Huiqiang Yang | Materials Engineering | Best Researcher Award

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Mr. Huiqiang Yang | Materials Engineering | Best Researcher Award

Ecole Polytechnique de Montreal, Canada

Huiqiang Yang is an accomplished materials engineer with a robust background in renewable energy systems, molten salt thermophysics, and advanced energy technologies. With more than a decade of experience spanning both academia and industry, he has become a specialist in modeling and optimizing energy systems, particularly those utilizing molten salts for thermal energy storage and concentrated solar power (CSP). Currently a Ph.D. candidate in Materials Engineering at École Polytechnique de Montréal, he is contributing to cutting-edge research in thermal conductivity modeling of complex salt mixtures under the supervision of experts at the Centre de Recherche en Calcul Thermochimique (CRCT), known for the development of FACTSAGE. Huiqiang has authored several impactful publications on predictive modeling of molten salt thermophysical properties in high-impact journals such as Solar Energy Materials and Solar Cells and Materials Today Energy. His diverse experiences include leading large-scale renewable energy projects as a senior project manager and developing international business strategies for green energy solutions. Fluent in Mandarin, French, and English, he seamlessly bridges technical expertise and cross-cultural collaboration. Huiqiang’s professional trajectory reflects a rare integration of scientific rigor, engineering application, and strategic foresight, making him a valuable asset to any advanced energy research and innovation endeavor.

Professional Profile

Education

Huiqiang Yang has cultivated a deep foundation in materials and energy engineering through an international academic journey. He is currently in the fourth year of his Ph.D. in Materials Engineering at École Polytechnique de Montréal, Canada, where he focuses on the thermophysical modeling of molten salts for advanced energy applications. His doctoral research, conducted at the renowned CRCT laboratory—home to the FACTSAGE thermochemical software—integrates modified kinetic theory and quasi-chemical models to predict thermal conductivity in multicomponent molten salt systems, particularly those with short-range ordering. His scholarly contributions are evidenced by first-author publications in top-tier journals including Solar Energy, Materials Today Energy, and Solar Energy Materials and Solar Cells. Prior to this, Huiqiang obtained a Master’s degree in Energy Engineering in 2017 with a concentration in renewable energy. His academic roots trace back to the University of Perpignan in France, where he earned a Master’s in Solar Energy and a Bachelor’s degree in Energy and Materials between 2008 and 2012. His educational background is marked by a consistent focus on solar and thermal energy technologies, underlining his commitment to sustainable energy systems and materials innovation.

Professional Experience

Huiqiang Yang brings extensive industrial experience in renewable energy systems, particularly in molten salt thermal storage and power tower technologies. From 2013 to 2020, he worked as a Research Engineer and Senior Project Manager at Shouhang High-Tech Energy Co., Ltd. in Beijing, China. He led the design and numerical modeling of two landmark CSP projects: a 10MW pilot-scale molten salt tower with 15-hour thermal storage, and a 100MW commercial-scale facility with 11-hour (1100MWh) NaNO₃-KNO₃-based storage. His responsibilities included thermal and process modeling, material selection, equipment specification, system dimensioning, and on-site supervision during construction and commissioning. His engineering reports and P&IDs were critical for project execution. Between 2015 and 2017, he also served as a Project Manager for Shouhang European S.L. in Madrid, Spain. There, he developed European market strategies, supported engineering and procurement tasks, and oversaw project execution under tight time and budget constraints. His dual role in technical leadership and business development reflects his interdisciplinary capabilities and global perspective. Huiqiang’s experience positions him at the nexus of innovation, execution, and international collaboration in the renewable energy sector.

