highlighting the innovative nature of his research. He has also been recognized for his teaching excellence and his role in advancing sustainable energy technologies through various research grants and projects. His work has been published in high-impact journals, further cementing his reputation as a leading figure in his field.

Research Focus 🔬

Eliseu Monteiro’s research focuses on the development and optimization of gasification processes for sustainable energy production. His work encompasses the study of biomass gasification, plasma gasification, and the co-gasification of various waste materials. He is particularly interested in the production of hydrogen-rich syngas and the application of computational modeling to optimize these processes. His research aims to provide innovative solutions for energy recovery from waste materials, contributing to the global transition towards renewable energy sources.

Publication Top Notes 📚

  1. “Energy recovery from infectious hospital waste and its safe neutralization”
  2. “Hydrogen-Rich Syngas Production Based on a Co-Gasification Process Coupled to a Water–Gas Shift Reactor Without Steam Injection”
  3. “Fundamental designs of gasification plants for combined heat and power”
  4. “Hydrogen-Rich Syngas Production from Gasification of Sewage Sludge: Catalonia Case”
  5. “Analysis of Forest Residues pretreatment using solar photovoltaic”
  6. “Air-Blown Biomass Gasification Process Intensification for Green Hydrogen Production: Modeling and Simulation in Aspen Plus”
  7. “Hydrogen supply chain: Current status and prospects”
  8. “Numerical analysis of plasma gasification of hazardous waste using Aspen Plus”
  9. “Some Perspectives for the Gasification Process in the Energy Transition World Scenario”
  10. “On the operating parameters for hydrogen-rich syngas production in a plasma co-gasification process of municipal solid wastes and polypropylene using a constrained model in Aspen plus”
  11. “On the green hydrogen production through gasification processes: A techno-economic approach”
  12. “Parametric studies over a plasma co-gasification process of biomass and coal through a restricted model in Aspen Plus”
  13. “Gasification of Solid Recovered Fuels with Variable Fractions of Polymeric Materials”
  14. “Plasma gasification process using computational fluid dynamics modeling”
  15. “Biomass pre-treatment techniques for the production of biofuels using thermal conversion methods: A review”
  16. “Optimizing the operating conditions for hydrogen-rich syngas production in a plasma co-gasification process of municipal solid waste and coal using Aspen Plus”
  17. “Performance assessment of the co-gasification for sustainable management of municipal solid waste: Moroccan Case”
  18. “A Review on Plasma Gasification of Solid Residues: Recent Advances and Developments”
  19. “Improvement of the Crude Glycerol Purification Process Derived from Biodiesel Production Waste Sources through Computational Modeling”
  20. “Modeling and simulation of a fixed bed gasification process for thermal treatment of municipal solid waste and agricultural residues”
  21. “Numerical modeling of plasma gasification process of polychlorinated biphenyl wastes”
  22. “Techno-economic study for a gasification plant processing residues of sewage sludge and solid recovered fuels”
  23. “Effects of dry and hydrothermal carbonisation on the properties of solid recovered fuels from construction and municipal solid wastes”
  24. “A Comprehensive Review on Biomass Gasification Modified Equilibrium Models”
  25. “Parametric studies in the gasification agent and fluidization velocity during oxygen-enriched gasification of biomass in a pilot-scale fluidized bed: Experimental and numerical assessment”
  26. “Numerical investigation of optimum operating conditions for syngas and hydrogen production from biomass gasification using Aspen Plus”
  27. “Characterization of Municipal, Construction and Demolition Wastes for Energy Production Through Gasification – A Case Study for a Portuguese Waste Management Company”
  28. “Co-Gasification of Sewage Sludge Mixed with Waste Wood in Different Proportions”
  29. “Plasma fixed bed gasification using an Eulerian model”
  30. “Experimental and Modeling Analysis of Brewers´ Spent Grains Gasification in a Downdraft Reactor”
  31. “An Eulerian model for forest residues gasification in a plasma gasifier”
  32. “Numerical approaches and comprehensive models for gasification process: A review”
  33. “Experimental Analysis of Brewers’ Spent Grains Steam Gasification in an Allothermal Batch Reactor”
  34. “A Holistic Review on Biomass Gasification Modified Equilibrium Models”
  35. “A review on occupational risk in gasification plants processing residues of sewage sludge and refuse-derived fuel”
  36. “Energetic valorisation of lignocellulosic and industrial wastes by thermal gasification”
  37. “Modelling higher heating value of different separated fractions from municipal and construction and demolition wastes”
  38. “Solidificação de Metais: Modelação e Simulação”
  39. “Environmental impact and occupational risk in gasification plants processing residues of sewage sludge and refuse-derived fuel: a review”
  40. “Assessment of Municipal Solid Wastes Gasification Through CFD Simulation”
  41. “Fluid dynamics model on fluidized bed gasifier using agro-industrial biomass as fuel”
  42. “Co-gasification and recent developments on waste-to-energy conversion: A review”
  43. “Experimental and modeling studies of Portuguese peach stone gasification on an autothermal bubbling fluidized bed pilot plant”
  44. “REMEDIATION OF A LANDFILL LEACHATE BY ADSORPTION USING ASHES AND BIOCHARS FROM DIFFERENT LIGNOCELLULOSIC RESIDUES WASTES: Solutions, Treatments and Opportunities”
  45. “Biomass resources in Portugal: Current status and prospects”
  46. “Remediation of a landfill leachate by adsorption using ashes and biochars from different lignocellulosic residues”
  47. “An experimental and numerical study on the Miscanthus gasification by using a pilot scale gasifier”
  48. “Assessment of the miscanthus gasification in a semi-industrial gasifier using a CFD model”
  49. “Pulsating Flow Effects on Hydrodynamics in a Desalination Membrane Filled with Spacers”
  50. “Hydrogen production using plasma gasification with steam injection”

