Hailu Wang | Materials Science | Best Researcher Award

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Dr. Hailu Wang | Materials Science | Best Researcher Award

Dr. Hailu Wang, Wuhan University of Science and Technology, China

Dr. Hailu Wang (1995) is a postdoctoral researcher at Wuhan University of Science and Technology, specializing in Materials Science and Engineering. His research focuses on advanced ceramic materials, including their application in lithium-ion batteries and high-temperature processes. Dr. Wang has authored 9 SCI papers and holds several patents in refractory materials and ceramic technology. Notable projects include the development of ceramic saggers for battery cathode material roasting and the design of ceramic crucibles for high-end superalloys. He has contributed to key scientific research funded by the National Natural Science Foundation of China. πŸ”¬βš™οΈπŸ“š

 

Publication Profile

Scopus

Academic Contributions

Dr. Wang has published nine papers in prestigious journals such as Chemical Engineering Journal, Journal of the European Ceramic Society, and Ceramics International. His research has focused on advanced ceramic materials, their applications in energy storage, and high-performance materials for industrial processes like battery production and alloy smelting. He has made significant contributions to understanding material behaviors under extreme conditions and has published in renowned international journals.

Research Focus

Dr. Hailu Wang’s research primarily focuses on advanced ceramic materials and their applications in high-temperature industries. His work includes the development of ceramic sagger materials for lithium-ion battery cathode material roasting πŸ”‹, high-performance ceramic crucibles for melting nickel-based superalloys πŸ”§, and the synthesis of lightweight, high-strength, and corrosion-resistant ceramics for various industrial uses. Additionally, Dr. Wang investigates the structure and properties of porous ceramics for adsorption, filtration, and thermal insulation 🌱. His studies contribute significantly to materials science, particularly in improving the efficiency and sustainability of energy storage and manufacturing technologies. πŸ”¬πŸ’‘

 

Publication Top Notes

  • Effect of BPO4 on phase transition behavior and sintering of quartz materials – Li, J., Li, Y., Li, S., … Qiao, Z., Xiang, K. (2024) πŸ“œ
  • Preparation of mullite whisker foam ceramics and exploration of its application in adsorption – Li, Y., Wang, H., Li, S., Bai, C., Liu, F. (2024) 🧱
  • Synthesis and application evaluation in lithium battery furnace of mullite insulating refractory bricks from tailings – Wang, H., Li, Y., Yin, B., … Xiang, R., Qiao, Z. (2023) πŸ”‹
  • Damage mechanism and corrosion resistance improvement of corundum-mullite kiln furniture during calcining of Li-ion cathode materials – Wang, H., Li, Y., Li, S., … Qiao, Z., Xiang, K. (2023) πŸ”¬
  • Controlled structure preparation of low thermal conductivity Bi4B2O9 foams – Chen, P., Li, Y., Yin, B., … Qiao, Z., Liu, J. (2023) 🌑️
  • New design of bismuth borate ceramic/epoxy composites with excellent fracture toughness and radiation shielding capabilities – Chen, P., Li, Y., Yin, B., … Wang, H., Liu, J. (2023) βš›οΈ
  • Firing properties and corrosion resistance of mullite-Al2TiO5 saggar materials – Xiang, K., Li, S., Li, Y., … Xiang, R., He, X. (2023) πŸ”₯
  • Anti-corrosion effect of insulating firebrick coated with CA6 in the calcination of lithium-ion cathode materials – Wang, H., Li, Y., He, X., … Li, S., Li, S. (2022) πŸ”§
  • Synthesis of cordierite foam ceramics from kyanite tailings and simulated application effects – Wang, H., Li, Y., Yin, B., … Li, S., Zhou, Z. (2022) πŸ—οΈ
  • Interactions of Li2O volatilized from ternary lithium-ion battery cathode materials with mullite saggar materials during calcination – Xiang, K., Li, S., Li, Y., Wang, H., Xiang, R. (2022) πŸ”‹πŸ§±

 

Arnaud Demortière | Materials Science | Best Researcher Award

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Prof. Arnaud Demortière | Materials Science | Best Researcher Award

Director of research, LRCS Lab at CNRS, France

Dr. Arnaud Demortière is a highly accomplished researcher in materials science, currently serving as Director of Research at CNRS and head of Electron Microscopy and X-Ray Facilities at RS2E. With a PhD in Nanomaterials Science and an HDR, his academic achievements are complemented by an impressive research output, including 90 publications, an H-index of 36, and over 5700 citations. He has led multiple ANR-funded projects and contributed to high-profile European initiatives like Battery 2030+ and Horizon 2020. As a recipient of the CNRS RISE Innovation Award 2023, Dr. Demortière is recognized for his groundbreaking work in energy storage and his innovative startup, PreDeeption. Additionally, he has supervised 13 PhD students, fostering the next generation of scientists. His leadership in cross-disciplinary research, project management, and mentorship makes him a deserving candidate for the Research for Best Researcher Award.

