Prof. Ning Yongquan | Materials Science and Engineering | Best Researcher Award

Posted on 23/05/2025 by ScienceFather

Prof. Ning Yongquan | Materials Science and Engineering | Best Researcher Award

Northwestern Polytechnical University, China

Author Profile

Early Academic Pursuits

Yongquan Ning’s academic journey began with a strong foundation in materials science and engineering, a discipline he would eventually come to master and significantly contribute to. Born on May 14, 1982, in the People’s Republic of China, Ning’s early academic promise was evident from his undergraduate years. He completed his Bachelor of Science in Materials Science and Engineering at Nanchang Hangkong University in 2005, a period during which he was already involved in hands-on research in composite materials. His undergraduate work, which explored the fabrication and thermophysical properties of SiCp/Al composites, showcased a keen interest in materials innovation and experimentation.

Driven by a thirst for deeper knowledge and technological contribution, Ning proceeded to Northwestern Polytechnical University (NPU) in Xi’an, where he earned his Master’s degree in 2008 and subsequently a Ph.D. in 2010. His doctoral research delved into the high-temperature deformation behavior and recrystallization mechanisms of powder metallurgy (P/M) superalloys, under the mentorship of the distinguished Prof. Zekun Yao. His academic career further culminated in a postdoctoral fellowship at NPU in 2011, complemented by a year as a research associate at the prestigious Hong Kong Polytechnic University. These formative years solidified his expertise and prepared him for a lifelong contribution to materials engineering.

Professional Endeavors

Upon the completion of his postdoctoral training, Dr. Ning took on a faculty position at the School of Materials Science and Engineering at Northwestern Polytechnical University. From his base at NPU, he launched a range of research initiatives with significant academic and industrial relevance. Among his most enduring projects has been the study and optimization of structural-gradient materials (SGMs) used in dual-property turbine disks—an innovation pivotal to aerospace engineering.

His professional work has seamlessly blended academic inquiry with applied science. Ning has actively investigated the intricate relationships between gradient-temperature-heat-treatment parameters and their impact on the microstructure and mechanical properties of advanced alloys. His understanding of microstructure transitions, particularly the control of duplex grain regions, has enabled optimization efforts that significantly enhance the dual mechanical properties needed in high-performance turbine components.

Contributions and Research Focus

Dr. Ning’s primary research focus has revolved around the development and refinement of high-performance superalloys and structural-gradient materials. His contributions to understanding microstructural evolution during thermomechanical processing, including isothermal forging and hot compression, have offered novel insights into recrystallization behaviors and grain refinement mechanisms.

His work with powder metallurgy FGH4096 superalloys between 2006 and 2010 established foundational knowledge about the internal relationships between flow behavior and initial microstructures in HIPed (Hot Isostatically Pressed) materials. Additionally, his investigations into IN718 and GH4133A superalloys under various deformation conditions have had a lasting impact on forging technologies and alloy design strategies.

Accolades and Recognition

Dr. Ning’s academic excellence has been recognized consistently throughout his educational and professional career. As a student, he was the recipient of the First-Class Scholarship from NPU for four consecutive years (2006–2009), reflecting his outstanding academic performance and research achievements. In 2008, his growing expertise was acknowledged with the Second-Class Special Scholarship from the China Air-to-Air Missile Research Institute—an endorsement of both his intellectual capacity and the practical significance of his research in national defense technology.

In 2010, he was further honored with the Second-Class Chongde Scholarship awarded by the School of Materials Science and Engineering, signifying high regard from his academic community.

Impact and Influence

Through his research and teaching, Dr. Ning has influenced both his peers and a new generation of materials scientists. His investigations into gradient microstructures have provided critical pathways for improving dual-property materials, which are now crucial in aerospace and energy sectors. His close collaboration with both academic and industrial institutions has helped translate complex metallurgical theory into real-world engineering applications.

Furthermore, his work has added to the global body of knowledge on powder metallurgy and thermomechanical processing, enhancing the scientific community’s ability to develop materials that are lighter, stronger, and more resilient under extreme conditions. His scientific outputs not only push the boundaries of materials performance but also contribute directly to technological competitiveness in sectors vital to national and global progress.