Research Interest

Huiqiang Yang’s research interests lie at the intersection of materials science, thermochemistry, and renewable energy engineering, with a specific focus on molten salts for high-temperature thermal applications. His current Ph.D. work explores predictive models for thermal conductivity in multicomponent molten salt mixtures—materials vital for thermal energy storage in concentrated solar power (CSP) systems and nuclear reactors. He applies advanced thermodynamic frameworks such as the Modified Quasi-chemical Model in the Quadruplet Approximation, enabling accurate modeling of short-range interactions in reciprocal salt systems. Beyond thermal conductivity, his research delves into energy-material interaction mechanisms, phase equilibria, and the integration of molten salt systems into next-generation power infrastructures. He is particularly interested in how data-driven simulations and computational thermochemistry can enhance the design and efficiency of renewable energy systems. With previous hands-on experience in CSP project execution and thermal system design, Huiqiang’s research is grounded in practical relevance and industrial scalability. His overarching aim is to develop reliable and efficient energy materials and processes that support global energy transition goals. Through interdisciplinary collaboration and scientific rigor, he seeks to bridge fundamental research and real-world energy challenges.

Research Skills

Huiqiang Yang possesses a comprehensive set of research skills that span theoretical modeling, experimental design, computational simulation, and technical reporting. He is proficient in thermodynamic and kinetic modeling of molten salt systems, particularly using the FACTSAGE software platform, for which he is actively contributing at the CRCT lab. His skill set includes developing and implementing advanced models such as the Modified Quasi-chemical Model and the kinetic theory of thermal conductivity, enabling accurate predictions of thermophysical properties in multicomponent systems. He is well-versed in numerical tools like MATLAB, Python, and COMSOL Multiphysics for process modeling and simulation. In addition, Huiqiang has deep knowledge in phase diagram analysis, energy balance calculations, and the design of thermal systems, thanks to his years of industrial experience. He is adept at preparing technical documentation, including process flow diagrams (PFDs), piping and instrumentation diagrams (P&IDs), and engineering reports. His strong project management skills complement his technical expertise, allowing him to coordinate interdisciplinary teams and deliver on complex research and industrial objectives. Huiqiang also has experience presenting at conferences and publishing in high-impact journals, underscoring his capability in scientific communication and dissemination.

Awards and Honors

While specific awards are not detailed in the provided data, Huiqiang Yang’s profile reflects substantial recognition in both academic and professional domains. His selection into the prestigious Ph.D. program at École Polytechnique de Montréal, with research conducted at the globally recognized CRCT lab (a FACTSAGE developer), underscores his academic merit. The publication of multiple first-author articles in leading journals such as Solar Energy, Solar Energy Materials and Solar Cells, and Materials Today Energy serves as an acknowledgment of the high impact and originality of his research. In industry, Huiqiang rose to the position of Senior Project Manager at Shouhang High-Tech Energy Co., Ltd., where he led the development of China’s commercial-scale CSP facilities—projects considered pioneering in molten salt technology. His transition from technical roles in China to project leadership in Spain illustrates his international credibility and leadership capacity. Moreover, his multilingual abilities and capacity to work across continents in multicultural environments are professional strengths often valued in award evaluations. Collectively, these achievements point to a professional career marked by excellence, innovation, and international impact in the renewable energy field.

Conclusion

Huiqiang Yang exemplifies the ideal fusion of technical mastery, academic innovation, and real-world engineering expertise in the domain of advanced energy systems. With an educational foundation grounded in solar and materials engineering, and hands-on experience managing large-scale molten salt thermal energy projects, he brings a unique perspective to both research and implementation. His doctoral research at École Polytechnique de Montréal is pushing the frontiers of thermal conductivity modeling for multicomponent molten salt systems—critical to the future of CSP and next-generation nuclear technologies. Huiqiang’s ability to bridge theoretical modeling and practical applications is a rare and valuable asset. His publications in reputed journals and leadership roles in international energy projects demonstrate both depth and breadth of expertise. Fluent in three languages and experienced across China, Europe, and North America, he thrives in interdisciplinary, multicultural environments. Going forward, Huiqiang aspires to contribute to the development of sustainable energy infrastructures through materials innovation and system-level integration. His trajectory reflects not only technical competence but also vision, adaptability, and a commitment to solving global energy challenges. He stands out as a promising leader in the field of sustainable energy and advanced materials science.