Conclusion 🌍

Eliseu Leandro Magalhães Monteiro is a leading figure in the field of mechanical engineering and renewable energy, with a career marked by significant contributions to the development of sustainable energy technologies. His research on gasification processes and computational modeling has provided innovative solutions for energy recovery from waste materials, contributing to the global transition towards renewable energy sources. Through his teaching and research, Eliseu continues to inspire and educate the next generation of engineers, driving forward the field of sustainable energy and environmental conservation.

Xiaohui Zhong | Electrochemical Catalysis | Best Researcher Award

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Dr Xiaohui Zhong | Electrochemical Catalysis | Best Researcher Award

Teacher, School of Chemical and Environmental Engineering, Anhui Polytechnic University, China

Xiaohui Zhong is a dedicated researcher and academic affiliated with the School of Chemical and Environmental Engineering at Anhui Polytechnic University, China. With a strong background in materials science and environmental engineering, she has made significant contributions to the fields of photocatalysis, electrocatalysis, and environmental remediation. Her work focuses on developing innovative materials for sustainable energy conversion and pollution control. Xiaohui is recognized for her expertise in designing advanced nanostructures for applications such as CO2 reduction, water oxidation, and pollutant degradation. She actively collaborates with leading researchers and institutions, contributing to high-impact publications and cutting-edge research projects. Her commitment to advancing green technologies underscores her role as a key figure in addressing global environmental challenges.

Professional Profile

Orcid

Scopus

Education 🎓

Xiaohui Zhong earned her education from prestigious institutions, including a degree from the South China University of Technology in Guangzhou, China. Her academic journey equipped her with a strong foundation in chemical and environmental engineering, focusing on advanced materials and sustainable technologies. Her research during this period laid the groundwork for her expertise in catalysis and nanomaterials. She has since built upon this foundation through continuous learning and collaboration, staying at the forefront of scientific advancements in her field.

Experience 💼

Xiaohui Zhong has extensive experience in academia and research, currently serving as a faculty member at Anhui Polytechnic University. Her professional journey includes collaborations with multidisciplinary teams on projects related to photocatalysis, electrocatalysis, and environmental applications. She has contributed to the development of novel materials for energy conversion and pollution control, publishing her findings in high-impact journals. Her work often involves the synthesis and characterization of nanostructured materials, with a focus on improving their efficiency and stability for real-world applications. Xiaohui’s experience also includes mentoring students and guiding research initiatives aimed at addressing pressing environmental challenges.

Awards and Honors 🏆

Xiaohui Zhong has received recognition for her contributions to materials science and environmental engineering. Her research has been published in top-tier journals, earning her a strong reputation in the scientific community. She has been acknowledged for her innovative approaches to catalysis and sustainable energy solutions. While specific awards are not listed, her consistent publication record and collaborations with leading researchers highlight her standing as a respected figure in her field. Her work continues to inspire advancements in green technologies and environmental remediation.

Research Focus 🔬

Xiaohui Zhong’s research focuses on the development of advanced materials for sustainable energy and environmental applications. Her work spans photocatalysis, electrocatalysis, and environmental remediation, with a particular emphasis on CO2 reduction, water oxidation, and pollutant degradation. She specializes in designing nanostructured materials, such as heterojunctions, doped oxides, and metal-organic frameworks, to enhance catalytic performance. Her research aims to address global challenges like climate change and pollution by creating efficient, stable, and scalable solutions for energy conversion and environmental protection.