Legacy and Future Contributions

As a scholar grounded in both theory and application, Dr. Yongquan Ning’s legacy lies in his methodical approach to solving some of the most pressing challenges in materials science. With a professional ethos rooted in curiosity, precision, and innovation, he is poised to continue contributing significantly to the development of high-performance materials for aerospace, defense, and energy systems.

Looking forward, Ning is expected to deepen his research in structural-gradient materials, possibly exploring additive manufacturing integrations and AI-driven materials design—fields that align with global trends in smart manufacturing and digital engineering. Through continued mentorship, publication, and cross-disciplinary collaboration, he stands to leave an enduring mark on both academic research and industry practices.

Notable Publications

Competition between dynamic recovery and recrystallization during hot deformation for TC18 titanium alloy

Authors: Y.Q. Ning, X. Luo, H.Q. Liang, H.Z. Guo, J.L. Zhang, K. Tan
Journal: Materials Science and Engineering: A, Vol. 635, pp. 77–85
Year: 2015

Dynamic softening behavior of TC18 titanium alloy during hot deformation

Authors: Y.Q. Ning, B.C. Xie, H.Q. Liang, H. Li, X.M. Yang, H.Z. Guo
Journal: Materials & Design, Vol. 71, pp. 68–77
Year: 2015

DDRX and CDRX of an as-cast nickel-based superalloy during hot compression at γ′ sub-/super-solvus temperatures

Authors: B. Xie, H. Yu, T. Sheng, Y. Xiong, Y. Ning, M.W. Fu
Journal: Journal of Alloys and Compounds, Vol. 803, pp. 16–29
Year: 2019

Mechanisms of DRX nucleation with grain boundary bulging and subgrain rotation during the hot working of nickel-based superalloys with columnar grains

Authors: B. Xie, B. Zhang, Y. Ning, M.W. Fu
Journal: Journal of Alloys and Compounds, Vol. 786, pp. 636–647
Year: 2019

Microstructure evolution and underlying mechanisms during the hot deformation of 718Plus superalloy

Authors: B. Xie, B. Zhang, H. Yu, H. Yang, Q. Liu, Y. Ning
Journal: Materials Science and Engineering: A, Vol. 784, Article 139334
Year: 2020

Assist Prof Dr. Xianshu Qiao | Electrocatalysis | Best Researcher Award

Posted on 14/05/202514/05/2025 by ScienceFather

Assist Prof Dr. Xianshu Qiao | Electrocatalysis | Best Researcher Award

Jingdezhen Ceramic University, China

Author Profile

Orcid

Early Academic Pursuits

Dr. Xianshu Qiao’s journey in materials science began with a strong foundation in chemical engineering. She earned her Master’s degree in Chemical Engineering and Technology from Inner Mongolia University of Technology, China, where she developed a keen interest in chemical processes and reaction mechanisms. Her master’s dissertation, focused on the absorption of sulfur dioxide and the preparation of barium sulfate using a triethylene glycol and dimethyl sulfoxide system, showcased her ability to tackle complex chemical challenges. This early exposure to chemical processes not only honed her analytical skills but also laid the groundwork for her future exploration of catalysis and materials science.

Her academic pursuit reached new heights when she embarked on a Ph.D. program in Materials Science and Engineering at Harbin Institute of Technology, one of China’s top technical universities. Under the mentorship of distinguished professors Wei Qin and Xiaohong Wu, Dr. Qiao focused on the preparation of iridium and iron co-modified β-Ni(OH)₂ electrode materials, with a particular emphasis on their oxygen evolution performance. Her doctoral research was marked by a meticulous approach to material design and synthesis, leading to the development of highly efficient electrode materials. These experiences not only enriched her scientific knowledge but also cemented her passion for electrocatalysis, a field that would become the core of her research career.

Professional Endeavors

Dr. Xianshu Qiao’s career as an academic and researcher has been defined by her role as an Associate Professor of Materials Science at Jingdezhen Ceramic University. In this position, she has seamlessly integrated teaching, mentorship, and research, shaping the next generation of scientists while advancing the field of materials science. Her dedication to education is evident in her ability to inspire students, instilling in them a strong foundation in scientific principles and a curiosity for research.

