Süleyman Demir | Cell Structure Analysis | Best Researcher Award

Published on by Cell Biologist

Dr. Süleyman Demir | Cell Structure Analysis | Best Researcher Award

Dr. Süleyman Demir, Marmara Üniversitesi Mühendislik Fakültesi: Marmara Universitesi Muhendislik Fakultesi, Turkey

Dr. Süleyman Demir is a dynamic researcher and engineer with over a decade of experience in mechanical and aerospace engineering. Born in Kütahya in 1985, he has developed deep expertise in topological optimization, fatigue analysis, and additive manufacturing. His professional journey spans both academia and industry, having contributed significantly to national-scale R&D initiatives in wind energy and aerospace sectors. Currently serving as a Relations Manager at TUSAŞ (Turkish Aerospace Industries), he supports strategic innovation and industry-academia collaboration, helping students and professionals gain hands-on R&D experience. With a Ph.D. in Mechanical Engineering from Marmara University and multiple master’s degrees, Dr. Demir has authored influential publications in international conferences and journals. His interdisciplinary approach and focus on practical impact make him a strong candidate for the Best Researcher Award. A detail-oriented and forward-thinking individual, he is passionate about advancing sustainable technologies and supporting the next generation of engineers.

Publication Profile: 

Orcid

Strengths for the Award:

  1. Strong Academic Background

    • Holds a Ph.D. in Mechanical Engineering with a focus on topological optimization and fatigue testing of aerospace components.

    • Completed two master’s degrees focusing on wind turbine systems and thermal fatigue analysis.

  2. Interdisciplinary Expertise

    • Combines aerospace engineering, renewable energy, material science, and computational modeling.

    • Demonstrates versatility with experience in both aerodynamics and structural mechanics.

  3. Industry-Academia Bridging

    • Works as Relations Manager at TUSAŞ, where he facilitates collaboration between R&D labs and aviation students through programs like Lift Up.

  4. Research Contributions

    • Contributed to nationally important projects, such as the design and FEA of 500 kW wind turbines using domestic resources.

    • Authored multiple peer-reviewed publications and conference papers in both mechanical and aerospace engineering domains.

  5. Application-Focused Research

    • Research directly impacts real-world components such as helicopter tail rotor arms, advancing fatigue resistance and manufacturability.

⚠️ Areas for Improvement:

  1. Global Visibility

    • While he has presented internationally, more high-impact journal publications in globally recognized platforms (e.g., IEEE, ASME, Nature Engineering) would further strengthen his global profile.

  2. Project Leadership

    • Highlighting PI (Principal Investigator) or lead roles in major R&D grants or government-funded innovation programs would demonstrate leadership in research.

  3. Patent Portfolio

    • A stronger emphasis on patent filings or commercialized technologies would enhance the practical impact of his innovations.

🎓 Education:

Dr. Demir holds a Ph.D. in Mechanical Engineering from Marmara University (2018–2023), where he researched topology optimization and additive manufacturing of aerospace components. His dissertation focused on the helicopter tail rotor pitch arm, combining computational and experimental approaches such as fatigue testing on advanced aluminum alloys. He earned two master’s degrees in Mechanical Engineering: one from Kocaeli University (2010–2013), where he studied “Wind Turbine Hub Manufacturing and System Integration,” and another from Dumlupınar University, Kütahya, focusing on “Fatigue Strength Factor (Kf) and Thermal Variations.” His educational background reflects a strong commitment to renewable energy, structural optimization, and materials engineering. Dr. Demir’s academic record blends theoretical knowledge with industrial application, laying the foundation for his impactful contributions to aerospace and mechanical systems. His interdisciplinary training enables him to bridge gaps between R&D, manufacturing, and system-level engineering.

