Tarek Naadia | Materials Science | Sustainable Engineering Leadership Award

Dr. Tarek Naadia | Materials Science | Sustainable Engineering Leadership Award

Lecturer researcher from Polytechnic School of Architecture and Urban Planning EPAU, Algeria

Dr. NAADIA Tarek is an accomplished Associate Professor in Civil Engineering with a specialization in the mechanics and rheology of self-compacting concrete. Holding a University Habilitation awarded in 2021 from USTHB, she is a respected teacher-researcher affiliated with the Polytechnic School of Architecture and Urbanism (EPAU) and a key member of the Civil Engineering Laboratory (LBE). Her work focuses on advancing sustainable construction materials, particularly optimizing the performance and flow properties of steel fiber reinforced self-compacting concrete using innovative experimental design techniques. Dr. Tarek’s research outputs have been published in high-impact journals, emphasizing both the mechanical and rheological characteristics of eco-friendly concrete formulations incorporating industrial by-products such as tuff and marble powders. She combines rigorous scientific methodology with practical applications that support the development of greener, more durable building materials. Throughout her academic career, Dr. Tarek has demonstrated a commitment to excellence in research, teaching, and collaborative innovation within the civil engineering community. Her expertise aligns well with global efforts to promote sustainability in infrastructure development and materials science. Dr. Tarek’s contributions position her as a valuable leader in sustainable engineering research, with a growing impact on both regional and international levels.

Professional Profile

Education

Dr. NAADIA Tarek completed her highest academic qualification with a University Habilitation in Civil Engineering, awarded on January 21, 2021, at the University of Science and Technology Houari Boumediene (USTHB). This qualification represents a significant academic milestone, signifying her capability to conduct independent research, supervise doctoral students, and contribute original knowledge to her field. Her educational journey has been deeply rooted in civil engineering, with a particular focus on materials science and mechanics. Although specific earlier degrees are not listed, the habilitation level indicates advanced expertise beyond the doctoral level, underscoring her extensive research experience and academic maturity. The habilitation also reflects a comprehensive understanding of both theoretical foundations and applied techniques related to concrete rheology, material optimization, and sustainable construction technology. Her educational background equips her with the tools necessary to drive innovation in civil engineering and to influence the development of sustainable materials that address modern construction challenges. The advanced training and scholarship involved in attaining the habilitation have prepared her for a leading role in academia and research, enabling her to contribute effectively to the scientific community and to mentor future engineers.

Professional Experience

Dr. NAADIA Tarek currently serves as an Associate Professor (Class A) and a Teacher-Researcher at the Polytechnic School of Architecture and Urbanism (EPAU). She is also an active member of the Civil Engineering Laboratory (LBE) at USTHB, where she engages in research on the mechanics of materials, focusing particularly on self-compacting concrete. Her professional role involves a blend of teaching, laboratory research, and project management. As a lecturer, she contributes to civil engineering curricula, imparting knowledge on construction materials, experimental techniques, and sustainability concepts. Within the laboratory, she conducts experimental research that integrates mechanical testing and rheological measurement methods to optimize concrete formulations. Dr. Tarek’s work includes the development of new procedures for measuring concrete flow behavior and the application of design of experiments (DOE) methodologies to fine-tune mix designs for performance and environmental benefits. Her position requires collaboration with fellow researchers, students, and industry stakeholders to ensure practical relevance and innovation. Over time, she has established herself as a key figure in her department, contributing to research projects and academic advancements that enhance sustainable engineering practices in Algeria and beyond.

Research Interests

Dr. NAADIA Tarek’s primary research interests lie at the intersection of civil engineering materials, rheology, and sustainability. She specializes in the study and optimization of self-compacting concrete (SCC), focusing on both its rheological (flow) properties and mechanical performance. Her work emphasizes the development of sustainable concrete formulations that incorporate industrial by-products such as marble and tuff powders, which serve as partial replacements for traditional cement or aggregates. This approach not only improves the environmental footprint of concrete but also enhances its durability and functionality. A significant aspect of her research involves applying the design of experiments (DOE) methodology to systematically optimize the composition and performance of steel fiber reinforced self-compacting concrete (SFRSCC). This method allows for efficient exploration of multiple variables and their interactions, facilitating robust improvements in concrete quality. Dr. Tarek also investigates the rheological behavior of concrete mixtures, developing new measurement procedures to better understand their flow characteristics under various conditions. Her research contributes to sustainable construction practices by promoting materials that reduce resource consumption, waste, and energy use while improving structural integrity and longevity.

