Qian Sun | Materials Science | Young Scientist Award

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Dr. Qian Sun | Materials Science | Young Scientist Award

Postdoc, Northwestern Polytechnical University, China

Dr. Qian Sun is a Postdoctoral researcher at Northwestern Polytechnical University, specializing in Mechanics of Materials and Shape Memory Alloys. He earned his Ph.D. from Hiroshima University, Japan, in 2024, following a Master’s degree in the same field. His research focuses on Martensitic Phase Transformation, Impact Dynamics, and Thermomechanical Training of materials. Dr. Sun has published widely in high-impact journals and contributed to advancements in the performance of iron-based shape memory alloys. He has also received prestigious awards, including the China Scholarship Council and JASSO Scholarship. 📚🔬📈

 

Publication Profile

Scopus

Orcid

Google Scholar

Work Experience

Since April 2024, Dr. Qian Sun has been serving as a Postdoctoral Researcher at the School of Civil Aviation at Northwestern Polytechnical University. In this role, he continues his pioneering work in Mechanics of Materials, focusing on Shape Memory Alloys and Impact Dynamics. Dr. Sun’s research contributes to advancing the field of civil aviation by enhancing the performance and reliability of materials used in critical applications. His position allows him to combine his expertise in materials science with practical applications in engineering, propelling innovative developments in aerospace technology. 🔧🚀

 

Educational Background

Dr. Qian Sun’s academic journey is marked by a strong foundation in Materials Science and Engineering. He completed his Bachelor’s degree at Nanjing Forestry University, China (2014-2018). He then pursued advanced studies at Hiroshima University, Japan, where he earned his Master’s (2019-2021) and Doctoral degrees (2021-2024) in Mechanics of Materials from the Graduate School of Engineering and the Graduate School of Advanced Science and Engineering. Throughout his academic career, Dr. Sun’s work focused on the development and characterization of Shape Memory Alloys and other advanced materials. 🔬🌍

 

Research Interests

Dr. Qian Sun’s research spans multiple advanced topics in Materials Science. His primary focus is on the Mechanics of Materials, where he explores areas such as Engineering Mechanics and Experimental Mechanics to improve material behavior under various conditions. His work on Impact Dynamics involves studying how materials respond to dynamic forces, while his expertise in Shape Memory Alloys and Martensitic Phase Transformation seeks to enhance material recovery and performance. Additionally, Dr. Sun investigates Materials Characterization and Thermomechanical Training Treatments, aiming to advance the development of high-performance materials for modern engineering applications. 🛠️⚙️

 

Teaching Experience

Dr. Qian Sun has gained valuable teaching experience in the field of Computational Solid Mechanics. From 2021, he served as a Teaching Assistant, supporting students in mastering complex computational methods used in solid mechanics. In 2022, he took on the role of Teaching Fellow, where he not only continued his teaching in computational solid mechanics but also incorporated Japanese language lessons, enabling students to navigate technical content in both English and Japanese. His diverse teaching roles reflect his commitment to educating the next generation of engineers and researchers. 🏫💻

 

Awards and Recognitions

Dr. Qian Sun’s exceptional academic achievements have been recognized through prestigious awards. In 2021, he was honored with the China Scholarship Council award, supporting his advanced studies and research. Prior to that, in 2020, he received the Japan Student Services Organization (JASSO) Scholarship, enabling him to further pursue his academic interests in Japan. These awards underscore Dr. Sun’s commitment to excellence in research and education, reflecting his drive for innovation in materials science and engineering. 🌏🎓

 

Research Focus

Dr. Qian Sun’s research focuses on Mechanics of Materials and Engineering Mechanics, with a particular interest in Shape Memory Alloys (SMAs) and Martensitic Phase Transformation. His work explores the impact dynamics of SMAs, especially in the context of thermo-mechanical treatments and cyclic loading. Dr. Sun has made significant contributions to understanding the shape recovery behavior and deformation characteristics of Fe-Mn-Si alloys. His studies also include advanced materials characterization methods, contributing to the development of additively manufactured SMAs. 🌡️⚙️ His work enhances applications in structural integrity and material performance across engineering fields.