In her research, Dr. Qiao has established herself as a leading figure in the development of transition metal-based electrocatalysts. Her work centers on the rational design, controlled synthesis, and catalytic reaction mechanisms of materials, particularly those involving nickel, iron, and cobalt compounds. Her extensive research on these materials has led to significant advancements in the efficiency of oxygen evolution reaction (OER) and hydrogen evolution reaction (HER), two critical processes for sustainable energy conversion. As a researcher, she has demonstrated a rare ability to bridge theoretical insights with practical applications, making substantial contributions to the development of efficient, durable catalysts.

Contributions and Research Focus

Dr. Xianshu Qiao’s research is characterized by a deep understanding of transition metal-based electrocatalysts, particularly those involving nickel, iron, and cobalt. Her focus on the rational design and controlled synthesis of these materials has led to the development of catalysts with exceptional performance in OER and HER. These reactions are vital for renewable energy technologies, including water splitting and hydrogen production.

Her work has resulted in numerous high-impact publications, including 13 SCI papers as the first author in internationally recognized journals such as Applied Catalysis B: Environmental, Small, International Journal of Hydrogen Energy, ACS Applied Materials and Interfaces, and Inorganic Chemistry Frontiers. These publications reflect not only her expertise in the field but also her commitment to advancing scientific knowledge. In addition to her first-author publications, she has co-authored more than 30 SCI papers, demonstrating her ability to collaborate with other researchers and contribute to multidisciplinary projects.

One of her most notable achievements is the development of porous Fe-doped β-Ni(OH)₂ nanopyramid array electrodes for water splitting, a breakthrough that has been widely recognized in the field. Her innovative approach to catalyst design, involving electronic dual modulation and grain boundary engineering, has set a new standard for the performance of transition metal-based catalysts. This work has not only advanced the understanding of catalytic mechanisms but also paved the way for the development of next-generation energy storage and conversion technologies.

Accolades and Recognition

Dr. Xianshu Qiao’s contributions to materials science have earned her significant recognition in the scientific community. Her research has been published in some of the most prestigious journals in the field, and her work on transition metal-based electrocatalysts has been widely cited by peers worldwide. Her reputation as a leading researcher is further reinforced by her extensive publication record, which includes 13 first-author SCI papers and over 30 co-authored SCI papers.

Beyond her publications, Dr. Qiao has been recognized for her ability to mentor and inspire young researchers. Her role as an educator at Jingdezhen Ceramic University has allowed her to shape the careers of aspiring scientists, fostering a culture of academic excellence and intellectual curiosity. Her dedication to scientific rigor and innovation has made her a respected figure in the academic community.

Impact and Influence

The impact of Dr. Qiao’s research extends far beyond her publications. Her innovative work on efficient electrocatalysts has the potential to drive the development of sustainable energy solutions, contributing to global efforts to combat climate change. By improving the efficiency of OER and HER, her catalysts can enhance the performance of renewable energy systems, making them more viable for large-scale applications.

As an educator and mentor, Dr. Qiao has influenced the next generation of scientists, equipping them with the skills and knowledge needed to excel in their careers. Her ability to foster a collaborative and intellectually stimulating research environment has inspired many young researchers to pursue careers in materials science.

Legacy and Future Contributions

Dr. Xianshu Qiao’s legacy is one of scientific excellence, innovation, and mentorship. Her groundbreaking research on transition metal-based electrocatalysts has transformed the field of catalysis, providing new insights into the design and optimization of efficient, durable catalysts. As she continues to explore new materials and catalytic mechanisms, her work will likely lead to further advancements in sustainable energy technologies.

In the future, Dr. Qiao is expected to expand her research into new areas of energy conversion and storage, exploring the potential of novel materials and catalytic systems. Her commitment to education and mentorship will continue to shape the careers of young scientists, ensuring that her legacy endures for generations to come.