💼 Experience:

Dr. Süleyman Demir has cultivated a robust career across industry and academia. At TUSAŞ (Turkish Aerospace Industries) in Ankara, he works as a Relations Manager, playing a pivotal role in R&D lab development and the Lift Up program, fostering practical experience for aviation students. From June 2011 to October 2013, he served as a Researcher at Sabancı University in Istanbul, where he focused on the mechanical design and FEA (Finite Element Analysis) of 500 kW wind turbines developed with domestic resources. His career is defined by a passion for engineering innovation and collaboration. His leadership bridges academic research with industrial application, ensuring practical solutions are brought to complex engineering problems. By mentoring young researchers and promoting applied science in aerospace technologies, Dr. Demir continues to impact Turkish and global research landscapes in engineering.

🔬 Research Focus:

Dr. Demir’s research focuses on structural optimization, fatigue damage modeling, additive manufacturing, and renewable energy systems. His Ph.D. research pioneered fatigue-based topological optimization of aerospace components, including helicopter rotor arms, using advanced materials like Al 7050-7452. His work combines simulation (ANSYS, FEA) with physical testing to validate optimized designs. In earlier roles, he contributed to the design and analysis of wind turbines, slewing bearings, and composite systems—demonstrating a balance between sustainable technologies and mechanical resilience. A key strength of his research is its translational nature: from lab-scale experiments to real-world aerospace applications. He actively supports engineering education through initiatives at TUSAŞ, bridging theory and application for undergraduate researchers. His interdisciplinary contributions have been recognized through national conferences, journals, and industrial innovation. Dr. Demir continues to push the boundaries in the optimization of energy-efficient, durable, and manufacturable components for both aviation and renewable energy fields.

📚 Publications Top Notes:

  1. 📘 Modeling of Aerodynamic on Wind Turbine using Q‑Blade Software – IATS’17, Elazığ

  2. 🛠 Interaction Analysis of Slewing Bearing using Hertz Theory and ANSYS Workbench Software – IATS’17, Elazığ

  3. Direksiyon Aksonlarının Statik Hasar Analizi – APJ Eng Sci, Vol.1, No:2 (2013)

  4. 🌬 Topology Optimization of a Mid‑Size Horizontal Axis Wind Turbine Hub – CMMSE 2013, Almeria, Spain

  5. 🚁 Fatigue Damage–Based Topology Optimization of Helicopter Tail Rotor Pitch Arm – Impact Dynamics in Aerospace Materials, 2023

🧾 Conclusion:

Dr. Süleyman Demir is a highly accomplished researcher with a well-rounded background in aerospace, mechanical engineering, and renewable energy systems. His work on topological optimization and fatigue-resistant aerospace structures, particularly within the framework of additive manufacturing, reflects deep technical expertise and strong innovation potential.

Through his role at TUSAŞ and his academic endeavors, Dr. Demir has significantly contributed to Turkey’s national R&D ecosystem, particularly in aviation and renewable energy. His ability to connect theory with practice, train future engineers, and develop strategic industry-university partnerships demonstrates both vision and leadership.

qingwei lu | Cell Differentiation Processes | Innovative Research Award

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Mr. qingwei lu | Cell Differentiation Processes | Innovative Research Award

Mr. qingwei lu , Xinjiang Academy of Animal Sciences , China

Qingwei Lu is a student at the Xinjiang Academy of Animal Sciences, China, specializing in animal genetics, breeding, and reproduction. His research focuses on the genetic improvement of wool and meat sheep, specifically through quantitative genetics, population genetic analysis, and genomic selection for key traits. Qingwei also explores the molecular mechanisms behind hair follicle development in cashmere goats, applying transcriptomics and proteomics to understand hair follicle cycling and its relationship with production traits. His studies aim to provide scientific foundations for breeding and industrial development in the livestock sector. Qingwei is actively involved in national and international research collaborations and has published multiple academic papers in prominent journals. His work contributes significantly to the field of animal genetics and breeding, making him a promising researcher with a growing impact in the industry.