 

Publication Top Notes

  • “Effect of impact deformation on shape recovery behavior in Fe-Mn-Si shape memory alloy under shape memory training process with cyclic thermo-mechanical loading” – Cited by 16, 2021 🌡️
  • “Bending fracture strength of the pipe joint using iron-based shape memory alloy (Fe-SMA) subjected to different expansion methods at various deformation rates” – Cited by 13, 2022 🔧
  • “Effect of deformation rate on the axial joint strength made of Fe-SMA” – Cited by 11, 2022 🏗️
  • “Whole martensitic transformation process in Fe–Mn–Si–Cr shape memory alloy by improved characterization of volume resistivity” – Cited by 7, 2023 🔬
  • “An Evaluation on Strain Rate Sensitivity of Phase Transformation in Fe-28Mn-6Si-5Cr Shape Memory Alloy during Loading and Heating Processes by Measuring Volume Resistivity” – Cited by 1, 2019 ⚙️
  • “An improvement of shape memory effect in Fe-Mn-Si shape memory alloy by training process under impact tensile loading”- 2024 🔄
  • “A Review of Additively Manufactured Iron-Based Shape Memory Alloys” – 2024 🖨️

Shengqiu Zhao | Materials Science | Best Scholar Award

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Dr. Shengqiu Zhao | Materials Science | Best Scholar Award

Dr. Shengqiu Zhao, Foshan Xianhu Laboratory, China

Dr. Shengqiu Zhao 🎓 (Born: 24 February 1997) is a researcher in Materials Science and Engineering at Wuhan University of Technology. He earned his Ph.D. (2018-2024) and B.Sc. in Polymer Materials and Engineering (2014-2018) from the university. His research focuses on hydrogen-electricity conversion technology, developing efficient and stable polymer electrolytes and hydrogen separation methods. Dr. Zhao has contributed to groundbreaking work in proton exchange membranes, including industrial-scale applications in fuel cells and hydrogen production. He has authored multiple high-impact papers 📚, filed several patents 💡, and received prestigious awards 🏅, including the Outstanding Ph.D. Graduate Award.

 

Academic Career 🎓

Dr. Shengqiu Zhao pursued his academic journey in Materials Science and Engineering, beginning with a B.Sc. in Polymer Materials and Engineering from Hunan University of Technology (2014-2018). His dedication led him to Wuhan University of Technology, where he enrolled in a combined Master’s and Ph.D. program in Materials Science and Engineering (2018-2024). Throughout his academic career, Dr. Zhao focused on innovative research in hydrogen-electricity conversion technology and polymer electrolytes, contributing significantly to advancements in fuel cell systems and hydrogen production. His work has earned him recognition in the academic community 📚🏅.

 

Academic Background & Contributions 🔬⚡

Since 2018, Dr. Shengqiu Zhao has focused on overcoming challenges in hydrogen-electricity conversion technology. His research includes designing efficient and stable polymer electrolytes, investigating ion conduction mechanisms, and optimizing membrane interfaces. Key contributions include the cost-effective synthesis of novel polymer electrolytes, which reduces production costs and variability, as well as the development of an efficient electrochemical hydrogen separation method. Additionally, Dr. Zhao has designed high-performance, durable Membrane Electrode Assemblies (MEA) for hydrogen-electricity conversion, enhancing chemical durability and membrane performance. His innovative work supports advancements in clean energy technologies 🌱🔋.

 

Research Projects 🧪🔋

Dr. Shengqiu Zhao has contributed to groundbreaking research in hydrogen energy technologies. From June 2019 to November 2021, he was a key member in developing composite proton exchange membrane engineering technology. This project resulted in high-performance ePTFE-enhanced membranes, leading to China’s first fully indigenous production line for perfluorosulfonic acid proton exchange membranes, with a stable annual capacity of 300,000 m². These membranes have powered hydrogen fuel cell buses, demonstrated at the 2022 Beijing Winter Olympics. Additionally, from March 2022 to September 2023, he contributed to developing melt-extruded multilayer composite membranes for water electrolysis, advancing China’s megawatt-scale hydrogen production unit ⚡🚀.

 

Honors & Awards 🏆🎓

Dr. Shengqiu Zhao has earned numerous prestigious accolades throughout his academic journey. From 2018 to 2024, he was recognized as an Outstanding Ph.D. Graduate and awarded a First-Class Scholarship by Wuhan University of Technology for his exceptional research and academic performance. Earlier, during his undergraduate studies at Hunan University of Technology (2014-2018), he received the Outstanding Undergraduate Graduate of Hunan Province honor and was a recipient of the National Endeavor Scholarship for three consecutive years. These awards highlight his dedication and excellence in the field of materials science and engineering 🎖️🎓.