Notable Publications

Hierarchical Ultrafine Nanosheet-Based O-Doped FeCoS₂ Microsphere Catalyst for Highly Efficient Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: International Journal of Hydrogen Energy
Year: 2025

Ultra-Small β-Ni(OH)₂ Quantum Dot Catalyst with Abundant Edges for an Efficient Urea Oxidation Reaction

Author: Xianshu Qiao
Journal: Inorganic Chemistry Frontiers
Year: 2025

Modulating Electronic Structure of Iridium Single-Atom Anchored on 3D Fe-Doped β-Ni(OH)₂ Catalyst with Nanopyramid Array Structure for Enhanced Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Small
Year: 2024

Grain Boundary Density and Electronic Dual Modulation of Intermetallic Co₂B by Fe Doping Toward Efficient Catalyst for Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Applied Catalysis B: Environmental
Year: 2022

Novel FeNi-Based Nanowires Network Catalyst Involving Hydrophilic Channel for Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Small
Year: 2022

Assoc Prof Dr. Ayse Nihan Basmaci | materials | Best Researcher Award

Posted on 16/04/2025 by ScienceFather

Assoc Prof Dr. Ayse Nihan Basmaci | materials | Best Researcher Award

Tekirdag Namik Kemal University, Turkey

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Early Academic Pursuits: The Foundations of Brilliance

Ayşe Nihan Basmacı’s academic journey began with a clear and passionate vision rooted in electrical and electronics engineering. Her foundational years were shaped at Pamukkale University, where she pursued a Bachelor of Science degree in Electrical-Electronics Engineering from 2004 to 2008. Her early interest in understanding the behavior of electronic systems, particularly the wave-based phenomena in engineered materials, guided her into graduate studies with an inquisitive mindset and technical precision.

She advanced seamlessly into a Master of Science at the same university, earning her degree in 2011. This formative period sharpened her theoretical understanding and experimental skills, setting a strong base for further scholarly exploration. Committed to academic excellence, she continued on to a Ph.D. in the same discipline, completing it in 2017. Her doctoral work laid the groundwork for future exploration into electromagnetic wave propagation, a field where she has made significant scholarly contributions.

Professional Endeavors: Educator and Innovator

Since 2012, Ayşe Nihan Basmacı has been an integral part of Tekirdağ Namık Kemal University, beginning her career as a lecturer and eventually rising to the rank of Associate Professor in the Department of Electronics and Automation within the Vocational School of Technical Sciences. Her dedication to education is evident in her decade-long contribution to developing electronic engineering curricula and mentoring students in practical and research-intensive environments.

Between 2021 and 2022, she also took on an administrative role as Deputy Director of the Research and Application Center, showcasing her leadership abilities and commitment to fostering an innovative research culture within the institution.

Contributions and Research Focus: Exploring the Invisible

Assoc. Prof. Basmacı’s research centers around electromagnetic wave propagation, particularly in advanced materials like carbon nanotubes, photonic crystals, and welded functionally graded structures. She has a keen interest in understanding how electromagnetic waves interact with novel materials, which has vast implications in communications, photonics, and material science.

Her scholarly output is prolific and impactful. In recent years, she has published in respected international journals such as Materials, Coatings, Applied Sciences, and the Journal of Optoelectronics and Advanced Materials. Her work includes investigating backward wave behavior in carbon nanotube-coated metamaterials, and simulating electromagnetic properties in photonic-like welded structures using the finite element method.

She also delves into experimental and computational analyses, as seen in her studies on welded rods with functionally graded materials, and dual-mode microstrip filters for communication systems. This diverse but coherent body of research reflects both scientific depth and practical relevance.

Accolades and Recognition: A Scholar’s Rising Star

While specific awards and honors are not explicitly listed, her appointment as an Associate Professor in 2022 is a significant academic milestone that speaks volumes about her reputation, contributions, and recognition within the scientific community. Her collaborative works with other noted researchers like Filiz Seçkin, Ceyhun Karpuz, and Ali Kürşad Görür further underscore her visibility and respect in the field of electronics and applied physics.

The citation of her articles, particularly those published in high-impact journals with rigorous peer review, demonstrates the value of her work to both academia and industry. She has positioned herself as a knowledgeable voice in a highly technical and specialized area of research.

Impact and Influence: Bridging Theory and Application

Assoc. Prof. Basmacı’s research on carbon nanostructures and photonic waveguides has implications for the development of next-generation communication systems, sensors, and metamaterials. Through her investigations, she contributes to the global scientific understanding of how materials at the nanoscale behave under electromagnetic influence — a key to innovations in 5G/6G technologies, biomedical imaging, and defense systems.

Her academic influence also extends to her role as a mentor and educator. Generations of engineering students have benefited from her lectures and research supervision, gaining both technical skills and inspiration to pursue careers in electronics and material science.