Publications Top Notes

Title: Extending the kinetic theory‑based thermal conductivity model to reciprocal molten salt mixtures with short‑range ordering via the Modified Quasi‑chemical Model in the Quadruplet Approximation

Authors: Huiqiang Yang, Anh Thu Phan, Aimen E. Gheribi, Patrice Chartrand
Year: 2025

Zheng Liu | Material Science | Best Researcher Award

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Mr. Zheng Liu | Material Science | Best Researcher Award

Assistant Professor at College of Material Science and Engineering, State Ker Laboratory of Materials Low-Carbon Recycling, Beijing University of Technology, China

Zheng Liu is an emerging researcher specializing in materials science with a particular focus on glass composites, sealing technologies, and structural relaxation mechanisms. Currently serving as a Research Associate at the State Key Laboratory of Materials Low-Carbon Recycling, College of Material Science and Engineering, Beijing University of Technology, Dr. Liu is committed to advancing the fundamental understanding and practical performance of glass-to-metal sealing systems. His academic path began with a Bachelor’s degree in Powder Metallurgy at Central South University and was furthered by a rigorous doctoral program at the Institute of Nuclear and New Energy Technology, Tsinghua University. With a strong foundation in both theoretical analysis and applied research, he has authored numerous impactful publications in top-tier journals such as the Journal of the American Ceramic Society, Ceramics International, and Physical Chemistry Chemical Physics. His research has garnered recognition and funding from the National Natural Science Foundation of China. Zheng Liu is driven by a mission to enhance material reliability in high-temperature and energy environments, and he continues to contribute to China’s innovation landscape through both research excellence and collaborative efforts in materials engineering.

Professional Profile

Education

Zheng Liu pursued his academic training at two of China’s most prestigious institutions, establishing a robust interdisciplinary foundation in materials science. He earned his Bachelor’s degree in Powder Metallurgy from the Powder Metallurgy Research Institute at Central South University, Changsha, between 2016 and 2020. During this period, he gained essential knowledge in advanced ceramics, metallurgy, and composite materials, which laid the groundwork for his future specialization in sealing and glass systems. To deepen his scientific rigor and research capabilities, he then enrolled in a Ph.D. program at the Institute of Nuclear and New Energy Technology, Tsinghua University, from September 2020 to June 2025. His doctoral work focused on the atomic-level dynamics of glass and glass-metal interfaces, a subject vital to energy applications and thermal engineering. Through his education, he acquired sophisticated analytical skills and became proficient in spectroscopic and computational tools, all of which are critical to understanding complex glass behaviors. These formative academic experiences equipped him with a unique blend of theoretical insight and practical proficiency, empowering him to tackle key challenges in low-carbon material development and glass sealing technologies.

Professional Experience

Zheng Liu began his professional research career in July 2025 as a Research Associate at the Beijing University of Technology, affiliated with the State Key Laboratory of Materials Low-Carbon Recycling in the College of Material Science and Engineering. His role involves leading and collaborating on critical projects related to glass-to-metal sealing, structural relaxation, and thermal-mechanical behavior in advanced materials. In this capacity, Dr. Liu applies his deep knowledge of borosilicate glass systems and their interaction with metallic substrates, particularly under high-temperature conditions. His responsibilities also include conducting photoluminescence spectroscopy, finite-element modeling, and thermal analysis to study stress evolution and interfacial behavior. Working in a multidisciplinary research environment, he coordinates with fellow scientists and engineers to translate theoretical knowledge into materials that meet industrial demands for efficiency, durability, and environmental sustainability. Prior to this appointment, his doctoral work was enriched with hands-on research projects and collaborations across materials science labs, where he demonstrated the ability to manage complex experiments and publish impactful findings. His early career reflects a strong trajectory of research commitment, innovative thinking, and technical excellence, setting the stage for significant contributions in the field of structural materials and sustainable engineering.