 

Research Focus 🔬⚡

Dr. Shengqiu Zhao’s research primarily revolves around advancing hydrogen-electricity conversion technologies with a focus on proton exchange membranes (PEMs) for fuel cells and water electrolysis. His work includes the development of durable, high-performance PEMs with enhanced proton conductivity and resistance to degradation. He explores composite membrane engineering, ion-conducting channels, and electrocatalysts to improve fuel cell efficiency. Additionally, Zhao investigates hydrogen separation methods, polymer electrolytes, and material design for sustainable energy systems, aiming to reduce costs, enhance performance, and promote the large-scale application of these technologies in clean energy solutions 🌱🔋.

 

Publication Top Notes 📚

  • Self-Assembly-Cooperating in Situ Construction of MXene–CeO2 as Hybrid Membrane Coating for Durable and High-Performance Proton Exchange MembraneCited by 53, Year 2022 📃🔬
  • Proton-conductive channels engineering of perfluorosulfonic acid membrane via in situ acid–base pair of metal organic framework for fuel cellsCited by 31, Year 2023 ⚡🧪
  • Perfluorosulfonic acid proton exchange membrane with double proton site side chain for high-performance fuel cells at low humidityCited by 24, Year 2023 🔋🌬️
  • Recent advances regarding precious metal-based electrocatalysts for acidic water splittingCited by 24, Year 2022 💧⚡
  • Construction of reliable ion-conducting channels based on the perfluorinated anion-exchange membrane for high-performance pure-water-fed electrolysisCited by 16, Year 2023 💧🔋
  • Polyphenol synergistic cerium oxide surface engineering constructed core-shell nanostructures as antioxidants for durable and high-performance proton exchange membrane fuel cellsCited by 15, Year 2023 ⚙️🌱
  • Hydrophilic channel volume behavior on proton transport performance of proton exchange membrane in fuel cellsCited by 15, Year 2022 💡💧
  • Construction of catalyst layer network structure for proton exchange membrane fuel cell derived from polymeric dispersionCited by 13, Year 2023 🔧⚡
  • Low-Pt anodes with gradient molybdenum isomorphism for high performance and anti-CO poisoning PEMFCsCited by 8, Year 2024 ⚡🧪
  • Proton exchange membranes with functionalized sulfonimide and phosphonic acid groups for next-generation fuel cells operating at 120° CCited by 6, Year 2024 🔋🌡️
  • Sulfur/carbon cathode composite with LiI additives for enhanced electrochemical performance in all-solid-state lithium-sulfur batteriesCited by 5, Year 2023 🔋⚡
  • Rational design of perfluorinated sulfonic acid ionic sieve modified separator for high-performance Li-S batteryCited by 3, Year 2020 🔋🔬
  • Phosphate-grafted polyethyleneimine-induced multifunctional cerium oxide as an antioxidant for simultaneously enhancing the proton conductivity and durability of proton exchange membrane fuel cellsCited by 2, Year 2024 🌿🔬
  • Rationally designing anti-poisoning polymer electrolyte by electronegativity modulation: Towards efficient ammonia-cracked hydrogen fuel cellsCited by 2, Year 2024 💡🔋
  • Highly durable anion exchange membranes with sustainable mitigation of hydroxide attacks for water electrolysisCited by 1, Year 2024 💧🔋
  • Grafting of Amine End-Functionalized Side-Chain Polybenzimidazole Acid–Base Membrane with Enhanced Phosphoric Acid Retention Ability for High-Temperature Proton ExchangeCited by 1, Year 2024 🔬💡
  • Modification of sulfonated poly (arylene ether nitrile) proton exchange membranes by poly (ethylene-co-vinyl alcohol)Cited by 1, Year 2023 🔋💧
  • Evolution of the network structure and voltage loss of anode electrode with the polymeric dispersion in PEM water electrolyzerYear 2024 🔧💡
  • NH3 to H2, Exploration from Pyrolytic Key Materials to Device Structure DesignCited by 0, Year 2023 🔬⚡
  • In situ programming acid-base pair proton-conductive channels of perfluorosulfonic acid membrane for fuel cellsYear 2023 🧪💡

 

SEVIL AKCAGLAR | Materials Science | Best Researcher Award

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Assoc Prof Dr. SEVIL AKCAGLAR | Materials Science | Best Researcher Award