Profile:

Education

Dr. Arnaud DemortiΓ¨re has an extensive and distinguished academic background, beginning with a Bachelor’s in Physics-Chemistry from Lyon 1 University in 2001. He continued his studies at Lyon 1 University and ENS Lyon, where he earned a Master’s in Condensed Matter Physics in 2003. His passion for materials science led him to pursue a PhD at Pierre & Marie Curie University (Paris 6) and CNRS, where he specialized in Nanomaterials Science and completed his doctorate in 2007.

Dr. DemortiΓ¨re further advanced his expertise through two prestigious postdoctoral fellowshipsβ€”first at IPCMS-CNRS in Strasbourg, France, and later at Argonne National Laboratory in Chicago, USA, under the Department of Energy (DOE) Fellowship. In 2021, he achieved the “Habilitation Γ  Diriger des Recherches” (HDR) from UPJV University in Amiens, France, a significant academic milestone that recognizes his authority to supervise doctoral research, particularly in the field of battery materials and imaging techniques.

Professional Experiences

Dr. Arnaud DemortiΓ¨re has an extensive professional background, marked by leadership roles at prestigious institutions. He currently serves as the Director of Research at CNRS and is the Head of Electron Microscopy and X-Ray Facilities at the RS2E Network. Since joining CNRS in 2014, he has led cross-disciplinary research initiatives focused on developing in-situ and operando techniques for imaging and diffraction, crucial for advancing battery materials research. His earlier experience includes positions at Illinois Institute of Technology and Argonne National Laboratory, where he conducted groundbreaking work in materials science. Dr. DemortiΓ¨re’s leadership extends to managing the Image, Data Science, and Diffraction (I&2D) team at the LRCS Laboratory, where he spearheads cutting-edge research in nanomaterials. His diverse roles also include serving as a scientific consultant for Chut! Magazine, reflecting his commitment to bridging the gap between scientific research and societal impact. His professional journey exemplifies innovation, leadership, and collaboration in advancing materials science.

Research Skills

Dr. Arnaud DemortiΓ¨re is a highly skilled researcher with an extensive background in nanomaterials and energy storage technologies. His expertise spans cutting-edge techniques such as in-situ and operando imaging, diffraction, and X-ray tomography, enabling detailed investigation of battery materials. As a leader of several interdisciplinary research teams and projects, including ANR and Horizon 2020 initiatives, Dr. DemortiΓ¨re has demonstrated exceptional proficiency in managing large-scale scientific endeavors. His research has resulted in 90 high-impact publications, an H-index of 36, and over 5700 citations, reflecting the significance of his contributions to the field. Additionally, his role as a mentor to PhD students and postdoctoral researchers highlights his ability to foster scientific talent and drive innovation. Dr. DemortiΓ¨re’s technical expertise, combined with his leadership in both academic and industrial collaborations, positions him as a key figure in advancing materials science and energy storage technologies.

Award And Recognitions

Dr. Arnaud DemortiΓ¨re, Director of Research at CNRS and Head of the Electron Microscopy and X-Ray Facilities at RS2E, is a distinguished figure in the field of materials science. He has authored 90 research articles, boasts an H-index of 36, with over 5700 citations, and has presented at 50 conferences, 18 of which were as an invited speaker. In recognition of his groundbreaking work, Dr. DemortiΓ¨re was awarded the prestigious CNRS RISE Innovation Award in 2023 for his innovative startup project, PreDeeption. He has led several large-scale research projects, including the ANR DESTINa-ion and DynamoBat, while actively contributing to European initiatives like Battery 2030+ and Horizon 2020. Dr. DemortiΓ¨re’s commitment to mentoring the next generation of scientists is reflected in his supervision of numerous PhD students. His career achievements, research excellence, and contributions to the field of energy storage solidify his reputation as a leading researcher in his domain.

Conclusion

Dr. Arnaud Demortière is a highly qualified candidate for the Research for Best Researcher Award due to his extensive contributions to materials science and energy storage. With an impressive academic background, including a PhD in Nanomaterials Science and an HDR, his research has made a significant impact on the field. His prolific output, with 90 publications, an H-index of 36, and over 5700 citations, demonstrates his expertise and influence. As a leader in major national and international research projects, such as ANR and Horizon 2020, he has successfully driven innovation in battery technology. Additionally, his receipt of the CNRS RISE Innovation Award 2023 for his startup project PreDeeption highlights his ability to bridge scientific research and practical applications. His mentorship of numerous PhD students and postdoctoral researchers further strengthens his candidacy, as he plays a vital role in shaping the next generation of scientists. Overall, Dr. Demortière exemplifies research excellence and innovation