Publication Top Notes 📚

  1. Fabrication of cubic PtCu nanocages and their enhanced electrocatalytic activity towards hydrogen peroxide
  2. Improved Surface Charge Transfer in MoO3/BiVO4 Heterojunction Film for Photoelectrochemical Water Oxidation
  3. A wide linear range and stable H2O2 electrochemical sensor based on Ag decorated hierarchical Sn3O4
  4. In3+-doped BiVO4 photoanodes with passivated surface states for photoelectrochemical water oxidation
  5. Enhanced Photoelectrochemical Water Oxidation Performance on BiVO4 by Coupling of CoMoO4 as a Hole-Transfer and Conversion Cocatalyst
  6. Enhanced photoelectrochemical water oxidation on WO3 nanoflake films by coupling with amorphous TiO2
  7. MoO3/BiVO4 heterojunction film with oxygen vacancies for efficient and stable photoelectrochemical water oxidation
  8. Insight into the Improvement Mechanism of Copper Oxide/BiVO4 Heterojunction Photoanodes for Solar Water Oxidation
  9. Boosting solar water oxidation activity and stability of BiVO4 photoanode through the Co-catalytic effect of CuCoO2
  10. Lattice-strained nanotubes facilitate efficient natural sunlight-driven CO2 photoreduction
  11. Biomimetic inspired porphyrin-based nanoframes for highly efficient photocatalytic CO2 reduction
  12. Towards a broad-operation window for stable CO2 electroreduction to HCOOH by a design involving upcycling electroplating sludge-derived Sn@N/P-doped carbon
  13. Tailoring the crystal forms of the Ni-MOF catalysts for enhanced photocatalytic CO2-to-CO performance
  14. Sn Dopants with Synergistic Oxygen Vacancies Boost CO2 Electroreduction on CuO Nanosheets to CO at Low Overpotential
  15. Highly efficient photocatalytic degradation of the emerging pollutant ciprofloxacin via the rational design of a magnetic interfacial junction of mangosteen peel waste-derived 3D graphene hybrid material
  16. Efficient photoreduction of diluted CO2 using lattice-strained Ni1_xSe nanoflowers
  17. Enhancing photocatalytic CO2 reduction reaction on amorphous Ni@NiO aerogel via oxygen incorporated tuning
  18. Boron Dopant Modulated Electron Localization of Tin Oxide for Efficient Electrochemical CO2 Reduction to Formate
  19. Highly dispersed nickel site catalysts for diluted CO2 photoreduction to CO with nearly 100% selectivity
  20. Fe-Ni2P@NPC Synthesized by Trametes Orientalis as an Efficient Electrocatalyst for the Oxygen Evolution Reaction
  21. Photothermal effect improving the activity of spinel MnFe2O4 nanoparticles for the catalytic activation HCO3−/H2O2 to achieve the degradation of dye pollutants in low-temperature condition
  22. Anchoring of NiCox alloy nanoparticles on nitrogen vacancy-rich carbon nitride nanotubes toward promoting efficiently photocatalytic CO2 conversion into solar fuel
  23. Sn/nitrogen-doped carbon composites with enhanced CO2 electroreduction toward formate

Bablu Mordina | Supercapacitor for energy storage application | Innovations in Materials Engineering Award

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Dr Bablu Mordina | Supercapacitor for energy storage application | Innovations in Materials Engineering Award

Scientist ‘E’, DMSRDE (DRDO) , Kanpur

Dr. Bablu Mordina is a distinguished scientist currently serving as Scientist D at the Defence Materials and Stores Research and Development Establishment (DMSRDE), DRDO, Kanpur. He specializes in the development of advanced nanomaterials for sensor and energy applications. With over a decade of experience, Dr. Mordina has contributed significantly to nanocomposites, supercapacitors, microwave absorbers, and eco-friendly materials. He holds 16 international journal publications, 5 Indian patents, and 4 book chapters. Dr. Mordina has presented his research at prestigious conferences and delivered invited talks at renowned institutions.