Legacy and Future Contributions: A Vision of Progress

Looking ahead, Ayşe Nihan Basmacı stands at the confluence of emerging technologies and scientific discovery. Her expertise in computational electromagnetics and nanomaterials places her in a unique position to lead interdisciplinary research projects that could redefine materials engineering and telecommunications.

With the steady growth of fields like quantum computing, smart materials, and wearable electronics, her work is expected to become even more relevant. Her future contributions will likely focus on expanding the functionality of metamaterials and optimizing photonic structures for energy efficiency and signal clarity.

Through a rich combination of teaching, research, and leadership, Assoc. Prof. Basmacı is not only shaping the field of electromagnetic engineering but also cultivating a legacy of scientific curiosity and educational excellence.

Characteristics of electromagnetic wave propagation in a segmented photonic waveguide

Author: Ayşe Nihan Basmacı
Journal: Journal of Optoelectronics and Advanced Materials
Year: 2020

Experimental analysis of welded rods with a functionally graded material approach

Author(s): Ayşe Nihan Basmacı, Filiz Seçkin, Mümin Şahin
Journal: Applied Sciences
Year: 2020

Design of tunable microstrip dual-mode bandpass filter having reconfigurable filtering characteristics for mobile applications

Author(s): Ceyhun Karpuz, Ali Kürşad Görür, Ayşe Nihan Basmacı
Conference: 46th European Microwave Conference (EuMC)
Year: 2016

Design and analysis of a compact dual-mode dual-band microstrip bandpass filter

Author(s): Ceyhun Karpuz, Ali Kürşad Görür, Ayşe Nihan Basmacı, Ahmet Özek
Journal: Journal of Electromagnetic Waves and Applications
Year: 2013

Dual‐mode dual‐band microstrip bandstop filter design with independently tunable center frequencies

Author(s): Ali Kürşad Görür, Ayşe Nihan Basmacı, Engin Doğan, Ceyhun Karpuz, Adnan Görür
Journal: Microwave and Optical Technology Letters
Year: 2017

Dr. Sumaira Nazar Hussain | Materials Chemistry | Best Researcher Award

Posted on 01/04/2025 by ScienceFather

Dr. Sumaira Nazar Hussain | Materials Chemistry | Best Researcher Award

Shenzhen University, China

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Early Academic Pursuits

Sumaira Nazar’s academic journey began with a strong foundation in chemistry, earning her Bachelor of Science degree from Lahore College for Women University in Pakistan. She furthered her education with a Master of Science degree in Chemistry from the same institution. Her passion for chemistry led her to pursue a Bachelor of Education degree from Allama Iqbal Open University in Islamabad, Pakistan. This diverse educational background laid the groundwork for her future success in research and academia.

Professional Endeavors

Sumaira Nazar’s professional endeavors took a significant leap when she enrolled in the Ph.D. program in Chemistry at Wuhan University in China. Her research focus on nanomaterial synthesis for clean energy and environmental applications earned her a Ph.D. degree. Currently, she works as a Postdoctoral Researcher at the Institute for Advanced Study, Shenzhen University, in Shenzhen, China. Her role involves conducting research, collaborating with colleagues, and contributing to the academic community.

Contributions and Research Focus

Sumaira Nazar’s research expertise lies in nanomaterial synthesis, electrocatalytic water splitting, and nano-impact electrochemistry. Her work focuses on developing sustainable solutions for clean energy and environmental applications. She has published 10 papers in reputable peer-reviewed journals, showcasing her commitment to advancing knowledge in her field. Her research has garnered significant attention, with a total impact factor of over 100 and an H-index of 6 since 2022.

Accolades and Recognition

Sumaira Nazar’s outstanding contributions to research have earned her recognition within the academic community. Her publications have been cited over 100 times, demonstrating the impact of her work. Her commitment to research excellence has also been acknowledged through various awards and accolades.

Impact and Influence

Sumaira Nazar’s research has far-reaching implications for sustainable energy and environmental solutions. Her work on nanomaterial synthesis and electrocatalytic water splitting has the potential to contribute significantly to the development of clean energy technologies. As a researcher, she continues to inspire and influence the next generation of scientists and researchers.