Research Skills

Dr. NAADIA Tarek possesses a comprehensive skill set tailored to experimental civil engineering research, particularly in concrete materials science. She is proficient in rheological testing methods for assessing the flow behavior of self-compacting concrete, including the design and implementation of novel measurement procedures. Her expertise extends to mechanical characterization techniques for fiber-reinforced composites, enabling detailed analysis of strength, durability, and deformation properties. She employs advanced statistical tools, notably the design of experiments (DOE) approach, to optimize material formulations systematically, which enhances research efficiency and reliability. This methodological rigor allows her to manage complex variables and interactions within concrete mix designs, leading to reproducible and scalable results. Additionally, Dr. Tarek is skilled in interpreting data to improve concrete sustainability by integrating alternative materials such as marble and tuff powders. Her laboratory experience is complemented by academic teaching, where she applies her research skills to train future engineers in experimental and analytical techniques. Collectively, these competencies support her ability to innovate within sustainable engineering and to drive research that meets both academic standards and practical industry needs.

Awards and Honors

While the CV provided does not specify particular awards or honors received by Dr. NAADIA Tarek, her attainment of the University Habilitation itself represents a prestigious academic recognition. The habilitation is a significant scholarly achievement that acknowledges her capability for independent research and academic leadership. This advanced qualification is often regarded as a benchmark of excellence within many academic systems, highlighting her contributions to civil engineering research and education. Furthermore, Dr. Tarek’s publications in high-impact journals reflect peer recognition of the quality and relevance of her work. Her growing portfolio of research articles and her position as an Associate Professor at a leading institution further attest to her professional esteem and influence within her field. For future career development, formal awards for sustainable engineering or leadership in research could complement her credentials and enhance her profile internationally. Participation in academic societies, editorial boards, or conference leadership roles may also lead to additional honors, reinforcing her position as a research leader.

Conclusion

Dr. NAADIA Tarek is a promising and dedicated civil engineering researcher with a clear focus on sustainable construction materials. Her expertise in the rheology and optimization of self-compacting concrete, combined with her use of innovative experimental design methods, positions her at the forefront of sustainable materials research. Her academic qualifications, including a University Habilitation, and her role as an Associate Professor underscore her capability for independent research and leadership within academia. Although further international collaboration and formal recognition through awards could strengthen her profile, her existing contributions demonstrate significant potential for advancing sustainable engineering practices. Dr. Tarek’s work is particularly relevant to the global imperative of reducing environmental impacts in construction, supporting the development of eco-friendly materials that are both durable and efficient. With continued research productivity and expanded engagement with the international engineering community, she is well positioned to become a leading figure in sustainable engineering research and innovation.

Publications Top Notes

  • Rheological and mechanical optimization of a steel fiber reinforced self-compacting concrete using the design of experiments method
    Authors: D Gueciouer, G Youcef, N Tarek
    Journal: European Journal of Environmental and Civil Engineering, Volume 26, Issue 3, Pages 1097-1117
    Year: 2022
    Citations: 28

  • Development of a measuring procedure of rheological behavior for self compacting concrete
    Authors: T Naadia, Y Ghernouti, D Gueciouer
    Journal: Journal of Advanced Concrete Technology, Volume 18, Issue 6, Pages 328-338
    Year: 2020
    Citations: 4

  • Rheology-compactness-granularity correlations of self-compacting concretes
    Author: T Naadia
    Year: 2014
    Citations: 1

  • Optimization of Steel Fiber-Reinforced Self-Compacting Concrete with Tuff Powder
    Authors: T Naadia, D Gueciouer
    Journal: Construction and Building Materials, Volume 474, Article 140759
    Year: 2025