Publication Top Notes

  • Improved ACOM Pattern Matching in 4D-STEM through Adaptive Sub-Pixel Peak Detection and Image Reconstruction
    • Authors: Folastre, N., Cao, J., Oney, G., Rauch, E.F., DemortiΓ¨re, A.
    • Year: 2024
    • Citations: 0
  • Identification of Degree of Ordering in Spinel LiNi0.5Mn1.5O4 through NMR and Raman Spectroscopies Supported by Theoretical Calculations
    • Authors: Oney, G., Sevillano, J.S., Yahia, M.B., Croguennec, L., Carlier, D.
    • Year: 2024
    • Citations: 1
  • Investigating Cathode Electrolyte Interphase Formation in NMC 811 Primary Particles through Advanced 4D-STEM ACOM Analysis
    • Authors: Gallegos-Moncayo, K., Jean, J., Folastre, N., Jamali, A., DemortiΓ¨re, A.
    • Year: 2024
    • Citations: 0
  • Binder-Free CNT Cathodes for Li-O2 Batteries with More Than One Life
    • Authors: Su, Z., Temprano, I., Folastre, N., Franco, A.A., DemortiΓ¨re, A.
    • Year: 2024
    • Citations: 0
  • Coupling Liquid Electrochemical TEM and Mass-Spectrometry to Investigate Electrochemical Reactions Occurring in a Na-Ion Battery Anode
    • Authors: Gallegos-Moncayo, K., Folastre, N., Toledo, M., Huo, D., DemortiΓ¨re, A.
    • Year: 2024 (Article in Press)
    • Citations: 0
  • Computational Model for Predicting Particle Fracture During Electrode Calendering
    • Authors: Xu, J., Paredes-Goyes, B., Su, Z., DemortiΓ¨re, A., Franco, A.A.
    • Year: 2023
    • Citations: 10
  • The Impact of Intergrain Phases on the Ionic Conductivity of the LAGP Solid Electrolyte Material Prepared by Spark Plasma Sintering
    • Authors: Cretu, S., Bradley, D.G., Feng, L.P.W., DemortiΓ¨re, A., Duchamp, M.
    • Year: 2023
    • Citations: 3
  • Molten Salt Synthesis of Multifaceted Pure-Phase Spinel LiNi0.5Mn1.5O4 Platelets
    • Authors: Oney, G., Olchowka, J., DemortiΓ¨re, A., Weill, F., Croguennec, L.
    • Year: 2023
    • Citations: 3
  • Study of the Delithiation Dynamics in a Single LiFePO4 Cathode Crystal via In Situ TEM Experiments and the Phase-Field Model
    • Authors: Yousfi, A., Gallegos, K., Jean, J., Boussinot, G., DemortiΓ¨re, A.
    • Year: 2023
    • Citations: 0
  • Study of Lithiation Dynamics in Primary Particles of Cathode Materials by In Situ Electrochemical Liquid TEM
    • Authors: Gallegos, K., Yousfi, A., Jean, J., Jamali, A., DemortiΓ¨re, A.
    • Year: 2023
    • Citations: 0

Shaolong Li | Materials Science | Best Researcher Award

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Mr. Shaolong Li | Materials Science | Best Researcher Award

Doctoral student, Xi’an University of Technology, China

Shaolong Li is a Ph.D. student in Materials Science and Engineering at Xi’an University of Technology, China, and a visiting research student at City University of Hong Kong. His research focuses on the configurational design of heterogeneous structured titanium matrix composite materials using powder metallurgy and additive manufacturing technologies. πŸŒŸπŸ”¬

Profile

scopus

orcid

Education πŸŽ“

  • Bachelor of Engineering in Materials Physics and Chemistry, Xi’an University of Technology, China (Sep. 2016 – Jul. 2020)
  • Ph.D. student in Materials Science and Engineering, Xi’an University of Technology, China (Sep. 2020 – Present)
  • Visiting Research Student in Materials Science and Engineering, City University of Hong Kong (Feb. 2024 – Present)

Experience πŸ§ͺπŸ“ˆ

Shaolong Li has led significant research projects, including being the Principal Investigator for the Doctoral Study Abroad Joint Education Fund at Xi’an University of Technology, with a funding of $12,000. His work is dedicated to understanding and improving the properties of titanium matrix composites.

Research Interests πŸ”¬πŸ“Š

Shaolong Li’s research interests include heterogeneous structures, high-temperature softening mechanisms, the Hall-Petch relationship, powder metallurgy, and additive manufacturing. His studies aim to reveal the strengthening-toughening mechanisms of titanium matrix composites through advanced characterization techniques.

AwardsπŸ…πŸŽ–οΈ

Outstanding Undergraduate Thesis at the University Level, 2020

National Scholarship for Graduate Students, 2022

Academic Scholarship for Graduate Students, 2021, 2023

Excellent Academic Report, Xi’an University of Technology, 2023

Excellent Academic Report, Chinese Society for Composite Materials, 2023

Publications Top Notes πŸ“š

High-temperature “Inverse” Hall-Petch relationship and fracture behavior of TA15 alloy International Journal of Plasticity, 2024- Link

Achieving back-stress strengthening at high temperature via heterogeneous distribution of nano TiBw in TC4 alloy by electron beam powder bed fusion Materials Characterization, 2024- Link

High temperature softening mechanism of powder metallurgy TA15 alloy Materials Science and Engineering: A, 2023- Link

Microstructure and mechanical properties of TiC+TiB reinforced TC4 matrix composites prepared by in-situ reaction of powder metallurgy TC4-B4C The Chinese Journal of Nonferrous Metals, 2023- Link

Loss-free tensile ductility of dual-structure titanium composites via an interdiffusion and self-organization strategy Proceedings of the National Academy of Sciences of the United States of America, 2023- Link