Legacy and Future Contributions

Sumaira Nazar’s legacy in the field of chemistry and materials science will be marked by her significant contributions to research and academia. As she continues her research endeavors, she is poised to make even more groundbreaking discoveries, advancing our understanding of sustainable energy and environmental solutions. Her commitment to research excellence and her passion for chemistry will undoubtedly leave a lasting impact on the scientific community.

Notable Publications

Molybdenum-Induced Tuning 3d-Orbital Electron Filling Degree of CoSe₂ for Alkaline Hydrogen and Oxygen Evolution Reactions

Author: SN Hussain, Y Men, Z Li, P Zhao, G Cheng, W Luo

Journal: Chinese Chemical Letters

Year: 2023

GM Trust Shaped by Trust Determinants with the Impact of Risk/Benefit Framework: The Contingent Role of Food Technology Neophobia

Author: S Ali, MA Nawaz, M Ghufran, SN Hussain, AS Hussein Mohammed

Journal: GM Crops & Food

Year: 2021

Advancing the Development of Hollow Micro/Nanostructured Materials for Electrocatalytic Water Splitting: Current State, Challenges, and Perspectives

Author: MA Mushtaq, M Ahmad, A Shaheen, A Mehmood, G Yasin, M Arif, Z Ali, SN Hussain

Journal: ACS Materials Letters

Year: 2024

The Psychological Perspective on the Adoption of Approved Genetically Modified Crops in the Presence of Acceptability Constraint: The Contingent Role of Passion

Author: S Ali, M Ghufran, MA Nawaz, SN Hussain

Journal: GM Crops & Food

Year: 2019

Morphology-Controlled Synthesis of Cobalt Diselenide Nanorods for Highly Efficient Hydrogen Evolution in Alkaline and Acidic Media

Author: SN Hussain, H Gul, N Raza, F Albouchi, M Ahmad, ZM El-Bahy

Journal: Journal of Alloys and Compounds

Year: 2023

Prof. Fanxiu Chen | Intenational Material Scientist Awards | Best Researcher Award

Posted on 04/03/2025 by ScienceFather

Prof. Fanxiu Chen | Intenational Material Scientist Awards | Best Researcher Award

Qingdao University of Technology,China

Profile

Scopus

Early Academic Pursuits

Fanxiu Chen’s journey in academia began with a strong foundation in mechanical engineering, where she cultivated a deep interest in experimental mechanics and material behavior analysis. Her early academic years were characterized by a curiosity for understanding the intrinsic properties of materials and their response to external forces. She pursued her studies with an unwavering commitment to scientific discovery, delving into the complexities of optomechanical methods and their applications. Recognizing the need for advanced measurement techniques, she dedicated herself to exploring novel methodologies for analyzing mechanical properties, setting the stage for her future contributions to the field.

Professional Endeavors

As a professor and doctoral supervisor, Fanxiu Chen has played a pivotal role in advancing experimental mechanics and testing technology. Her professional journey has been marked by active participation in esteemed committees, including the Professional Committee of Experimental Mechanics of the Chinese Mechanical Society and the Professional Committee of Testing Technology of the Production Engineering Branch of the Chinese Mechanical Engineering Society. She has also been recognized as a young expert of Taishan Scholars in Shandong Province. Her work has bridged the gap between theoretical research and practical applications, particularly in the safety assessment and monitoring of major infrastructure projects in coastal environments.

Her research focuses on developing high-precision optical non-contact detection technologies to enhance the reliability of concrete infrastructure. By integrating modern optomechanical methods with structural health monitoring, she has provided groundbreaking insights into material degradation, damage evaluation, and safety diagnostics. Through collaboration with interdisciplinary teams, she has successfully translated her findings into real-world applications, benefiting large-scale engineering projects across the globe.

Contributions and Research Focus

At the core of Fanxiu Chen’s research lies a dedication to improving the durability and longevity of reinforced concrete structures, particularly those exposed to harsh coastal environments. She has led systematic investigations into the microstructural evolution of concrete, analyzing how factors such as multi-ion coupling, steel corrosion, and environmental stressors influence material integrity. Her work has provided a scientific basis for predicting the service life of reinforced concrete structures, offering innovative solutions for mitigating structural degradation.