Publication Profile:

Orcid

Strengths for the Award:

Qingwei Lu’s work demonstrates remarkable innovation in the field of animal genetics, with a particular emphasis on sheep and cashmere goats. His integration of transcriptomics and proteomics techniques to study the genetic and molecular mechanisms of hair follicle development, especially in cashmere goats, is groundbreaking. The focus on secondary hair follicle cycling and the role of PLIN2 in regulating this cycle offers important insights for enhancing wool and meat production traits. Furthermore, his research is supported by substantial funding, such as the National Key R&D Program and the National Natural Science Foundation of China, underlining the relevance and impact of his work. His numerous published journal articles, including in high-impact journals, also reflect his contributions to advancing the scientific understanding of animal breeding and genetics.

Areas for Improvements:

While Qingwei Lu’s research is highly innovative and impactful, expanding his collaborative network further to include industry partners could enhance the translational aspect of his research. Additionally, more engagement with public-facing scientific communication and outreach could make his discoveries more accessible to a broader audience, including agricultural industries and farmers.

Education:

Qingwei Lu is currently pursuing advanced studies at the Xinjiang Academy of Animal Sciences in China. He holds a bachelor’s degree in animal science, followed by graduate studies focused on animal genetics and breeding. His academic journey is heavily centered on animal genetics, specifically in the context of wool and meat sheep, as well as the genetic improvement of cashmere goats. Qingwei’s research includes the application of quantitative genetics, genomic selection, and molecular techniques to unravel complex genetic traits in livestock. His education equips him with strong foundations in both the theoretical and practical aspects of animal breeding, enabling him to work effectively on high-impact national research projects. Qingwei’s academic achievements reflect his dedication to the scientific advancement of animal science, particularly in genetic evaluation and breeding program optimization.

Experience:

Qingwei Lu’s research experience spans multiple projects in the field of animal genetics and breeding. His primary research focuses on the genetic enhancement of sheep and goats, particularly wool and meat sheep, and cashmere goats, through innovative approaches in genomics and molecular biology. Qingwei’s work includes estimating genetic parameters, analyzing population genetic structures, and implementing genomic selection to improve economic traits in livestock. He is currently involved in key national research programs in China, including the National Key R&D Program (2021YFD1200902) and the National Natural Science Foundation of China Regional Science Fund (32360814). His collaborative research efforts have resulted in numerous journal publications. Qingwei also collaborates on industry-sponsored projects, contributing his expertise to practical breeding solutions for livestock farmers. His expertise in combining transcriptomics, proteomics, and genomic techniques is making a significant impact on livestock breeding and industrial development.

Research Focus:

Qingwei Lu’s research focus revolves around the genetic improvement of livestock, with particular emphasis on wool and meat sheep, and cashmere goats. His research involves the use of quantitative genetics to estimate genetic parameters, analyze population genetic structures, and implement genomic selection for important economic traits such as early growth and reproductive traits. Additionally, Qingwei studies the genetic and molecular mechanisms of hair follicle development in cashmere goats, aiming to uncover the regulatory pathways behind hair follicle cycling. His work integrates transcriptomics, proteomics, and genomic sequencing techniques to explore how these molecular processes influence the production of wool and cashmere. By understanding these molecular mechanisms, Qingwei seeks to develop breeding strategies that can enhance productivity and economic outcomes in the livestock industry. His work provides valuable insights for improving livestock breeding programs and contributes to the scientific foundation for the development of more sustainable and profitable animal farming.

Publications Top Notes:

  1. Screening of CircRNA Related to Secondary Hair Follicle Cycling in Southern Xinjiang Cashmere Goats
    🐐📚 Chinese Journal of Animal Husbandry and Veterinary Medicine, 2024 | DOI: 10.19556/j.0258-7033.20230117-04

  2. Effects of Non-genetic Factors on Early Growth Traits in Southern Xinjiang Cashmere Goats
    🐐📖 Chinese Journal of Animal Science, 2024 | DOI: 10.16431/j.cnki.1671-7236.2024.05.001

