Baolin Liu | Electrochemical energy storage | Best Researcher Award

Published on by Civil Engineering

Dr Baolin Liu | Electrochemical energy storage | Best Researcher Award

Postdoctor, Southern University of Science and Technology, China

Baolin Liu is a dedicated researcher with a strong academic background in chemistry and physics. He holds a Doctor of Science in Chemistry from Xinjiang University and is currently a post-doctoral fellow at the Southern University of Science and Technology. His research focuses on advanced materials for energy storage and conversion, particularly in sodium-ion batteries, supercapacitors, and catalytic applications. With over 30 publications in high-impact journals, Baolin has made significant contributions to the field of materials science. His work emphasizes the development of nanostructured materials, defect engineering, and heterostructures to enhance electrochemical performance. Baolin is also an active member of the scientific community, contributing to various collaborative projects and mentoring students.

Professional Profile

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Education 🎓

  • 2024.01-Present: Post-doctoral Fellow, Physics, Southern University of Science and Technology, China.
  • 2019.09-2023.12: Doctor of Science, Chemistry, Xinjiang University, China.
  • 2016.09-2019.06: Master of Science, Chemistry, Xinjiang University, China.
  • 2014.09-2015.06: Bachelor of Engineering, Chemical Engineering, Beijing University of Chemical Technology, China.
  • 2012.09-2016.06: Bachelor of Engineering, Chemical Engineering, Tarim University, China.

Experience 💼

  • Post-doctoral Research: Focused on advanced materials for energy storage and conversion, including sodium-ion batteries and supercapacitors.
  • Doctoral Research: Specialized in catalytic materials for CO oxidation and coal liquefaction, with expertise in nanostructured materials and defect engineering.
  • Collaborative Projects: Worked on interdisciplinary projects involving nanomaterials, electrochemistry, and catalysis.
  • Mentorship: Guided graduate and undergraduate students in research methodologies and experimental techniques.

Awards and Honors 🏆

  • Scopus Author ID: Recognized for high-impact publications in materials science and chemistry.
  • Research Excellence: Multiple papers published in top-tier journals like Journal of Colloid and Interface ScienceSmall, and Chemical Engineering Journal.
  • Collaborative Achievements: Contributed to projects funded by national and institutional grants.
  • Academic Recognition: Received accolades for innovative research in energy storage and catalytic materials.

Research Focus 🔬

Baolin Liu’s research focuses on the design and synthesis of advanced materials for energy storage and conversion. His work includes:

  • Sodium-ion Batteries: Developing high-performance anode materials using nanostructured composites and defect engineering.
  • Supercapacitors: Exploring carbon-based materials and heterostructures for enhanced electrochemical performance.
  • Catalysis: Investigating catalytic materials for CO oxidation, hydrogenation, and environmental applications.
  • Nanomaterials: Engineering nanostructured materials with tailored properties for energy and catalytic applications.

