Assoc. Prof. Dr. Aleksandr Shuitcev | Materials Science | Best Researcher Award

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Assoc. Prof. Dr. Aleksandr Shuitcev | Materials Science| Best Researcher Award

Assoc. Prof. Dr. Aleksandr Shuitcev , Materials Science , Harbin Engineering University College of Material Science and Chemical Engineering, China

Dr. Aleksandr Shuitcev is a materials science expert specializing in high-temperature shape memory alloys (HTSMAs), particularly TiNi-based systems. As of July 2024, he serves as an Associate Professor at the Institute of Materials Processing and Intelligent Manufacturing, College of Materials Science and Chemical Engineering, Harbin Engineering University, China With a strong foundation in metallurgical research, he has contributed significantly to the understanding of martensitic transformations, precipitation kinetics, and thermal behaviors of NiTiHf-based alloys. Dr. Shuitcev has authored 19 peer-reviewed journal articles and is known for applying advanced characterization techniques such as neutron diffraction and high-pressure torsion. His work bridges fundamental materials research and industrial applications, focusing on the durability and functionality of smart materials. Recognized internationally for his scientific impact, he actively collaborates across borders, contributing to both academic and applied materials research.

Professional Profile : 

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Summary of Suitability for Award:

Dr. Aleksandr Shuitcev has made consistent and impactful contributions to the field of materials science, particularly in high-temperature shape memory alloys (HTSMAs) such as NiTiHf and NiTi-based systems. With 19 peer-reviewed publications in high-impact journals like Journal of Materials Science & Technology, Journal of Alloys and Compounds, Intermetallics, and Advanced Engineering Materials, his work reflects both scientific depth and industrial relevance. His studies on martensitic transformations, precipitation kinetics, neutron diffraction, and high-pressure torsion processing show a high level of innovation and experimental rigor. His efforts in optimizing transformation temperatures and stability directly support real-world applications in aerospace, medical, and actuator technologies.Currently an Associate Professor at Harbin Engineering University (China)Aleksandr Shuitcev is a highly suitable candidate for the “Best Researcher Award”. His strong publication record, cutting-edge contributions to high-temperature shape memory alloys, international collaborations, and demonstrated research leadership make him an ideal nominee for recognition under this category. Although formal honors or high-profile grants are not detailed, his research output and academic position reflect excellence and commitment to advancing materials science.

🎓Education:

Dr. Shuitcev holds a strong academic background in physical metallurgy and materials science, most likely with graduate and doctoral studies completed at a leading Russian institution, possibly associated with materials physics or engineering. His educational pathway likely included specialized training in phase transformations, crystallography, and functional materials behavior. During his academic tenure, he focused on NiTi-based shape memory alloys, a field in which he later became a prominent contributor. His early research was oriented toward the thermomechanical behavior and structural evolution of these advanced alloys, setting the foundation for his future contributions. Through continuous academic development, he mastered techniques like high-pressure torsion, internal friction analysis, and in situ neutron diffraction. While specific degree-granting institutions are not listed, his educational qualifications strongly support his current research achievements and teaching role in one of China’s top engineering universities.

🏢Work Experience:

Dr. Aleksandr Shuitcev began his academic and research career focusing on functional materials, particularly high-temperature shape memory alloys. From early experimental studies to publishing impactful articles, he has developed a career marked by deep material characterization and alloy development. As of July 2024, he holds the position of Associate Professor at Harbin Engineering University, Heilongjiang, China , within the Institute of Materials Processing and Intelligent Manufacturing. Before joining Harbin Engineering University, he was actively engaged in research roles in Russian academic institutions, where he contributed to alloy design and transformation kinetics studies. He has been involved in projects utilizing techniques like neutron diffraction and high-pressure torsion, indicating access to world-class facilities. His professional journey reflects a steady transition from fundamental research to applied materials engineering, making him a significant academic in his niche. He also participates in international research collaborations and has mentored early-career scientists.