  3. Research on the Cyclical Patterns of Different Types of Hair Follicles in Southern Xinjiang Cashmere Goats
    🐐🔬 Chinese Journal of Animal Science, 2025 | DOI: 10.19556/j.0258-7033.20240422-10

  4. Comparison of Different Animal Models for Estimating Genetic Parameters for Early Growth Traits and Reproductive Traits in Tianmu Sainuo Sheep
    🐑📄 Frontiers in Veterinary Science, 2024 | DOI: 10.3389/fvets.2024

  5. Proteomics Reveals the Role of PLIN2 in Regulating the Secondary Hair Follicle Cycle in Cashmere Goats
    🧬🐐 International Journal of Molecular Sciences, 2025 | DOI: 10.3390/ijms26062710

Conclusion:

Qingwei Lu’s innovative approach to genetic improvement in sheep and goats, particularly his exploration of hair follicle regulation mechanisms and their relation to production traits, makes him an excellent candidate for the Innovative Research Award. His contributions to advancing genetic evaluation and breeding programs have the potential to greatly impact agricultural industries, aligning well with the goals of the award.

Hadji Djebar | Microbial Cell Biology | Best Paper Award

Published on by Cell Biologist

Prof. Hadji Djebar | Microbial Cell Biology | Best Paper Award

Prof. Hadji Djebar , saida university ,  Algeria

Dr. Djebar Hadji is a professor at Saida University, Algeria, specializing in nonlinear optical (NLO) properties, structural analysis, and theoretical quantum chemistry methods. With a deep passion for material science, his research focuses on the relationship between molecular structure and its photonic and NLO properties. Dr. Hadji has published numerous articles in top-tier scientific journals and is a recognized expert in computational chemistry, particularly within the field of nonlinear optics. His contributions extend to being an editor for BMC Chemistry, Springer, and a referee for several journals in his field. He has demonstrated significant expertise in the theoretical investigation of novel materials, combining both experimental and theoretical approaches. Dr. Hadji is continuously working on advancing the understanding of nonlinear optical properties in various molecular compounds and materials.

Publication Profile: 

Orcid

Strengths for the Award:

Dr. Djebar Hadji’s work is well-regarded in the field of Nonlinear Optical (NLO) properties, with a focus on theoretical quantum chemistry and structure-property relationships. His substantial body of work published in high-impact journals like Journal of Molecular Liquids, Journal of Electronic Materials, and Revue Roumaine de Chimie highlights his expertise in the synthesis, characterization, and theoretical study of NLO materials. Dr. Hadji’s research makes a notable contribution to understanding the photonic behavior and NLO properties of various chemical compounds, from organic to inorganic hybrids. His work on N-acyl glycine derivatives and thiosemicarbazides stands out for their novel approaches and interdisciplinary nature. Theoretical methodologies, alongside experimental validations, provide a well-rounded understanding of the materials under study. Furthermore, his continuous engagement as a reviewer and editor adds to his credibility in the scientific community.

Areas for Improvement:

While Dr. Hadji’s research has covered a broad spectrum of NLO materials, there appears to be room to increase the scope of applications and practical validations of these materials in real-world scenarios. A more applied focus, such as exploring their use in specific devices or industry-related innovations, could be beneficial for the impact and commercial potential of his work. Additionally, expanding collaborative efforts with experimentalists in material fabrication could lead to more direct applications and enhance the relevance of the research.

Education:

Dr. Djebar Hadji completed his academic journey with distinction in the field of chemistry. He earned his Ph.D. in Chemistry from a renowned Algerian institution, focusing on nonlinear optical properties and theoretical quantum chemistry methods. His academic endeavors have led him to explore various facets of computational chemistry, and he has continued to deepen his knowledge and expertise throughout his career. Dr. Hadji’s education has provided him with a robust foundation in both theoretical and experimental aspects of chemistry, which has fueled his research on understanding the complex relationships between molecular structures and their properties. His postgraduate education was complemented by ongoing professional development, where he has continuously engaged with the global scientific community through collaborations, conferences, and publications. This educational background, combined with years of teaching and research experience, has made Dr. Hadji a respected figure in his field.