Publication Top Notes 📚

  1. 2D heterostructural Mn2O3 quantum dots embedded N-doped carbon nanosheets with strongly stable interface enabling high-performance sodium-ion hybrid capacitors
  2. Construction of WS2/NC@C nanoflake composites as performance-enhanced anodes for sodium-ion batteries
  3. Enhancing sodium-ion battery performance through crystalline water-assisted Zn2V2O7 anode material
  4. High quality bifunctional cathode for rechargeable zinc-air batteries using N-doped carbon nanotubes constrained CoFe alloy
  5. Metal-electronegativity-induced sulfur-vacancies and heterostructures of MnS1-x/ZnS-NC@C with dual-carbon decoration for high-performance sodium-ion storage
  6. Nano-bowl-like carbon confined 1T/2H-MoS2 hybrids as anode for high-performance sodium-ion storage
  7. Remarkable upgrade of hydrogen evolution activity up to 40.8 folds and mechanistic investigation of expediting charge transfer achieved by Bi2O3-modified TiO2 photocatalyst
  8. Structure and Defect Engineering of V3S4−xSex Quantum Dots Confined in a Nitrogen-Doped Carbon Framework for High-Performance Sodium-Ion Storage
  9. Synergistic promotion for the performance of photocatalytic carbon dioxide reduction by vacancy engineering and N-doped carbon nanotubes
  10. Bi@C sandwiched carbon nanolayers enables remarkable cyclability at high current density for lithium-ion batteries
  11. Construction of oxygen vacancies and heterostructure in VO2-x/NC with enhanced reversible capacity, accelerated redox kinetics, and stable cycling life for sodium ion storage
  12. Honeycomb carbon obtained from coal liquefaction residual asphaltene for high-performance supercapacitors in ionic and organic liquid-based electrolytes
  13. Oxygen self-doped hierarchical porous carbons derived from coal liquefaction residue for high-performance supercapacitors in organic and ionic liquid-based electrolytes
  14. Sulfur-Bridged Bonds Heightened Na-Storage Properties in MnS Nanocubes Encapsulated by S-Doped Carbon Matrix Synthesized via Solvent-Free Tactics for High-Performance Hybrid Sodium Ion Capacitors
  15. Constructing ultrafine Cu nanoparticles encapsulated by N-doped carbon nanosheets with fast kinetics for high-performance lithium/sodium storage
  16. Phosphorus/sulfur co-doped hard carbon with a well-designed porous bowl-like structure and enhanced initial coulombic efficiency for high-performance sodium storage
  17. Solid-State Construction of CuOx/Cu1.5Mn1.5O4 Nanocomposite with Abundant Surface CuOx Species and Oxygen Vacancies to Promote CO Oxidation Activity
  18. Copper-based catalysts for CO oxidation, 用于CO氧化的铜基催化剂研究进展
  19. In-situ impregnation of β-FeOOH on coal by solid-state reaction toward direct coal liquefaction
  20. Insight into the Crystal Structures and Surface Property of Manganese Oxide on CO Catalytic Oxidation Performance
  21. A “two-pronged” strategy: Boosting electrocatalytic oxygen reduction reaction property based on the Ni–MnO synergistic effect and high conductivity of rod-like Ni–MnO/N–C composites prepared via simple solution-free route
  22. Engineering CuOx–ZrO2–CeO2 nanocatalysts with abundant surface Cu species and oxygen vacancies toward high catalytic performance in CO oxidation and 4-nitrophenol reduction
  23. The solid-state in situ construction of Cu2O/CuO heterostructures with adjustable phase compositions to promote CO oxidation activity
  24. Fe3O4 Nanoparticles Supported on Modified Coal toward Catalytic Hydrogenation of Coal to Oil
  25. Solvent‐Free Chemical Approach to Synthesize Co Nanoparticles Supported on N‐doped Porous Carbon for Efficient Electrocatalytic Oxygen Reduction
  26. Room-Temperature Solid-State Preparation of CoFe2O4@Coal Composites and Their Catalytic Performance in Direct Coal Liquefaction
  27. Cu/Cu2O/rGO nanocomposites: solid-state self-reduction synthesis and catalytic activity for p-nitrophenol reduction
  28. Optimum Balance of Cu + and Oxygen Vacancies of CuO x ‐CeO 2 Composites for CO Oxidation Based on Thermal Treatment
  29. V-modified Co3O4 nanorods with superior catalytic activity and thermostability for CO oxidation

Conclusion 🎯

Baolin Liu is a highly deserving candidate for the Best Researcher Award. His prolific publication record, innovative research contributions, and interdisciplinary expertise make him a standout researcher in materials science and chemistry. While there are areas for improvement, such as expanding international collaborations and industry engagement, his strengths far outweigh these considerations. His work has already made a significant impact, and with continued dedication, he is poised to achieve even greater heights in his research career.

CENKER AKTEMUR | Energy | Best Researcher Award

Published on by Civil Engineering

Assist. Prof. Dr CENKER AKTEMUR | Energy | Best Researcher Award

Assistant Professor, Sivas University of Science and Technology, Turkey

Asst. Prof. Dr. Cenker Aktemur is a distinguished academic in Mechanical Engineering, specializing in thermodynamics, refrigeration systems, energy storage, and renewable energy. He completed his PhD at Kocaeli University, focusing on solar-assisted absorption and vapor compression cascade refrigeration systems. Dr. Aktemur’s extensive academic journey includes earning his MSc and BSc from Eastern Mediterranean University. Currently, he serves as an Assistant Professor at Sivas University of Science and Technology. Dr. Aktemur has an impressive publication record with notable works in energy analysis and optimization, showcasing his dedication to sustainability and energy efficiency.