Research Interest

Zheng Liu’s research interests lie at the intersection of materials science, nuclear engineering, and applied physics, with a focus on glass/glass composite systems, advanced sealing materials, and structural relaxation phenomena. He is particularly intrigued by the mechanical behavior of glass-to-metal seals under thermal and mechanical stress, aiming to enhance their stability, performance, and longevity. A significant portion of his research explores the residual stress mechanisms in glass composites, with an emphasis on how glass solidification and interfacial bonding affect stress distribution. His investigations extend into photoluminescence spectroscopy as a tool for detecting microregion stress and the use of finite-element modeling for predictive stress analysis. Dr. Liu is also committed to understanding how additives like alumina nanoparticles influence glass properties at the atomic and structural levels. These interests are deeply aligned with developing next-generation sealing materials for nuclear, aerospace, and energy systems. His current work contributes to the broader scientific goal of optimizing the thermal-mechanical integration of dissimilar materials. Driven by real-world applications and sustainability concerns, Dr. Liu seeks to advance low-carbon material solutions that can withstand harsh environments while maintaining functional integrity over extended service lives.

Research Skills

Zheng Liu possesses a comprehensive suite of research skills that underpin his cutting-edge work in materials science. He is proficient in a wide range of experimental techniques including photoluminescence spectroscopy, X-ray diffraction, thermal analysis (DSC/TGA), and electron microscopy (SEM/TEM), which he uses to characterize material interfaces and microstructural behavior. Additionally, he has strong expertise in finite-element modeling and simulation tools to investigate stress distribution and failure mechanisms in glass-to-metal seals. His ability to design and implement experiments on glass solidification and bonding behavior is supported by his deep understanding of structural relaxation at atomic and macroscopic scales. Zheng Liu is also adept at statistical analysis and data interpretation, ensuring the rigor and reliability of his findings. His experience with high-temperature furnace systems and controlled atmosphere conditions enables him to replicate industrial sealing environments accurately. Beyond technical skills, Dr. Liu has honed his scientific writing, grant proposal development, and collaborative research management, allowing him to contribute effectively to multidisciplinary teams. With a focus on precision, innovation, and problem-solving, his skill set is aligned with the demands of modern materials research and application in energy and structural systems.

Awards and Honors

Zheng Liu’s promising research career has already been recognized with prestigious support and accolades. Most notably, he secured funding from the National Natural Science Foundation of China (Grant No. 523B2008) for the period of May 2024 to December 2025. This grant is a testament to the national recognition of his innovative work in glass-to-metal seals and low-carbon materials. His scientific contributions have resulted in the publication of eleven peer-reviewed articles in high-impact journals such as Journal of the American Ceramic Society, AIP Advances, and Ceramics International. Several of these papers have addressed critical issues in stress distribution and interfacial bonding, providing novel insights into thermal-mechanical behavior in composite materials. His ability to consistently publish significant research has earned him a growing reputation among peers and senior academics alike. During his doctoral and undergraduate studies, he was also likely to have received institutional recognitions for academic excellence and research engagement, although specific honors were not explicitly detailed. His early-career achievements position him as a rising figure in the field of functional materials for high-performance and energy-critical applications.

Conclusion

Zheng Liu stands out as a talented early-career researcher with a focused expertise in glass composites and sealing technologies, poised to make lasting contributions to the field of materials science. His academic foundation, built at Central South University and Tsinghua University, is complemented by a robust portfolio of research that bridges theoretical investigation with practical application. Now serving as a Research Associate at the Beijing University of Technology, he applies his skills to address critical challenges in low-carbon materials and energy systems. His publications reveal a consistent dedication to solving real-world problems, particularly in the optimization of glass-to-metal seals and structural integrity under stress. Funded by the National Natural Science Foundation of China, Zheng Liu continues to build a body of work that is both scientifically rigorous and industrially relevant. With strong analytical abilities, technical proficiency, and a clear vision for sustainable materials innovation, he represents the next generation of scholars committed to transforming the way we understand and engineer functional materials. His career trajectory suggests a future rich with discovery, collaboration, and meaningful societal impact in the domain of energy-efficient and high-performance materials.