Assoc Prof Dr. SEVIL AKCAGLAR, Department of Mechanical Engineering, Faculty of Engineering, Dokuz Eylül University, Turkey

Assoc. Prof. Dr. Sevil Akçaglar is a renowned scholar specializing in nuclear physics. She earned her Ph.D. in Nuclear Sciences from Ege University (2000) after completing her postgraduate studies in Physics (1991) and an undergraduate degree in Physics Engineering from Selcuk University (1988). Since 1989, she has been serving as an Assistant Professor at Dokuz Eylul University, where she has taught various physics courses 📚, including Research Projects and Physics I. Her research in nuclear physics 💡, combined with over three decades of academic contribution, has solidified her as a leader in the field.

 

Publication Profile

orcid

Education Background 🎓

Assoc. Prof. Dr. Sevil Akçaglar has an extensive educational background in nuclear sciences. She earned her Ph.D. in Nuclear Sciences from Ege University (2000), following her postgraduate studies in Physics at the same institution (1991). Dr. Akçaglar began her academic journey with a Bachelor’s degree in Physics Engineering from Selcuk University (1988). With her strong foundation in nuclear physics and extensive research experience, Dr. Akçaglar has become a prominent figure in the field, contributing significantly to academia and scientific innovation. 💡

 

Research Areas 🔬

Assoc. Prof. Dr. Sevil Akçaglar specializes in the field of nuclear physics, focusing on the behavior and interaction of atomic particles. Her research delves into topics like nuclear reactions, radioactivity, and the development of materials for nuclear energy applications. With her expertise, she contributes to advancing both theoretical and applied aspects of nuclear science, pushing boundaries in energy sustainability and radiation safety. Dr. Akçaglar’s work continues to influence technological innovations in energy production, medical diagnostics, and environmental protection. ⚛️

 

Teaching Contributions 📚

Assoc. Prof. Dr. Sevil Akçaglar has been actively teaching undergraduate courses in physics for several years. Her courses include FİZİK-I and FİZİKI, which she has taught consistently from 2014 to 2021. These courses cover fundamental topics in physics, providing students with a strong foundation in the subject. Additionally, she has taught Research Projects (ARAŞTIRMA PROJESİ) during 2015-2017, guiding students through practical applications of their studies. Dr. Akçaglar’s dedication to education and her interactive teaching style have inspired many future physicists. 🌟

 

Conclusion

With her expertise in nuclear physics, long-standing academic role, and dedication to teaching, Assoc. Prof. Dr. Sevil Akçaglar is a deserving candidate for the Best Researcher Award. Her consistent contributions to nuclear sciences and education align well with the criteria for this prestigious recognition.

 

Publication Top Notes

  • Adsorption of a Paper Industry Dye (Malachite Green) Using MnO2-GO Nanocomposite 🧪 (2022) – Fresenius Environmental Bulletin 🌍
  • Preparation of MoO3/MoS2-E Composite for Enhanced Photoelectrocatalytic Removal of Antimony from Petrochemical Wastewaters ⚗️ (2022) – Turkish Journal of Chemistry  🌿
  • Removal of Co(II) and Se(VI) from Raw Metal and Glass Industry Wastewaters Using Nano-SiO2/ZrO2-Calcium Alginate Aerogels 🏭 (2018) – Sigma Journal of Engineering and Natural Sciences  🌊
  • Development of a Portable Survey Meter System for the Studies of Uranium Discovery ☢️ (2013) – Journal of Radioanalytical and Nuclear Chemistry  ⚛️

Rudi Dungani | Materials Science | Best Researcher Award

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Rudi Dungani | Materials Science | Best Researcher Award

Assoc Prof Dr Rudi Dungani ,Institut Teknologi Bandung, Indonesia

Assoc. Prof. Dr. Rudi Dungani appears to be a strong candidate for the Best Researcher Award. His extensive research and contributions in biocomposites, nanocellulose, and polymer composites align well with criteria for innovation and academic excellence. Here are key points that support his candidacy:

