Ms. Gülay Özkan | Chemical Engineering | Best Researcher Award

Ms. Gülay Özkan | Chemical Engineering | Best Researcher Award 

Prof. Dr. Gülay Özkan , Ankara university , Turkey

Prof. Dr. Gülay Özkan is an esteemed scholar and educator at Ankara University, specializing in Chemical Engineering. With a robust academic foundation built at Ankara University, she earned her Bachelor’s (1989), Master’s (1993), and Doctorate (1997) in Chemical Engineering. Prof. Dr. Gülay Özkan has dedicated her career to advancing hydrogen production technologies, with a focus on chemical storage materials, contributing significantly to the hydrogen economy’s integration in transportation, power generation, and industrial applications. She has authored over 40 peer-reviewed articles in SCI-indexed journals, three books, and contributed to various high-impact research collaborations, including those with TÜBİTAK. A visionary researcher and educator, she has successfully completed ten major research projects and is a trailblazer in her field. Her professional pursuits reflect her commitment to sustainable energy solutions, fostering innovation, and contributing to the global scientific community.

Professional Profile:

Orcid 

Scopus

Summary of Suitability for Award:

Prof. Dr. Gülay Özkan is highly deserving of the “Best Researcher Award” based on her exceptional contributions to the field of Chemical Engineering, particularly in the area of sustainable energy and hydrogen production. Her academic journey is marked by advanced education and impactful research that addresses global energy challenges. She has completed 10 research projects and published 40 articles in prestigious indexed journals, demonstrating her dedication to advancing scientific knowledge. Her three books and collaborations with TÜBİTAK and the Ministry of Science and Industry showcase her ability to bridge academia and industry effectively.

🎓Education:

Prof. Dr. Gülay Özkan has a robust academic foundation in Chemical Engineering, developed entirely at Ankara University. She advanced through undergraduate, postgraduate, and doctoral studies in the field, gaining deep expertise in process optimization and dynamic simulation techniques. Her educational journey focused on practical applications of engineering principles, culminating in significant research contributions such as the adaptive generalized predictive control of reactor temperature profiles and object-oriented programming for dynamic simulations. This solid academic background has been instrumental in shaping her innovative approaches to chemical engineering challenges. Her rigorous training and specialized focus have equipped her with the analytical skills and technical knowledge required for groundbreaking work in hydrogen production and sustainable energy solutions. Prof. Dr. Gülay Özkan’s education reflects a seamless integration of theoretical knowledge and practical application, laying a strong foundation for her distinguished career as a researcher and educator.

🏢Work Experience:

Prof. Dr. Gülay Özkan has over 30 years of academic and research experience at Ankara University. Her career is marked by a steadfast commitment to education and innovation in Chemical Engineering. She has supervised multiple research projects, securing impactful collaborations with industry stakeholders, TÜBİTAK, and the Turkish Ministry of Science and Industry. Prof. Dr. Gülay Özkan has successfully completed ten major research projects and has been involved in consultancy for industry-sponsored initiatives. Her editorial roles and participation in collaborative research underscore her influence in the global academic community. A prolific scholar, she has authored 40 articles in indexed journals, three books, and contributed to advancing hydrogen production technologies. Beyond research, Prof. Dr. Gülay Özkan has been instrumental in curriculum development, mentoring the next generation of engineers, and fostering a culture of interdisciplinary collaboration within her department.

🏅Awards: 

Prof. Dr. Gülay Özkan’s dedication to academic excellence has earned her numerous accolades, underscoring her contributions to Chemical Engineering and sustainable energy research. Her innovative work in hydrogen production has been recognized by TÜBİTAK and other prestigious organizations in Turkey. She has been honored for her exceptional teaching and research achievements at Ankara University, where she continues to inspire students and peers alike. While specific award details are not listed in her profile, her extensive publication record, research collaborations, and completed projects highlight her as a leader in her field. Prof. Dr. Gülay Özkan’s role in advancing chemical engineering education and her contributions to sustainable energy solutions make her a deserving nominee for any award celebrating innovation and academic excellence.