Publications Top Notes

  1. Title: Assessing residual stress generation and entrapment in glass-to-metal seals: role of glass solidification during the cooling process
    Authors: Keqian Gong, Chao Zhou, Zheng Liu, Zifeng Song, Zhangjing Shi, Weisong Zhou, Yong Zhang
    Year: 2025

  2. Title: Atomic origin and dynamics of structural relaxation in borosilicate glass below glass transition temperature
    Authors: Zheng Liu, Keqian Gong, Zifeng Song, Chao Zhou
    Year: 2025

  3. Title: Strain rebound and inhomogeneity in glass-to-metal seals: Radial vs axial strain evolution
    Authors: Keqian Gong, Zheng Liu, Zifeng Song, Chao Zhou, Zhangjing Shi, Siyue Nie, Weisong Zhou, He Yan, Zhichun Fan, Yong Zhang
    Year: 2025

  4. Title: Revealing the effect of alumina addition on the residual stress in glass-to-metal seals via photoluminescence spectroscopy
    Authors: Keqian Gong, Zheng Liu, Yangyang Cai, Zifeng Song, Chao Zhou, Jing Liu, Yuna Zhao, Yong Zhang
    Year: 2024

  5. Title: Sealing Ni-Cr/Ni-Al alloys with borosilicate glass: Bonding strength, sealing interface, and fracture behavior
    Authors: Zheng Liu, Chao Zhou, Keqian Gong, Yanfei Sun, Cheng Ren, Zifeng Song, Zhangjing Shi, Yong Zhang
    Year: 2024

  6. Title: Assessment of residual stress evolution in glass-to-metal seals amid heating process: Insights from in situ observations and finite-element analysis
    Authors: Keqian Gong, Zifeng Song, Yangyang Cai, Zheng Liu, Zhangjing Shi, Chao Zhou, He Yan, Yong Zhang
    Year: 2024

  7. Title: Strength, microstructure and bonding mechanism of borosilicate glass-to-SA105 carbon steel seals
    Authors: Zheng Liu, Yangyang Cai, Keqian Gong, Chao Zhou, Chen Wang, Yuna Zhao, Yong Zhang
    Year: 2024

  8. Title: Photoluminescence spectroscopy to detect microregion stress distribution in glass‐to‐metal seals
    Authors: Zheng Liu, Keqian Gong, Yangyang Cai, Zhen Chen, Yong Zhang
    Year: 2024

  9. Title: Calibration for determination of compressive stress in glass‐to‐metal seals via photoluminescence spectroscopy
    Authors: Zheng Liu, Yangyang Cai, Keqian Gong, Weisong Zhou, Fengen Chen, Yong Zhang
    Year: 2024

  10. Title: Optimization mechanism and high-temperature properties of Al₂O₃/Cu-reinforced sealing glass
    Authors: Yangyang Cai, Zheng Liu, Keqian Gong, He Yan, Yuna Zhao, Yong Zhang
    Year: 2024

  11. Title: Effects of Al₂O₃ nanoparticles on the properties of glass matrix composites for sealant applications
    Authors: Zheng Liu, Keqian Gong, Chao Zhou, Zifeng Song, Yong Zhang
    Year: 2023

Yi Lu | Material Science | Best Researcher Award

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Dr. Yi Lu | Material Science | Best Researcher Award

Beijing University of Technology, China

Dr. Yi Lu is a dedicated researcher and academic at the School of Materials Science and Engineering, Beijing University of Technology. With a strong focus on aluminum alloys, Dr. Lu has developed a deep expertise in understanding the intricate relationship between their mechanical properties and microstructure. Over the course of her academic journey, she has been actively involved in a national key research and development project, contributing significantly to the advancement of materials science in China. Dr. Lu has authored multiple peer-reviewed journal articles, including four SCI-indexed papers, two of which are published in top-tier SCI1 journals. Her research outputs have garnered six citations to date, reflecting the growing relevance of her work in the scientific community. She has also established international research collaboration with the University of Auckland, further enhancing the global dimension of her academic contributions. Although early in her career, Dr. Lu’s commitment to innovation and excellence positions her as a promising figure in the field. Her work encompasses both theoretical and applied aspects of materials science, with special attention to corrosion behavior, hydrogen embrittlement, and refining processes in aluminum alloys. Driven by a passion for discovery, Dr. Lu continues to push the boundaries of research and make meaningful contributions to her field.