PROFESSIONAL PROFILE

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STRENGTHS FOR THE AWARDS

  1. Extensive Academic Background
    • PhD in Mechanical Engineering with a focus on thermodynamics and renewable energy at Kocaeli University, supported by a prestigious scholarship under CoHE’s 100/2000 Program.
    • Master’s and Bachelor’s degrees in Mechanical Engineering, demonstrating a robust foundation in the field and fluency in English as the medium of education.
  2. Research Excellence
    • Published extensively in high-impact journals, covering topics like energy systems, thermodynamics, and renewable energy technologies.
    • Citations reflect strong contributions to refrigeration, thermal management, and sustainable energy systems, with notable works like:
      • Energy and exergy analysis of environmentally friendly refrigerants.
      • Optimization studies for insulation and energy savings.
  3. Professional Experience
    • Current role as an Assistant Professor at Sivas University of Science and Technology, leading research and academic initiatives.
    • Previous industrial experience as an R&D Engineer at CMAK Crane Systems, adding a practical dimension to theoretical expertise.
  4. Recognition and Awards
    • Scholarships for both undergraduate and graduate studies.
    • Consistent academic excellence, highlighted by Certificates of Honor and High Honor during undergraduate education.
  5. Interdisciplinary Focus
    • Expertise spans thermodynamics, refrigeration, solar energy, energy storage, and energy management, making a versatile and impactful researcher.

AREAS FOR IMPROVEMENT

  1. Collaboration and Visibility
    • Expanding international collaborations can increase the global visibility of research and diversify perspectives.
    • More active participation in international conferences and symposia to enhance networking opportunities.
  2. Grant Acquisition and Projects
    • Leadership in obtaining competitive research grants could further validate the impact and applicability of research.
    • Initiating or leading large-scale projects on renewable energy systems would strengthen professional credentials.
  3. Broader Dissemination
    • While publications are numerous, outreach through public lectures, workshops, or policy recommendations could amplify the societal impact of research.

EDUCATION

🎓 PhD in Mechanical Engineering – Kocaeli University (2018-2023)

  • Dissertation: Thermodynamic Performance Enhancement of Solar-Assisted Absorption and Vapor Compression Cascade Refrigeration Cycle
    🎓 MSc in Mechanical Engineering – Eastern Mediterranean University (2015-2017)
  • Thesis: Energy and Economic Analyses of Natural Gas Heating Systems
    🎓 BSc in Mechanical Engineering – Eastern Mediterranean University (2010-2015)
  • Capstone Project: Design and Manufacturing of Reverse Shoulder Prosthesis

EXPERIENCE

💼 Assistant Professor – Sivas University of Science and Technology (2024–Present)
💼 R&D Engineer – CMAK Crane Systems (2023-2024)

AWARDS AND HONORS

🏆 PhD Scholarship from CoHE 100/2000 Program (2018-2022)
🏆 MSc Scholarship (100%) and BSc Scholarship (50%) (2010-2017)
🏆 Certificates of Honor and High Honor during Undergraduate Studies (2011-2015)

RESEARCH FOCUS

🔬 Thermodynamic optimization of refrigeration systems
🔬 Renewable energy integration with advanced energy storage
🔬 Energy management and efficiency
🔬 Sustainable thermodynamic cycles