Experience:

Dr. Djebar Hadji has extensive experience in academia and research. As a professor at Saida University, Dr. Hadji has mentored numerous students, guiding them through the complexities of chemistry and computational modeling. His teaching covers a wide range of topics, including theoretical quantum chemistry and nonlinear optics. Dr. Hadji is actively involved in collaborative research, having contributed to groundbreaking studies published in reputable journals such as Journal of Molecular Liquids, Journal of Electronic Materials, and Physical Chemistry Research. His research spans the theoretical and computational investigation of nonlinear optical properties, focusing on the structure-property relationships in various chemical compounds. Dr. Hadji also holds editorial roles in prominent journals and reviews papers for several renowned scientific publications. His multifaceted experience, including both theoretical and experimental work, positions him as a highly knowledgeable and influential figure in the field of chemistry, particularly in nonlinear optics and material science.

Research Focus:

Dr. Djebar Hadji’s research primarily focuses on nonlinear optical (NLO) properties, the interaction between molecular structures and photonic characteristics, and the application of theoretical quantum chemistry methods. His work investigates how molecular arrangements and electronic properties influence NLO responses, which has vast applications in areas like telecommunications, photonics, and material science. Dr. Hadji’s research explores novel molecular compounds, particularly those with potential for high-performance NLO behavior. He utilizes quantum chemical methods such as DFT (Density Functional Theory) and TD-DFT (Time-Dependent DFT) to predict and analyze molecular properties. Additionally, Dr. Hadji is dedicated to the synthesis and characterization of new materials, including hybrid inorganic-organic systems and azo derivatives. His goal is to design materials with enhanced NLO properties for various technological applications, focusing on optimizing the relationship between structure and function. This research contributes significantly to the development of advanced materials with improved nonlinear optical responses.

Publications Top Notes:

  1. Nonlinear optical and antimicrobial activity of N-acyl glycine derivatives, Journal of Molecular Liquids, 2024 📖🧬
  2. Deeper Insights on the Nonlinear Optical Properties of O-acylated Pyrazoles, Journal of Electronic Materials, 2024 🔬💡
  3. Synthesis And Characterization Of Novel Thiosemicarbazide For Nonlinear Optical Applications: Combined Experimental And Theoretical Study, Revue Roumaine de Chimie, 2024 🔬⚗️
  4. NLO azo compounds with sulfonamide groups: A theoretical investigation, Journal of Indian Chem. Soc., 2023 🧪✨
  5. Synthesis and characterization of novel thiosemicarbazide for nonlinear optical applications, Rev. Roum. Chim., 2023 ⚗️🔍
  6. Efficient NLO Materials Based on Poly(ortho-anisidine) and Polyaniline: A Quantum Chemical Study, Journal of Electronic Materials, 2022 🧬💡
  7. Molecular Structure, Linear, and Nonlinear Optical Properties of Piperazine-1,4-Diium Bis 2,4,6-Trinitrophenolate, Physical Chemistry Research, 2022 ⚗️📚
  8. Theoretical insights into the nonlinear optical properties of cyclotriphosphazene, Journal of Materials Science, 2022 📊🔬
  9. Linear and nonlinear optical properties of anhydride derivatives: A theoretical investigation, December 2021 🧪💡
  10. Synthesis, spectroscopic characterization, crystal structure, and linear/NLO properties of a new hybrid compound, Journal of Molecular Structure, 2021 🧪🔍

Conclusion:

Dr. Djebar Hadji’s extensive contribution to the understanding of nonlinear optical properties of various compounds places him as a strong candidate for the Research for Best Paper Award. His solid foundation in both experimental and theoretical aspects of material science and quantum chemistry, as well as his consistent publication record, are commendable. While his work is theoretically rich, adding practical application studies could further enhance his impact and lead to real-world implementation of his discoveries in the field of optics and photonics.