  • Formulation and characterization of steel fiber reinforced self-compacting concrete (SFRSCC) based on marble powder
    Authors: T Naadia, D Gueciouer, Y Ghernouti
    Journal: Selected Scientific Paper – Journal of Civil Engineering
    Year: 2025

  • Effect of the aggregates size on the rheological behaviour of the self compacting concrete
    Authors: T Naadia, F Kharchi
    Journal: International Review of Civil Engineering (IRECE), Volume 4, Issue 2, Pages 92-97
    Year: 2013


Haopeng Zhang | Materials Science | Best Researcher Award

Mr. Haopeng Zhang | Materials Science | Best Researcher Award

Doctor at Harbin University of Science and Technology, China

Haopeng Zhang is an emerging researcher with a strong academic foundation, having completed both his bachelor’s and master’s degrees at Harbin University of Science and Technology. Currently pursuing his Ph.D. at the same institution, Zhang’s research focuses on supercapacitors and biosensors, areas with significant implications for energy storage and biosensing technologies. His dedication to these advanced fields reflects his commitment to innovative research. Zhang’s continuous academic journey and early start in his doctoral studies demonstrate a promising trajectory in his research career. However, to further strengthen his candidacy for awards, he should aim to increase his research output, gain broader recognition through publications and professional engagements, and explore interdisciplinary approaches to enhance the impact of his work. With continued focus and strategic development, Zhang has the potential to make notable contributions to his field.

Profile

Education

Haopeng Zhang’s educational journey reflects a strong foundation in his chosen field. He completed his bachelor’s degree in July 2019 and his master’s degree in April 2022, both from Harbin University of Science and Technology in Heilongjiang province, China. His academic focus during these years was centered on advanced technologies, including supercapacitors and biosensors. In September 2022, Zhang continued his academic pursuits by enrolling as a doctoral candidate at the same institution. His decision to advance his studies at Harbin University of Science and Technology underscores his commitment to building upon his prior knowledge and research experience. Through his education, Zhang has developed a robust understanding of his research areas and is poised to contribute meaningfully to advancements in energy storage and biosensing technologies. His educational path highlights his dedication and preparation for future research endeavors.

 Professional Experience

Haopeng Zhang’s professional experience reflects a solid foundation in research and academia. After completing his bachelor’s and master’s degrees at Harbin University of Science and Technology in July 2019 and April 2022, respectively, he began his doctoral studies at the same institution in September 2022. His academic journey has been focused on advancing knowledge in the fields of supercapacitors and biosensors, areas crucial for energy storage and biosensing applications. During his master’s studies, Zhang was involved in various research projects that laid the groundwork for his current doctoral research. His role as a doctoral candidate involves conducting in-depth research, developing innovative solutions, and contributing to academic publications. Zhang’s involvement in these cutting-edge fields demonstrates his commitment to contributing significantly to technological advancements and reflects his dedication to addressing key challenges in energy and sensing technologies.

Research Skills

Haopeng Zhang possesses a strong set of research skills that underpin his work in supercapacitors and biosensors. His expertise in experimental design and material synthesis is evident from his academic training at Harbin University of Science and Technology, where he has developed and optimized advanced materials for energy storage and sensing applications. Zhang demonstrates proficiency in various analytical techniques, including electrochemical testing and sensor calibration, essential for evaluating the performance of supercapacitors and biosensors. His ability to conduct rigorous data analysis and interpret complex results highlights his analytical capabilities. Zhang’s skills also extend to literature review and hypothesis formulation, allowing him to frame his research within the broader context of current scientific advancements. As a doctoral candidate, he is continually honing his skills in research methodology and problem-solving, positioning him well for future contributions to his field.