🔬Research Focus:

Prof. Dr. Gülay Özkan’s research is centered on hydrogen production from chemical storage materials, contributing to the development of a sustainable hydrogen economy. Her work aims to integrate hydrogen as a primary energy carrier in critical sectors such as transportation, power generation, and industrial applications. By leveraging advanced chemical engineering techniques, she explores the synthesis, optimization, and control of processes for efficient hydrogen generation. Her expertise extends to adaptive generalized predictive control systems, which she has applied to optimize temperature profiles in chemical reactors. With a strong focus on interdisciplinary collaboration, Prof. Dr. Gülay Özkan’s research aligns with global efforts to combat climate change and transition towards renewable energy sources. Her projects and publications reflect her commitment to addressing energy challenges and fostering innovation in clean energy technologies.

Publication Top Notes:

1. Development of Boron-Containing Electrolyte Additive for Lithium-Ion Batteries
  • Citations: 0
2. Green Synthesis of TiO2 Nanoparticles Using Aloe Vera Extract as Catalyst Support Material and Studies of Their Catalytic Activity in Dehydrogenation of Ethylenediamine Bisborane
  • Citations: 8
3. Innovation in the Synthesis of Hydrazine Borane by Mechanochemical Method and Hydrolysis of Hydrazine Borane with Pd/TiO2 Catalyst
  • Citations: 7
4. Catalytic Dehydrogenation of Ethylenediamine Bisborane in Ethylenediamine Media
  • Citations: 4
5. Hydrogen Generation from the Hydrolysis of Ethylenediamine Bisborane Using Ni/NixBy-Zr and Pd-Ni/ NixBy-Zr as Highly Active Catalysts
  • Citations: 6

 

 

 

Tayebe Bagheri Lotfabad | Chemical Engineering | Best Researcher Award

Dr. Tayebe Bagheri Lotfabad | Chemical Engineering | Best Researcher Award

Doctorate at National Institute for Genetic Engineering and Biotechnology, Iran

Dr. Tayebe Bagheri Lotfabad is a prominent figure in the field of Chemical Engineering with a specialization in Biotechnology. Her work primarily addresses environmental challenges through innovative biotechnological solutions, focusing on microbial processes and biosurfactant production. With a strong academic background and extensive research experience, Dr. Lotfabad has significantly contributed to advancing sustainable practices in wastewater treatment and pollution remediation, making her a respected leader in her field.

Author Metrics

Scopus Profile

ORCID Profile

Dr. Lotfabad has established a significant presence in the scientific community, as evidenced by her author metrics. She has published numerous articles in reputable, peer-reviewed journals, achieving a notable h-index that reflects her impactful research contributions. Her work has garnered substantial citations, underscoring her influence and the relevance of her studies in environmental biotechnology and chemical engineering.

  • Total Citations: 991 citations across 864 documents, indicating a significant impact in her field.
  • Documents Published: 26 documents, showcasing a consistent output of research work.
  • h-index: 14, reflecting both the productivity and citation impact of her published work.

Education

Dr. Lotfabad holds a Ph.D. in Chemical Engineering – Biotechnology from Sharif University of Technology, completed in 2009. Prior to her doctoral studies, she earned her M.Sc. in Chemical Engineering – Biotechnology in 2001 from the same institution and her B.Sc. in Chemical Engineering – Petroleum Refining from Tehran University in 1996. This rigorous educational foundation has equipped her with the necessary skills and knowledge to tackle complex challenges in her research.

Research Focus

Dr. Lotfabad’s research focus encompasses several critical areas within environmental biotechnology, including the microbial degradation of environmental pollutants, the production of biosurfactants, and the development of efficient wastewater treatment processes. Her work aims to innovate sustainable solutions that utilize microbial systems to address pressing ecological issues, particularly in the realm of pollution control and resource recovery.

Professional Journey

Since earning her Ph.D., Dr. Lotfabad has embarked on a dynamic professional journey marked by significant contributions to academia and research. She has held various positions at the National Institute of Genetic Engineering and Biotechnology, where she has led numerous projects and collaborated with diverse teams. Her dual role as an educator and researcher has allowed her to mentor students while advancing scientific knowledge in her areas of expertise.