PROFILE

Scopus

STRENGTHS FOR THE AWARD

  1. Diverse Expertise in Nanomaterials and Sensors: Dr. Bablu Mordina has extensive experience in various cutting-edge fields, including nanomaterials, energy devices, supercapacitors, and magnetic nanoparticles. His work on metal oxide and bio-waste-based carbon nanostructures, supercapacitors, and nanocomposites for microwave absorption is highly relevant in modern research areas, demonstrating his expertise in both material science and energy storage.
  2. Innovative Contributions to Defense and Industry: His contributions to the development of novel nanomaterials for the defense sector, including eco-friendly coolants for radars and vehicles, and high-pressure hydraulic fluids for the Indian Navy, underscore his innovative applications of research to practical problems.
  3. Research Output: With 16 international journal publications, 5 patents, 4 technical reports, and 4 book chapters, Dr. Mordina’s prolific output in academic and applied research demonstrates his significant contribution to the field. His work has been presented at both national and international conferences, reflecting his active engagement in the scientific community.
  4. Recognition and Collaboration: Dr. Mordina has received recognition through citations of his work, showing the impact of his research. Additionally, his role in delivering invited talks at reputed academic and research institutes highlights his ability to disseminate knowledge and collaborate effectively.
  5. Commitment to Advancing Technology: His work in developing magnetorheological elastomers for vibration damping and wear-resistant polymer nanocomposites highlights his commitment to advancing technology with applications in both industrial and defense sectors.

AREAS FOR IMPROVEMENTS

  1. Collaborative Work with Broader Industries: While his work is highly impactful in defense and research, expanding collaborations with broader industrial sectors and non-defense applications could enhance the reach and application of his innovations. This could also provide further avenues for interdisciplinary research.
  2. Increased Public Engagement and Outreach: Although Dr. Mordina has delivered invited talks, expanding his public outreach to communicate his work to a broader audience—including students, policymakers, and the general public—could enhance the visibility and impact of his research.
  3. Diversification of Research Areas: While his work is impressive, focusing on diversifying the range of applications for his nanomaterials and energy devices—perhaps in sustainable energy or health care—could further establish him as a leader in multiple fields.

EDUCATION

🎓 B.Sc. Chemistry (Hons) – University of Calcutta (2002)
🎓 B.Tech. in Polymer Science & Technology – University of Calcutta (2005)
🎓 M.Tech. in Polymer Science & Technology – University of Calcutta (2009)
🎓 Ph.D. in Chemical Engineering – Indian Institute of Technology Kanpur (2017)

EXPERIENCE

🔬 Scientist D, DRDO (2009–Present): Focused on nanomaterials for sensors and energy devices.
🏭 Industrial Experience, Kalpana Industries Ltd. (2 years): Specialized in flexible cable compounds including polyvinyl chloride and polyethylene composites.

AWARDS AND HONORS

🏆 5 Indian Patents
🏆 16 International Journal Publications
🏆 10 Research Papers Presented at Conferences
🏆 8 Invited Talks at Academic and Research Institutes

RESEARCH FOCUS

🔍 Development of nanomaterials for sensors and energy devices.
🔍 Supercapacitors using bio-waste carbon nanostructures.
🔍 Nanocomposites for microwave absorption and vibration damping.
🔍 Eco-friendly coolants and hydraulic fluids for defense platforms.

PUBLICATION TOP NOTES

  1. 📖 Functional Polymer Nanocomposites as Supercapacitors for Health Care
  2. 📖 Structure-Property Relationship in Binder-Free Asymmetric Supercapacitor
  3. 📖 Binder-Free Hybrid Supercapacitor Based on Nickel Ferrite Nanoparticles
  4. 📖 Carbon Nanofibers-Reinforced Polymer Nanocomposites for Microwave Absorption
  5. 📖 Smart Elastomeric Hydrogel Containing Nanosized Barium Ferrite
  6. 📖 Impact of Process Conditions on NiMoO4 Nanorods for Supercapacitors
  7. 📖 Fe3O4 Nanoparticles in Hollow Mesoporous Carbon Nanofibers for Microwave Absorption
  8. 📖 Graphene Oxide in Magnetorheological Hydrogel for Enhanced Behavior
  9. 📖 Friction and Dry Sliding Wear of Bismaleimide with Carbon Nanotubes
  10. 📖 Thermal and Mechanical Properties of Poly(Vinyl Butyral)-Modified Nanocomposites

CONCLUSION

Dr. Bablu Mordina is highly deserving of the Best Researcher Award due to his diverse expertise in nanomaterials, energy devices, and defense-related applications. His extensive research output, industrial experience, and innovative contributions to both academic and defense sectors demonstrate his significant role in advancing modern science. While there are areas for improvement in terms of expanding collaborations and public outreach, his accomplishments make him a standout candidate for the award. His continued focus on developing novel technologies with real-world applications further solidifies his position as a leading researcher in his field.