Publication profile

Scopus

  1. Academic and Research Excellence: Dr. Dungani has a diverse academic background, with a Doctorate in Industrial Technology and substantial research grants focused on cutting-edge materials like nanocomposites and biopolymers. His work addresses sustainability challenges, particularly with bio-based materials.
  2. Publications and Impact: With numerous publications in high-impact journals like Bioresource Technology and Polymers, his research in materials science is well-cited, reflected by his Google Scholar H-index of 27 and Scopus H-index of 24. His patents also demonstrate a strong emphasis on innovation in nanomaterials and bio-composites.
  3. Recognition and Awards: He has received several prestigious awards, including being named in Stanford University’s list of the World’s Top 2% Scientists for three consecutive years, a clear indication of his influence and leadership in the field.
  4. Patents and Innovation: Dr. Dungani’s registered patents on nanocellulose and biocomposites underscore his contributions to advancing sustainable materials.
  5. International Collaboration and Mentorship: His work with international journals, collaborations on research projects, and contributions to conferences and seminars show his commitment to knowledge dissemination and global impact.

In summary, Dr. Dungani’s remarkable body of work in biocomposites, recognition from peers, and continued innovation make him an outstanding candidate for a Best Researcher Award.

Publication top notes

Physical, mechanical, and electrical conductivity characteristics of coconut shell-based H3PO4-Activated carbon/epoxy nanocomposites

A sustainable in situ synthesis of hydrophobic tung oil epoxy bifunctional nanocomposites with potential fire retardant and antioxidant properties

Preparation of superhydrophobic biomedical pulp from rice straw coated with a stearic acid-cellulose composite

Performance of Particleboard Made of Agroforestry Residues Bonded with Thermosetting Adhesive Derived from Waste Styrofoam

 

Wenyao Zhang | Materials Science | Young Scientist Award

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Dr Wenyao Zhang |  Materials Science |  Young Scientist Award

professor at  Nanjing university of science and technology, China

Dr. Wenyao Zhang is a distinguished professor at the School of Chemistry and Chemical Engineering, Nanjing University of Science & Technology in Nanjing, China. He currently leads research in the field of aqueous Zn-ion batteries, focusing on the surface chemistry of Zn metal and the stabilization of metal clusters.

Publication profile

Google Scholar

Educational Background:

  • Ph.D. in Materials Science & Engineering (2012 – 2017): Nanjing University of Science and Technology, China.
  • Joint Ph.D. in Colloid Chemistry (2015 – 2017): Max Planck Institute of Colloids and Interfaces, Germany.
  • B.Eng. in Materials Chemistry (2008 – 2012): Nanjing University of Science and Technology, China.

Dr. Zhang’s research contributions have significantly advanced the understanding and application of nanomaterials in energy storage and conversion technologies.

Professional Experience:

  • 2022 – Present: Professor, Overseas High-Level Talent Recruitment Programs, Nanjing University of Science & Technology.
    • Research: Zn metal surface chemistry, aqueous Zn-ion batteries, stabilization of atomic/subnanometric metal clusters.
  • 2020 – 2022: Postdoctoral Researcher, Chemical & Materials Engineering, University of Alberta, Canada.
    • Co-Advisors: Prof. Ken Cadien, Prof. Zhi Li.
  • 2017 – 2020: Postdoctoral Researcher, Waterloo Institute for Nanotechnology, University of Waterloo, Canada.
    • Co-Advisors: Prof. Zhongwei Chen, Prof. Aiping Yu.

Academic Background:

Dr. Zhang earned his Ph.D. in Materials Science and Engineering from Nanjing University of Science and Technology in 2017, under the supervision of Prof. Xin Wang. He conducted joint Ph.D. research in Colloid Chemistry at the Max Planck Institute of Colloids and Interfaces in Germany, under Prof. Markus Antonietti. His research during this period focused on carbon-nitrogen materials for electrocatalysis and lithium-ion batteries, and carbon nitride-based materials for photoelectrochemical water splitting.

Materials Science Research Focus:

Dr. Wenyao Zhang’s research in materials science primarily revolves around energy storage and conversion technologies, with a significant emphasis on the following areas:

  1. Aqueous Zn-ion Batteries:
    • Zn Metal Surface Chemistry: Investigating the chemical interactions and surface modifications of zinc metal to enhance the performance and stability of aqueous Zn-ion batteries.
    • Stabilization of Metal Clusters: Developing molecular trapping strategies to stabilize atomic and subnanometric metal clusters, which are crucial for improving the efficiency and longevity of battery systems.
  2. Electrocatalysis:
    • Carbon-Nitrogen Materials: Designing novel carbon-nitrogen materials to serve as supports for electrocatalysts, enhancing their activity and durability for various electrochemical reactions.
  3. Photoelectrochemical Water Splitting:
    • Carbon Nitride-Based Materials: Creating high-performance carbon nitride-based materials to act as catalysts for photoelectrochemical water splitting, aiming to generate hydrogen efficiently using solar energy.
  4. Nanostructured Materials:
    • Growth of MnO2 on Carbon Nanotubes: Controlled synthesis of nanostructured manganese dioxide on carbon nanotubes to develop high-performance electrochemical capacitors.