One of her most notable contributions is the development of a seamless multi-camera 3D-DIC method, which allows for high-precision real-time monitoring of structural performance. Additionally, she has pioneered the use of an underwater non-contact camera array for rapid assessment of damage in submerged structures. These technological advancements have revolutionized the way engineers approach infrastructure maintenance, enabling early detection of vulnerabilities and informed decision-making.

Her research has also yielded significant advancements in steel corrosion analysis. By establishing theoretical models for corrosion expansion forces under various environmental conditions, she has shed light on the relationship between corrosion-induced stress and surface strain in concrete. Her findings have been widely recognized, including the selection of her work as a highly cited ESI paper. Furthermore, her contributions to reducing steel reinforcement expansion forces have had a tangible impact on enhancing structural resilience.

Accolades and Recognition

Fanxiu Chen’s exemplary contributions have earned her numerous prestigious accolades, solidifying her reputation as a leading researcher in her field. She was among the first to be selected for the “Shandong Provincial Plan for the Introduction of Young Creative Talents in Colleges and Universities” in 2019. Her team’s research has resulted in the authorization of 10 domestic and international patents and the publication of three academic monographs and textbooks.

Her groundbreaking work has not only garnered recognition in academia but also in industry. The high-precision optical non-contact detection technology she developed has been successfully commercialized in partnership with major enterprises, including Dantec in Germany and leading companies in Shenzhen and Nanjing. The widespread adoption of her technology in over 20 countries, including the United Kingdom, the United States, and Canada, attests to the global impact of her innovations.

Her influence extends beyond research, as she has played a crucial role in mentoring the next generation of engineers and researchers. Under her guidance, her students have achieved remarkable success, winning national scholarships, provincial excellence awards, and recognition for innovation. Her dedication to fostering young talent has solidified her legacy as both a scholar and a mentor.

Impact and Influence

The impact of Fanxiu Chen’s research is far-reaching, with practical applications in critical infrastructure projects such as Qingdao Metro, Qinglian Railway, and Jiaozhou Bay Subsea Tunnel. Her contributions have been instrumental in ensuring the structural integrity of these projects, leading to prestigious awards such as the Luban Award and the National Quality Engineering Award.

Beyond engineering applications, her work has contributed significantly to the field of experimental mechanics, providing a deeper understanding of material behavior under complex environmental conditions. Her research has influenced policy-making in infrastructure safety, guiding best practices for maintenance and rehabilitation strategies. The economic and social benefits of her contributions are evident, with newly added sales revenue from her industrialized technologies surpassing 1.2 billion yuan in the past two years alone.

Legacy and Future Contributions

Looking ahead, Fanxiu Chen remains dedicated to pushing the boundaries of material science and structural health monitoring. Her future endeavors include further refining high-precision monitoring technologies and expanding the application of artificial intelligence in predictive maintenance. She envisions developing an intelligent, data-driven platform for real-time infrastructure monitoring, integrating machine learning algorithms to enhance predictive capabilities.

As a trailblazer in her field, she continues to inspire future researchers and engineers, advocating for a proactive approach to structural safety. Her unwavering commitment to scientific exploration, technological innovation, and knowledge dissemination ensures that her contributions will shape the landscape of engineering and material science for generations to come.

Notable Publications

Effects of water-cement ratio and particle diameter on the mechanical properties of cement paste particles

Author: Z. Qiu, Ziming; F. Chen, Fanxiu; Y. Yu, Yang; X. Wang, Xiao; Y. Wang, Yuan
Journal: Optics and Lasers in Engineering
Year: 2025

Structural properties and mechanical behavior of three-dimensional cylindrical particle-like systems under in situ loading

Author: Y. Gu, Yanji; F. Chen, Fanxiu; Y. Yu, Yang; J. Liu, Jinglan; Z. Qiu, Ziming
Journal: Powder Technology
Year: 2025

Contact force calculation and evolution analysis of granular systems based on micro-CT experiment

Author: X. Wang, Xiao; S. Song, Shiqi; Z. Ping, Zijian; X. Shang, Xianyi; F. Chen, Fanxiu
Journal: Wuli Xuebao/Acta Physica Sinica
Year: 2025

Quasi-static modeling of a cable-driven continuum manipulator considering non-smooth cable-hole friction and experimental verification

Author: S. Zhang, Shucui; J. Zhao, Jiayuan; X. Zhang, Xingang; H. Peng, Haijun; C. Liu, Caishan
Journal: Mechanism and Machine Theory
Year: 2024