PUBLICATION TOP NOTES

  • Comparative energy and exergy analysis of a subcritical cascade refrigeration system using low global warming potential refrigerants 🌍
  • Optimum insulation thickness for the exterior walls of buildings in Turkey 🏠
  • Energy and exergy analysis of a subcritical cascade refrigeration system with internal heat exchangers ♻️
  • Thermodynamic performance enhancement of booster-assisted ejector expansion refrigeration systems 🌞
  • An overview of natural gas as an energy source for various purposes 🔥
  • Thermodynamic optimization of booster-ejector vapor compression refrigeration systems with R152a/Cu nano-refrigerant 🌱
  • A comparison of optimization techniques for energy systems design 🤖
  • Determination of optimum insulation thicknesses for Turkey’s climate regions 🌐
  • Optimization on the thermal insulation layer thickness in buildings 📐
  • Estimation of heating energy requirement and fuel consumption in prototype buildings 🏢
  • Optimizing insulation thickness based on wall orientations 🌅
  • Thermodynamic optimization of LiBr+LiCl/H2O absorption chillers 🌡️
  • Advanced exergy approaches on R41/R1233ZD cascade refrigeration systems 🧪
  • Energetic analysis of solar-driven absorption refrigeration systems ☀️
  • Integrated ORC-VCR system assessment 🔧
  • Overview of trigeneration systems 📊

CONCLUSION

Cenker Aktemur demonstrates a remarkable combination of academic rigor, research productivity, and professional expertise. His work in thermodynamic performance optimization and energy-efficient systems addresses critical global challenges in energy sustainability. While opportunities exist to broaden his influence through collaborations and leadership in large-scale projects, his accomplishments and trajectory strongly position him as a deserving candidate for the Best Researcher Award.

Fanghua Li | Geothermal Energy | Best Researcher Award

Published on by Civil Engineering

Dr Fanghua Li | Geothermal Energy | Best Researcher Award

Research Assistant, Guangxi University, China

Dr. Fanghua Li is a distinguished scholar in civil and communication engineering, currently a PhD candidate at Guangxi University, China. He has worked across a range of engineering disciplines, focusing on urban heat island effects, permeability in concrete, and advanced pavement technologies. Dr. Li has made significant contributions to research in both theoretical and applied aspects of energy efficiency, particularly in cold regions and urban planning. With multiple publications in prestigious journals and several notable projects under his belt, Dr. Li is at the forefront of innovative solutions in sustainable infrastructure. His research is particularly focused on integrating heat flux management and cooling technologies in urban environments, contributing to the development of energy-efficient materials and designs.

Profile

Scopus

Strengths for the Award

Dr. Fanghua Li demonstrates exceptional strength in applied research in civil engineering, particularly in areas related to urban heat management, energy efficiency, and sustainable infrastructure. His work on evaporation resistance characteristics in permeable concrete and its impact on the urban heat island effect, as well as his studies on the reflectivity of roadbeds in cold regions, aligns well with current global environmental and sustainability priorities. He has published multiple highly regarded articles in top-tier journals, such as Cold Regions Science and Technology, Energy and Buildings, and Solar Energy, highlighting his profound impact on his field. His research has been widely cited, with over 590 citations across 480 documents, indicating that his work is not only innovative but also highly influential in advancing understanding and practical applications. Furthermore, his involvement in managing key laboratory projects and contributing to national science foundations emphasizes his leadership and collaborative skills.

Areas for Improvements

While Dr. Li’s research contributions are impressive, expanding his focus to include more interdisciplinary studies could further enhance the depth of his work. For example, exploring the integration of his civil engineering expertise with the latest advancements in artificial intelligence (AI) or machine learning for predictive modeling of urban infrastructure would be a valuable next step. Additionally, while his work is highly technical, expanding into more policy-driven research that examines how engineering solutions can be integrated at a government or societal level could bridge the gap between academia and practical, large-scale implementation.

Another area of improvement could be the exploration of emerging materials and technologies, such as nanotechnology or bio-based construction materials, in the context of urban cooling and energy efficiency. This could keep his work at the cutting edge of sustainable engineering and ensure that his research stays relevant in a rapidly changing technological landscape.

Education

Dr. Fanghua Li’s educational journey reflects his deep commitment to the field of engineering. He is currently pursuing a PhD in Civil Engineering at Guangxi University, focusing on sustainable urban infrastructure. He earned a Master’s degree in Communication Engineering from Hunan University (2012) and a Bachelor’s degree in Communication Engineering from Xi’an University of Technology (2009). His academic foundation spans both civil and communication engineering, allowing him to bridge the gap between infrastructure design and advanced communication systems. Dr. Li has participated in various research initiatives that blend his knowledge of engineering and technology, resulting in meaningful contributions to environmental and energy-efficient engineering solutions.