Dr. Zhang’s innovative research integrates advanced material design and synthesis techniques to address critical challenges in energy storage and conversion, contributing to the development of sustainable and efficient energy solutions.

Citations:

  • Total Citations: 1,645
  • Citations Since 2019: 1,437
  • h-index: 21
  • i10-index: 28

Publication Top Notes

  • Ternary manganese ferrite/graphene/polyaniline nanostructure with enhanced electrochemical capacitance performance
    • P. Xiong, C. Hu, Y. Fan, W. Zhang, J. Zhu, X. Wang, Journal of Power Sources, 266, 384-392, 2014
    • Citations: 183
  • Palladium nanoparticles supported on graphitic carbon nitride-modified reduced graphene oxide as highly efficient catalysts for formic acid and methanol electrooxidation
    • W. Zhang, H. Huang, F. Li, K. Deng, X. Wang, Journal of Materials Chemistry A, 2 (44), 19084-19094, 2014
    • Citations: 169
  • Defect‐Enriched Nitrogen Doped–Graphene Quantum Dots Engineered NiCo2S4 Nanoarray as High‐Efficiency Bifunctional Catalyst for Flexible Zn‐Air Battery
    • W. Liu, B. Ren, W. Zhang, M. Zhang, G. Li, M. Xiao, J. Zhu, A. Yu, Small, 15 (44), 1903610, 2019
    • Citations: 99
  • Merging single‐atom‐dispersed iron and graphitic carbon nitride to a joint electronic system for high‐efficiency photocatalytic hydrogen evolution
    • W. Zhang, Q. Peng, L. Shi, Q. Yao, X. Wang, A. Yu, Z. Chen, Y. Fu, Small, 15 (50), 1905166, 2019
    • Citations: 90
  • Zn-free MOFs like MIL-53 (Al) and MIL-125 (Ti) for the preparation of defect-rich, ultrafine ZnO nanosheets with high photocatalytic performance
    • H. Xiao, W. Zhang, Q. Yao, L. Huang, L. Chen, B. Boury, Z. Chen, Applied Catalysis B: Environmental, 244, 719-731, 2019
    • Citations: 90
  • Controlled growth of nanostructured MnO2 on carbon nanotubes for high-performance electrochemical capacitors
    • H. Huang, W. Zhang, Y. Fu, X. Wang, Electrochimica Acta, 152, 480-488, 2015
    • Citations: 87
  • Self-repairing interphase reconstructed in each cycle for highly reversible aqueous zinc batteries
    • W. Zhang, M. Dong, K. Jiang, D. Yang, X. Tan, S. Zhai, R. Feng, N. Chen, Nature Communications, 13 (1), 5348, 2022
    • Citations: 84
  • A general approach for fabricating 3D MFe2O4 (M= Mn, Ni, Cu, Co)/graphitic carbon nitride covalently functionalized nitrogen-doped graphene nanocomposites as advanced anodes
    • W. Zhang, Y. Fu, W. Liu, L. Lim, X. Wang, A. Yu, Nano Energy, 57, 48-56, 2019
    • Citations: 82
  • A “trimurti” heterostructured hybrid with an intimate CoO/Co x P interface as a robust bifunctional air electrode for rechargeable Zn–air batteries
    • Y. Niu, M. Xiao, J. Zhu, T. Zeng, J. Li, W. Zhang, D. Su, A. Yu, Z. Chen, Journal of Materials Chemistry A, 8 (18), 9177-9184, 2020
    • Citations: 81
  • One-pot synthesis of nickel-modified carbon nitride layers toward efficient photoelectrochemical cells
    • W. Zhang, J. Albero, L. Xi, K. M. Lange, H. Garcia, X. Wang, M. Shalom, ACS Applied Materials & Interfaces, 9 (38), 32667-32677, 2017
    • Citations: 67