Honors & Awards

Throughout her career, Dr. Lotfabad has received several prestigious awards recognizing her outstanding contributions to the field of environmental biotechnology. These honors reflect her innovative research and the societal impact of her work, particularly in developing methods for effective pollution management and sustainable resource utilization.

Publications Noted & Contributions

Dr. Lotfabad has an extensive publication record, featuring influential research articles in high-impact journals. Her notable contributions include studies on the microbial degradation of azo dyes and the production of biosurfactants from renewable resources. These publications not only advance academic knowledge but also provide practical solutions for environmental remediation, underscoring her commitment to impactful research.

1. Determining Kinetics Parameters of Bovine Serum Albumin-Protected Gold Nanozymes Toward Different Substrates

Published: July 3, 2023 | DOI: 10.32388/7VCB35

This study investigates the kinetics of gold nanozymes stabilized by bovine serum albumin (BSA) when interacting with various substrates. The research employs kinetic modeling to assess how these nanozymes catalyze reactions, contributing to the understanding of their potential applications in biocatalysis and biosensing. The findings demonstrate that BSA effectively enhances the stability and activity of the gold nanozymes, paving the way for their utilization in biomedical and environmental applications.

2. Study on the Use of Bovine Blood Protein Hydrolysate as a Peptone in Microbial Culture Media

Published: July 3, 2023 | DOI: 10.1080/10826068.2022.2119577

This article explores the feasibility of using bovine blood protein hydrolysate as a peptone alternative in microbial culture media. The authors, including Lotfabad, present experimental results showing that the hydrolysate supports the growth of various microorganisms, thus offering a cost-effective and sustainable option for microbial cultivation. This work highlights the potential of utilizing animal by-products in biotechnological applications, promoting resource efficiency.

3. Biological Activated Carbon Process for Biotransformation of Azo Dye Carmoisine by Klebsiella spp.

Published: August 11, 2022 | DOI: 10.1080/09593330.2021.1897167

In this research, the authors investigate the use of biological activated carbon as a medium for the biotransformation of the azo dye Carmoisine by Klebsiella species. The study demonstrates the efficacy of this method in degrading azo dyes, which are known for their environmental toxicity. The results indicate that the biological activated carbon significantly enhances the removal rates of the dye, providing insights into effective wastewater treatment strategies.

4. Biodecolourization of Azo Dye Under Extreme Environmental Conditions via Klebsiella quasipneumoniae GT7: Mechanism and Efficiency

Published: June 20, 2022 | DOI: 10.18502/jehsd.v7i2.9789

This study focuses on the strain Klebsiella quasipneumoniae GT7 and its ability to degrade azo dyes under harsh environmental conditions. The research elucidates the mechanisms behind the biodecolorization process and assesses the efficiency of this strain in real-world scenarios. The findings provide valuable information for developing robust bioremediation techniques for dye-contaminated environments.

5. Azo Dye Removal via Surfactant-Assisted Polyvinylidene Fluoride Membrane

Published: February 15, 2021 | DOI: 10.34172/EHEM.2021.04

In this article, the authors examine the use of surfactant-assisted polyvinylidene fluoride (PVDF) membranes for the removal of azo dyes from aqueous solutions. The study highlights the advantages of using surfactants to enhance membrane filtration performance, resulting in improved dye removal efficiency. This research has significant implications for developing advanced membrane technologies for wastewater treatment.

Research Timeline

Dr. Lotfabad’s research timeline illustrates a consistent trajectory of inquiry and innovation in environmental biotechnology. From her early studies during her Ph.D. to her ongoing projects focused on wastewater treatment and biosurfactant production, she has continuously explored the intersection of chemical engineering and microbiology, making significant strides in her research endeavors.

Conclusion

Dr. Tayebe Bagheri Lotfabad’s significant contributions to chemical engineering and biotechnology underscore her role as a leading researcher in environmental sustainability. Her innovative solutions to pollution and wastewater treatment not only advance academic knowledge but also offer practical approaches to pressing environmental challenges. While she has achieved notable recognition and impact in her field, there are opportunities for further growth through interdisciplinary collaboration, public engagement, and the exploration of diverse research avenues. Embracing these opportunities will not only enhance her own research trajectory but also contribute to broader societal benefits.