Experience

Dr. Fanghua Li’s professional experience spans over a decade, with significant roles in both academia and industry. From 2012 to 2013, he worked at the Huizhou Branch of China Mobile in network maintenance, where he honed his technical expertise in communication systems. From 2013 to 2020, he managed key laboratory operations at Guangxi University, gaining in-depth experience in research management and laboratory supervision. His role involved overseeing scientific projects focused on energy efficiency, urban heat management, and sustainable construction materials. His work continues to shape his academic and research output, with a focus on integrating innovative solutions in civil engineering and communication technologies to address pressing environmental challenges.

Awards and Honors

Dr. Fanghua Li has received numerous accolades for his outstanding contributions to research in civil and communication engineering. Among his most notable achievements are his successful completion of NSFC (National Natural Science Foundation of China) Youth Projects and his research on permeability in concrete and urban heat island mitigation. His work has earned recognition from multiple academic and industry bodies. Dr. Li has consistently ranked highly in collaborative research projects, including those related to reflectivity and cooling technologies in cold regions. His scholarly contributions have garnered him a strong citation record, with his work influencing both academia and industry in sustainable infrastructure design.

Research Focus

Dr. Fanghua Li’s research focuses on sustainable engineering solutions for urban environments, with particular emphasis on managing heat flux, permeability in materials, and improving energy efficiency. His work examines the urban heat island effect, the cooling performance of reflective surfaces, and the behavior of pavements and roadbeds in cold regions. He is also interested in advancing urban infrastructure materials, specifically in reducing the impact of extreme temperatures on urban areas. Additionally, Dr. Li explores the integration of nanomaterials in energy storage systems, paving the way for more sustainable building and construction practices. His research seeks to address both environmental and technical challenges by combining theoretical studies with practical applications.

Publication Top Notes

  1. Experimental study on the cooling performance of shading boards with different emissivities at the underside 🌞📚 Cold Regions Science and Technology, 2020
  2. An Innovative Simplified Approach for Conductive Heat Flux in Pavement Structures 🔥🏙 Energy and Buildings, 2024
  3. A side-by-side comparison of the cooling effect of building blocks with retro-reflective and diffuse-reflective walls 🏢🌞 Solar Energy, 2016
  4. A Scientometric Examination on Geothermal Energy Application Research 🌍💡 Renewable Energy, 2024
  5. Free convection simulation of hybrid nanomaterial in permeable cavity with inclusion of magnetic force ⚙️🔬 Journal of Molecular Liquids, 2021
  6. Influences of imposed magnetic force on treatment of hybrid nanofluid involving non-Darcy porous model 🔬🌡 International Communications in Heat and Mass Transfer, 2021
  7. Melting process of nanoparticle enhanced PCM through storage cylinder incorporating fins ❄️🔋 Powder Technology, 2021
  8. Performance of ventilation system involving thermal storage unit considering porous media 🌬️💨 Journal of Energy Storage, 2020
  9. Finned unit solidification with use of nanoparticles improved PCM 💡🔬 Journal of Molecular Liquids, 2020
  10. Numerical study for nanofluid behavior inside a storage finned enclosure involving melting process 🔧❄️ Journal of Molecular Liquids, 2020
  11. Moist curing increases the solar reflectance of concrete 🌞🏗️ Construction and Building Materials, 2019
  12. The amplitude and maximum of daily pavement surface temperature increase linearly with solar absorption 🌞🌍 Road Materials and Pavement Design, 2017

Conclusion

Dr. Fanghua Li is highly deserving of the Best Researcher Award. His robust academic background, leadership in managing complex research projects, and his pioneering contributions to urban cooling technologies and sustainable infrastructure design make him a strong candidate for this recognition. His ability to contribute to both theoretical and applied aspects of engineering, combined with a growing citation profile, shows his continued influence in the field. Moving forward, expanding his research to include interdisciplinary methodologies and emerging technologies would only further solidify his place as a leader in the global engineering research community.

Overall, Dr. Li exemplifies the qualities of an outstanding researcher—innovation, impact, and leadership—and would be an excellent choice for the Best Researcher Award.