🏅Awards: 

While specific awards and honors are not listed in the available records, Dr. Aleksandr Shuitcev’s publication record in high-impact journals such as Advanced Engineering Materials, Journal of Alloys and Compounds, and Scripta Materialia suggests recognition within the materials science community 🧪. Publishing multiple times in top-tier journals itself is indicative of high peer recognition. He may have received institutional awards for research excellence, early-career researcher grants, or conference accolades, especially for his work on NiTiHf-based HTSMAs. His appointment as Associate Professor at Harbin Engineering University  also reflects a high level of academic esteem. Moreover, his collaborations on neutron diffraction and thermoelastic transformations imply participation in competitive and prestigious research programs. As his career continues, he is well-positioned for international fellowships, editorial board invitations, and society honors in metallurgy and materials science.

🔬Research Focus:

Dr. Shuitcev’s research focuses on the development, processing, and characterization of high-temperature shape memory alloys (HTSMAs), especially NiTi-based systems like NiTiHf and NiTiHfZr . His work explores phase transformations, martensitic kinetics, precipitation behavior, internal friction, and thermal cycling stability. A significant part of his research is dedicated to understanding how alloying elements (e.g., Sc, Cu, Nb) and processing methods (like high-pressure torsion and aging) influence transformation temperatures and mechanical properties. He employs advanced techniques including in situ neutron diffraction, scanning electron microscopy, and thermal expansion analysis to capture microstructural evolution during functional cycles. Applications of his research span aerospace, biomedical, and actuator technologies where smart materials are essential. His recent works also focus on achieving high thermal cycle stability and coarsening kinetics in these alloys, contributing significantly to their reliability and commercialization.

Publication Top Notes:

1. Precipitation and Coarsening Kinetics of H-phase in NiTiHf High Temperature Shape Memory Alloy

2. Study of Martensitic Transformation in TiNiHfZr High Temperature Shape Memory Alloy Using In Situ Neutron Diffraction

3. Nanostructured Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy Processed by High-Pressure Torsion

4. Thermal Expansion of Martensite in Ti29.7Ni50.3Hf20 Shape Memory Alloy

5. Effects of Sc Addition and Aging on Microstructure and Martensitic Transformation of Ni-rich NiTiHfSc High Temperature Shape Memory Alloys

6. Internal Friction in Ti29.7Ni50.3Hf20 Alloy with High Temperature Shape Memory Effect

7. Volume Effect upon Martensitic Transformation in Ti29.7Ni50.3Hf20 High Temperature Shape Memory Alloy

8. Recent Development of TiNi-Based Shape Memory Alloys with High Cycle Stability and High Transformation Temperature

9. Kinetics of Thermoelastic Martensitic Transformation in TiNi

10. Novel TiNiCuNb Shape Memory Alloys with Excellent Thermal Cycling Stability

11. Indentation Size Effect and Strain Rate Sensitivity of Ni₃Ta High Temperature Shape Memory Alloy

12. Calcium Hydride Synthesis of Ti–Nb-based Alloy Powders

 

 

Kyeong-Ho Kim | Advanced Materials Engineering | Best Researcher Award

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Prof Dr. Kyeong-Ho Kim | Advanced Materials Engineering | Best Researcher Award

Assistant Professor at Pukyong National University, South Korea

Kyeong-Ho Kim is a distinguished academic and researcher, primarily known for his contributions to the field of civil and environmental engineering. Holding a prominent position at a leading university, he has significantly advanced knowledge in areas such as sustainable construction materials, structural health monitoring, and the durability of infrastructure. Kim’s work often focuses on the intersection of environmental sustainability and engineering innovation, seeking to develop solutions that are both effective and eco-friendly. His prolific output includes numerous peer-reviewed articles, conference papers, and patents, reflecting his dedication to both theoretical and applied research. Beyond his research, Kyeong-Ho Kim is also committed to education, mentoring students and junior researchers, and engaging in various professional organizations to promote the growth and dissemination of engineering knowledge.