Seckin Akin | Perovskite Solar Cells | Best Researcher Award

Posted on 12/12/202312/12/2023 by ScienceFather

Congratulations, Seckin Akin | Best Researcher Award| Perovskite Solar Cells | Award Winner 2023

Seckin Akin : Perovskite Solar Cells

Seckin Akin: Congratulations on Best Researcher Award for Perovskite Solar Cells! In recognition of your outstanding contributions to the field of materials science and engineering, particularly in the advancement of perovskite solar cells, we extend our heartfelt congratulations on receiving the prestigious Best Researcher Award. Your innovative work, dedication, and impactful research have not only earned you this well-deserved honor but have also significantly contributed to the progress of renewable energy technology. Your achievements inspire and set a benchmark for excellence in the scientific community. Bravo!

Professional Profile

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Early Academic Pursuits: Building the Foundation

Seckin Akin embarked on a journey of academic excellence, laying the groundwork for his impactful career. His quest for knowledge commenced with a Bachelor of Science degree in Physics (English) from Abant İzzet Baysal University, spanning from 2004 to 2009. Eager to deepen his understanding, he pursued a Master of Science in Physics/Solid State Physics at Anadolu University from 2009 to 2012. This phase of academic exploration marked the early stages of his commitment to the intricacies of materials science and engineering.

Professional Endeavors: Contributions to Materials Science and Engineering

Seckin Akin's professional journey is characterized by noteworthy contributions to the field of materials science and engineering. His active engagement in research spans diverse areas, including inorganic nanoparticle synthesis, thin film production, and the optoelectronic properties of materials. Notably, his work extends into the specialized domain of perovskite solar cells, showcasing his multidisciplinary expertise.

Contributions and Research Focus: Advancing Solar Cell Technology

Akin's contributions to the scientific community are substantial, particularly in the synthesis of new-generation inorganic nanoparticles and their application in perovskite solar cells. His research focus encompasses investigating inorganic nanoparticle synthesis, thin film production, and the optoelectronic properties of materials. A significant milestone in his research journey is the design and development of efficient and stable perovskite solar cells.

An exemplary achievement in this regard is the patent for an organometallic perovskite solar cell, tandem solar cell, and the associated manufacturing process (US20210249196A1). This patent underscores Akin's innovative approach to advancing solar cell technology, showcasing his prowess in translating research findings into practical applications.

Accolades and Recognition: A Trail of Achievements

Seckin Akin's accomplishments have garnered well-deserved recognition, as evidenced by a string of awards and honors:

2022: Entrepreneurship Grant by the Individual Young Entrepreneur Program (BIGG).
2021: Science Academy's Young Scientist Awards Program (BAGEP).
2021: SPTech Congress, Best Presentation Award.
2020: TUBITAK, BIDEB 2247-A – National Leading Researchers Programme.
2018: TUBITAK, BIDEB 2214-A – International Research Fellowship Programme (Laboratory of Photonics and Interfaces – LPI – EPFL, Switzerland / Supervisor: Prof. Michael Grätzel).
2017: E-MRS Fall Meeting, Best Presentation Award.
2017: ICENTE’17, Best Presentation Award.
2015: Konya Technocity, University - Industry Collaboration Award.

Impact and Influence: Shaping Scientific Discourse

Seckin Akin's impact on the scientific community is palpable through a prolific output of scientific publications. His work, published in reputable journals, has significantly shaped the discourse in materials science and engineering. Notable contributions include the development of efficient and stable perovskite solar cells with a record efficiency over 17%, exploration of composition engineering for operationally stable CsPbI2Br perovskite solar cells, and probing the low-frequency response of impedance spectroscopy of halide perovskite single crystals using machine learning.

Legacy and Future Contributions: Shaping the Landscape of Renewable Energy

Akin's legacy is firmly rooted in his pioneering work in the synthesis of inorganic nanoparticles and their application in solar cell technology. His dedication to advancing the understanding and practical applications of perovskite solar cells and optoelectronic properties has left an indelible mark on the field of materials science and engineering. As he continues his academic and research journey, the anticipation is high for Akin to further shape the landscape of renewable energy, leaving a lasting impact on the future of sustainable technology.