Award and Recognition

Haopeng Zhang, a doctoral candidate at Harbin University of Science and Technology, has demonstrated notable potential in the fields of supercapacitors and biosensors. Although still early in his research career, Zhang has shown a strong commitment to advancing these critical technologies. His focused research and academic trajectory—from his bachelor’s and master’s degrees to his current doctoral studies—underscore his dedication and potential for impactful contributions. As he progresses in his academic career, Zhang is expected to enhance his research output, gain broader recognition through publications and collaborations, and potentially diversify his research scope. While specific awards and recognitions are yet to be listed, Zhang’s ongoing work holds promise for future accolades as he continues to develop his expertise and contribute to his field. His progress and achievements will be closely watched as he moves forward in his research journey.

Conclusion

Haopeng Zhang shows promise as a researcher with a focused interest in significant technological areas like supercapacitors and biosensors. His dedication to his studies and early start in research are commendable. To be considered for the Research for Best Researcher Award, he should focus on increasing his research output, gaining broader recognition, and potentially diversifying his research scope. If he continues on his current trajectory and addresses these areas for improvement, he could become a strong candidate for prestigious research awards in the future.

Publications Top Notes

  1. Hierarchical core-shelled CoMo layered double hydroxide@CuCo₂S₄ nanowire arrays/nickel foam for advanced hybrid supercapacitors
    • Authors: Jiang, F., Xie, Y., Zhang, H., Yao, F., Yue, H.
    • Journal: Journal of Colloid and Interface Science
    • Year: 2025
  2. Construction of ultra-thin NiMo₃S₄ nanosheet sphere electrode for high-performance hybrid supercapacitor
    • Authors: Zhang, H., Xie, Y., Jiang, F., Bai, H., Yue, H.
    • Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects
    • Year: 2024
  3. Tapered cross-linked ZnO nanowire bundle arrays on three-dimensional graphene foam for highly sensitive electrochemical detection of levodopa
    • Authors: Huang, S., Zhang, H., Gao, X., Bai, H., Yue, H.
    • Journal: Microchimica Acta
    • Year: 2024
  4. Nanoassembly of l-Threonine on Helical Carbon Tubes for Electrochemical Chiral Detection of l-Cysteine
    • Authors: Su, H., Huang, S., Gao, X., Zhao, L., Yue, H.
    • Journal: ACS Applied Nano Materials
    • Year: 2024
  5. Vertically aligned graphene-MXene nanosheets based electrodes for high electrochemical performance asymmetric supercapacitor
    • Authors: Yu, Y., Zhang, H., Xie, Y., Yao, F., Yue, H.
    • Journal: Chemical Engineering Journal
    • Year: 2024
    • Citations: 5
  6. In-situ Ni-doped V-MOF ultra-thin nanosheet arrays on Ni foam for high-performance hybrid supercapacitors
    • Authors: Xie, Y., Zhang, H., Zhang, K., Yao, F., Yue, H.
    • Journal: Electrochimica Acta
    • Year: 2024
    • Citations: 3
  7. Hybrid of dandelion-like hollow Mo₂C nanospheres-graphene nanosheets as the electrode for highly sensitive electrochemical detection of dopamine
    • Authors: Huang, S., Li, Q., Zhang, H., Su, H., Yue, H.
    • Journal: Microchemical Journal
    • Year: 2024
  8. Polyaniline nanowire arrays on biomass-derived carbon nanotubes with typha longbracteata for high-performance symmetric supercapacitors
    • Authors: Yang, S., Wang, Z., Xie, Y., Zhang, H., Yue, H.
    • Journal: Diamond and Related Materials
    • Year: 2024
    • Citations: 1
  9. NiCo₂S₄ nanocone arrays on three-dimensional graphene with small hole diameters for asymmetric supercapacitor
    • Authors: Zhang, H., Xie, Y., Yang, S., Yao, F., Yue, H.
    • Journal: Journal of Alloys and Compounds
    • Year: 2023
    • Citations: 4
  10. Self-assembly of gold nanoparticles on three-dimensional eggshell biological carbon fiber membranes: Non-enzymatic detection of rutin
    • Authors: Zhang, H., Huang, S., Gao, X., Yang, S., Yue, H.
    • Journal: Sensors and Actuators B: Chemical
    • Year: 2023
    • Citations: 6