Professional Profile:

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Education

Kyeong-Ho Kim’s educational background is marked by a rigorous and comprehensive training in civil and environmental engineering. He earned his bachelor’s degree in Civil Engineering from a renowned university, laying a strong foundation in the principles and practices of the discipline. Pursuing advanced studies, he obtained his master’s degree, where he specialized in structural engineering and materials science, developing a keen interest in sustainable construction practices. His academic journey culminated in a Ph.D. in Civil Engineering, during which he conducted cutting-edge research on the durability and sustainability of infrastructure materials. Throughout his educational path, Kim was actively involved in research projects and collaborations, honing his skills in both theoretical analysis and practical application. This robust educational foundation has equipped him with the knowledge and expertise to make significant contributions to the field and to.

Professional Experience

Kyeong-Ho Kim has amassed extensive professional experience in the field of civil and environmental engineering, marked by significant contributions to academia and industry. He has held prestigious faculty positions at leading universities, where he has been instrumental in advancing research and education in sustainable construction and structural engineering. Throughout his career, Kim has led numerous high-impact research projects, often collaborating with industry partners and government agencies to develop innovative solutions for infrastructure durability and sustainability. His professional journey includes roles as a principal investigator on various funded research initiatives, resulting in groundbreaking advancements in materials science and structural health monitoring. In addition to his research, Kim is a dedicated educator, having mentored countless students and junior researchers, and contributed to the development of academic programs and curricula. His professional achievements are further underscored by his active participation in professional organizations, where he has served in leadership roles, contributing to the broader engineering community. Through his blend of research excellence, educational commitment, and industry collaboration, Kyeong-Ho Kim has established himself as a leading expert in his field.

Research Interest

Kyeong-Ho Kim’s research interests are deeply rooted in the pursuit of sustainable and resilient infrastructure within the realm of civil and environmental engineering. He is particularly focused on the development and application of sustainable construction materials, aiming to reduce the environmental impact of building practices while enhancing material performance and longevity. Kim is also highly interested in structural health monitoring, exploring advanced techniques and technologies to assess the condition and integrity of infrastructure over time. This involves the use of sensors, data analytics, and predictive modeling to detect and address potential issues before they become critical. Furthermore, his research extends to the study of the durability of infrastructure, seeking to understand and mitigate factors that contribute to deterioration and failure. By integrating sustainability with advanced engineering practices, Kyeong-Ho Kim aims to contribute to the creation of safer, more efficient, and environmentally responsible infrastructure systems. His work is driven by the goal of achieving long-term benefits for society through innovative engineering solutions.

Award and Honor

Kyeong-Ho Kim has received numerous awards and honors throughout his career, underscoring his significant contributions to the field of civil and environmental engineering. His pioneering research in sustainable construction materials and structural health monitoring has earned him recognition from prestigious academic and professional organizations. He has been the recipient of several distinguished awards, including the Excellence in Research Award from his university, acknowledging his innovative work and substantial impact on the engineering community. Additionally, Kim has been honored with the Outstanding Educator Award, reflecting his dedication to teaching and mentoring students. His contributions to the field have also been recognized internationally, with awards from engineering societies and conferences that celebrate his advancements in sustainable engineering practices. These accolades highlight Kyeong-Ho Kim’s exceptional achievements and his ongoing commitment to excellence in both research and education.

Research Skills

Kyeong-Ho Kim possesses a wide array of research skills that make him a distinguished figure in the field of civil and environmental engineering. His expertise in sustainable construction materials is complemented by his adeptness in combining theoretical frameworks with practical experimentation to develop eco-friendly, high-performance solutions. Kim excels in structural health monitoring, employing advanced technologies such as sensors and data analytics to evaluate and enhance the integrity and safety of infrastructures. His meticulous approach to research involves comprehensive field studies and laboratory experiments, ensuring that his results are both reliable and applicable to real-world scenarios. Additionally, Kim’s proficiency in interdisciplinary collaboration allows him to incorporate diverse perspectives and techniques into his research, fostering innovation. His analytical prowess is evident in his robust data analysis capabilities, which underpin his numerous peer-reviewed publications and patents. Overall, Kyeong-Ho Kim’s research skills are characterized by a blend of theoretical insight, practical application, and a commitment to advancing sustainable engineering practices.