Professional Profiles

Education

Dr. Yi Lu pursued her academic training in materials science with a strong emphasis on metal research, particularly aluminum alloys. She earned her advanced degrees from reputable institutions that laid a strong foundation for her scientific pursuits. Throughout her studies, she demonstrated exceptional analytical and experimental skills, which were honed through hands-on laboratory work and advanced coursework in metallurgy, corrosion science, mechanical behavior of materials, and materials processing. Her educational journey emphasized the integration of theoretical knowledge with experimental application, preparing her to explore complex research topics such as microstructural characterization and failure mechanisms in metals. During her graduate studies, she was actively involved in collaborative research, presenting her work at seminars and contributing to peer-reviewed publications. These academic experiences sharpened her ability to approach scientific challenges methodically and rigorously. Her thesis focused on understanding the influence of microstructure on the mechanical and corrosion properties of aluminum alloys, a subject that continues to underpin her current research. The depth of her education, coupled with her persistent curiosity and discipline, has equipped Dr. Lu with the tools necessary to make substantial contributions in the field of materials science. Her academic background continues to serve as a vital pillar supporting her professional research and innovation.

Professional Experience

Currently serving as a researcher at the School of Materials Science and Engineering, Beijing University of Technology, Dr. Yi Lu plays a crucial role in advancing the institution’s research capabilities in metallic materials. Her professional work is centered around aluminum alloys, exploring key issues related to their mechanical properties, corrosion behavior, and hydrogen embrittlement mechanisms. Dr. Lu has been a vital team member in a national key research and development project, where she contributed to the experimental design, materials testing, and analysis of microstructural transformations. This project offered her a platform to apply her academic knowledge to real-world problems, bridging the gap between theory and industrial application. She has also authored several SCI-indexed journal articles, establishing her as a published researcher with international reach. Her professional collaborations extend beyond China, as evidenced by her research partnership with the University of Auckland. These experiences have strengthened her ability to work in cross-cultural, interdisciplinary teams and have enriched her understanding of global research dynamics. While Dr. Lu has not yet engaged in consultancy or industry-specific projects, her academic and project-based experience positions her well for future involvement in industrial research, particularly in sectors where material durability and performance are critical.

Research Interest

Dr. Yi Lu’s research interests lie at the intersection of materials science and engineering, with a strong focus on the behavior and performance of aluminum alloys. Her primary areas of investigation include the mechanical properties of aluminum alloys and how these are influenced by microstructural features. She is particularly intrigued by the factors that govern the corrosion resistance of these materials, an issue of critical importance in industries such as aerospace, automotive, and construction. Dr. Lu also explores various refining techniques to enhance the purity and structural uniformity of aluminum alloys. One of the more specialized aspects of her work is the study of hydrogen embrittlement—an often overlooked but significant phenomenon that compromises the integrity of metals. Through her research, she seeks to understand the mechanisms behind hydrogen-induced failures and propose mitigation strategies. These interconnected areas form a cohesive framework that allows Dr. Lu to address both fundamental questions and practical challenges in materials performance. Her interests are not only driven by academic curiosity but also by the broader societal need for more resilient, lightweight, and corrosion-resistant materials. By focusing her research on these critical topics, she aims to contribute to the development of next-generation metallic materials with enhanced longevity and reliability.

Research Skills

Dr. Yi Lu possesses a robust set of research skills that enable her to tackle complex problems in materials science with precision and innovation. She is proficient in a wide range of experimental techniques used to analyze the mechanical and corrosion behavior of metals, particularly aluminum alloys. Her expertise includes mechanical testing methods such as tensile, hardness, and fatigue analysis, which she uses to assess the structural integrity of alloys. In addition, she is skilled in metallographic examination and advanced microscopy, including scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDS), allowing her to investigate microstructural features at fine resolutions. Dr. Lu is also experienced in electrochemical testing methods, which are essential for understanding corrosion kinetics and resistance. Her analytical skills extend to data interpretation and modeling, ensuring that experimental findings are rigorously evaluated and contextually grounded. Furthermore, she demonstrates competence in scientific writing and has successfully published in high-impact SCI journals. Her collaborative research experience with the University of Auckland highlights her ability to contribute to international projects and interdisciplinary teams. Whether conducting experiments, interpreting results, or drafting manuscripts, Dr. Lu consistently applies scientific rigor and attention to detail, making her a capable and well-rounded researcher in her field.

Awards and Honors

Although Dr. Yi Lu is in the early stages of her academic and research career, she has already achieved notable recognition for her contributions to materials science. Her most significant honor to date is her participation in a national key research and development project, a competitive and prestigious initiative that selects promising researchers to contribute to groundbreaking scientific work. In this project, Dr. Lu’s role was instrumental in generating valuable findings related to aluminum alloy performance. She has published four SCI-indexed papers and one EI paper, with two articles appearing in high-impact SCI1 journals—an accomplishment that reflects both the quality and relevance of her research. Her work has received six citations, an encouraging indicator of her growing impact within the academic community. Dr. Lu has also been nominated for the Best Researcher Award, a testament to her dedication and early academic promise. These accolades, while still accumulating, signify her upward trajectory in the field. As she continues to publish, collaborate, and contribute to material science research, Dr. Lu is poised to garner more awards and recognition. Her commitment to excellence and innovation lays the groundwork for future honors at both national and international levels.

Conclusion

Dr. Yi Lu exemplifies the qualities of a dedicated and forward-thinking researcher in the field of materials science and engineering. Her academic journey and professional work are unified by a clear focus on improving the performance and durability of aluminum alloys, which are critical to a wide range of industrial applications. Through rigorous experimentation, international collaboration, and scholarly publication, she has demonstrated the ability to contribute meaningful insights to her discipline. Her areas of expertise—including mechanical behavior, corrosion mechanisms, refining methods, and hydrogen embrittlement—address some of the most pressing challenges in metallic materials. Despite being at an early stage in her career, Dr. Lu’s accomplishments—such as participation in a national research initiative and publications in high-tier journals—highlight her potential for future leadership in research and innovation. She continues to refine her experimental techniques, expand her scientific understanding, and seek impactful collaborations. Looking ahead, Dr. Lu aims to further integrate her theoretical knowledge with practical applications, ultimately contributing to the design and development of materials that are stronger, lighter, and more resistant to environmental stress. Her dedication to scientific progress and her methodical approach to research ensure that she will remain a valuable asset to her institution and the global materials science community.

 Publications Top Notes

  1. Title: High thermal stability of Si-containing Al-Zn-Mg-Cu crossover alloy caused by metastable GPB-II phase
    Authors: Yi Lu, Shengping Wen, Wu Wei, Xiaolan Wu, Kunyuan Gao, Hui Huang, Zuoren Nie
    Year: 2025

  2. Title: The enhanced aging hardening behavior in Si-containing Al-5Zn-1Mg-1Cu alloys
    Authors: Yi Lu, Shengping Wen, Zuoren Nie
    Year: 2024

  3. Title: The phase transformation and enhancing mechanical properties in high Zn/Mg ratio Al–Zn–Mg–Cu(-Si) alloys
    Authors: Yi Lu, Shengping Wen, Kunyuan Gao, Xiangyuan Xiong, Wu Wei, Xiaolan Wu, Hui Huang, Zuoren Nie
    Year: 2024

  4. Title: TeleAware Robot: Designing Awareness-augmented Telepresence Robot for Remote Collaborative Locomotion
    Authors: Ruyi Li, Yaxin Zhu, Min Liu, Yihang Zeng, Shanning Zhuang, Jiayi Fu, Yi Lu, Guyue Zhou, Can Liu, Jiangtao Gong
    Year: 2024