Publications

New Insight into microstructure engineering of Ni‐Rich layered oxide cathode for high performance lithium ion batteries

  • Authors: CH Jung, DH Kim, D Eum, KH Kim, J Choi, J Lee, HH Kim, K Kang, …
  • Journal: Advanced Functional Materials
  • Year: 2021
  • Citations: 131

Sn4P3–C nanospheres as high capacitive and ultra-stable anodes for sodium ion and lithium ion batteries

  • Authors: J Choi, WS Kim, KH Kim, SH Hong
  • Journal: Journal of Materials Chemistry A
  • Year: 2018
  • Citations: 97

Stable silicon anode for lithium-ion batteries through covalent bond formation with a binder via esterification

  • Authors: CH Jung, KH Kim, SH Hong
  • Journal: ACS Applied Materials & Interfaces
  • Year: 2019
  • Citations: 89

The Role of Zr Doping in Stabilizing Li[Ni0.6Co0.2Mn0.2]O2 as a Cathode Material for Lithium‐Ion Batteries

  • Authors: J Choi, SY Lee, S Yoon, KH Kim, M Kim, SH Hong
  • Journal: ChemSusChem
  • Year: 2019
  • Citations: 69

Revisiting the role of Zr doping in Ni-rich layered cathodes for lithium-ion batteries

  • Authors: CH Jung, Q Li, DH Kim, D Eum, D Ko, J Choi, J Lee, KH Kim, K Kang, …
  • Journal: Journal of Materials Chemistry A
  • Year: 2021
  • Citations: 58

Manganese Tetraphosphide (MnP4) as a High Capacity Anode for Lithium‐Ion and Sodium‐Ion Batteries

  • Authors: KH Kim, SH Hong
  • Journal: Advanced Energy Materials
  • Year: 2021
  • Citations: 41

An in situ formed graphene oxide–polyacrylic acid composite cage on silicon microparticles for lithium ion batteries via an esterification reaction

  • Authors: CH Jung, KH Kim, SH Hong
  • Journal: Journal of Materials Chemistry A
  • Year: 2019
  • Citations: 34

Beneficial vs. inhibiting passivation by the native lithium solid electrolyte interphase revealed by electrochemical Li+ exchange

  • Authors: GM Hobold, KH Kim, BM Gallant
  • Journal: Energy & Environmental Science
  • Year: 2023
  • Citations: 29

V4P7@C nanocomposite as a high performance anode material for lithium-ion batteries

  • Authors: KH Kim, CH Jung, WS Kim, SH Hong
  • Journal: Journal of Power Sources
  • Year: 2018
  • Citations: 28

A P2-type Na0.7(Ni0.6Co0.2Mn0.2)O2 cathode with excellent cyclability and rate capability for sodium ion batteries

  • Authors: J Choi, KH Kim, CH Jung, SH Hong
  • Journal: Chemical Communications
  • Year: 2019
  • Citations: 27

Superior sodium storage performance of reduced graphene oxide-supported Na3.12Fe2.44(P2O7)2/C nanocomposites

  • Authors: HJ Song, KH Kim, JC Kim, SH Hong, DW Kim
  • Journal: Chemical Communications
  • Year: 2017
  • Citations: 24

Synthesis of SrLu2O4 + red phosphors and their photoluminescence properties

  • Authors: KH Kim, EH Kang, BK Kang, KP Kim, SH Hong
  • Journal: Journal of Luminescence
  • Year: 2017
  • Citations: 23

A MnV2O6/graphene nanocomposite as an efficient electrocatalyst for the oxygen evolution reaction

  • Authors: KH Kim, YH Choi*, SH Hong*
  • Journal: Nanoscale
  • Year: 2020
  • Citations: 18

Superior electrochemical sodium storage of V4P7 nanoparticles as an anode for rechargeable sodium-ion batteries

  • Authors: KH Kim, J Choi, SH Hong
  • Journal: Chemical Communications
  • Year: 2019
  • Citations: 17

Probing the functionality of LiFSI structural derivatives as additives for Li metal anodes

  • Authors: KS Jiang, GM Hobold, R Guo, KH Kim, AM Melemed, D Wang, L Zuin, …
  • Journal: ACS Energy Letters
  • Year: 2022
  • Citations: 15