Dr. Saqib Murtaza | Nanofluid Award | Best Researcher Award

Dr. Saqib Murtaza | Nanofluid Award | Best Researcher Award

Dr. Saqib Murtaza, King Mongkut’s University of Technology Thonburi, Thailand

Dr. Saqib Murtaza, is a mathematician specializing in fluid dynamics, heat transfer, and nanotechnology. Currently a researcher at King Mongkutā€™s University of Technology Thonburi, Thailand, his research intersects fractional calculus and mathematical modeling. Dr. Murtaza has co-supervised five M.Sc. theses on topics such as Maxwell nanofluids and fractal-fractional models. He has delivered talks at international conferences like INCSC 2023 in Turkey and Empowering a Global Revolution through Operations Research in Thailand. With over 18 published papers in reputable journals, his work advances the mathematical applications in materials science and fluid dynamics. His contributions to scientific research make him a valuable figure in the mathematical modeling of complex physical systems.

Professional Profile:

Scopus

Orcid

Google Scholar

Suitability for the Best Researcher Award:

Dr. Saqib Murtaza is an exceptional candidate for the “Best Researcher Award,” showcasing a blend of academic excellence, innovative research, and significant contributions to the field of applied mathematics, particularly in the areas of fluid dynamics, heat transfer, and nanofluids. Below is a summary of his qualifications and a conclusion regarding his suitability for the award:

šŸŽ“Education

Dr. Saqib Murtaza holds a Ph.D. in Mathematics from King Mongkutā€™s University of Technology Thonburi (2020ā€“2023), where he focused on fractal-fractional modeling in heat transfer. His M.Sc. in Mathematics from City University of Science & I.T. (2017ā€“2019) explored the time fractional analysis of generalized nanofluids in rotating frames. Additionally, he completed his earlier M.Sc. and B.Sc. in Mathematics at City University of Science & I.T. and the University of Peshawar, respectively. He also earned a B.Ed. degree from City University of Science & I.T. in 2016, reflecting his interest in education alongside research. His academic journey has fostered a robust understanding of fluid dynamics and mathematical modeling, fueling his contributions to advanced research in nanofluid dynamics and heat transfer models.

šŸ¢Experience

Dr. Murtaza has a diverse academic and research background. As a Ph.D. researcher at King Mongkutā€™s University of Technology Thonburi, he has focused on mathematical modeling in heat transfer and fluid dynamics. During his research tenure, he visited the University of Naples Federico II in Italy in 2023 to engage in modeling and data calibration in vegetation pattern dynamics. In addition to his research, Dr. Murtaza has co-supervised five M.Sc. theses on topics like Maxwell nanofluids and fractal-fractional models. He has actively contributed to scientific discourse through invited talks at prestigious international conferences, including INCSC 2023 in Turkey and Empowering a Global Revolution through Operations Research symposium in Thailand. His work continues to inspire new directions in nanotechnology and fluid dynamics.

šŸ…Awards and Honors

Dr. Murtaza has earned recognition for his contributions to mathematics and fluid dynamics. Notably, his work in heat transfer and nanofluid dynamics has been featured in major journals such as Scientific Reports and IEEE Access. His research and dedication have earned him invitations to speak at international platforms like the INCSC 2023 conference in Turkey. His ongoing contributions to mathematical modeling in fluid mechanics and nanotechnology also reflect his growing influence in these fields. Dr. Murtazaā€™s academic excellence, showcased through over 18 published research articles, continues to distinguish him in the global scientific community, earning him accolades from peers and scholars alike. His research is paving the way for innovations in the mathematical applications of nanotechnology and materials science.

šŸ”¬Research Focus

Dr. Murtaza’s research focuses on fractional calculus, fluid mechanics, and nanofluid dynamics. His work uses mathematical modeling to explore heat and mass transfer processes in complex systems, such as fractal-fractional models for nanofluids. He applies these mathematical techniques to real-world challenges in heat transfer and fluid dynamics. His research extends to studying nanofluid dynamics and developing models to optimize energy efficiency in various applications. With his expertise, Dr. Murtaza aims to advance the mathematical foundation of nanotechnology and heat transfer models, contributing to the development of energy-efficient materials and systems. His work in this field promises to lead to innovations that merge mathematics, engineering, and materials science.

Publication Top Notes:

  • Heat transfer analysis of generalized Jeffery nanofluid in a rotating frame: Atanganaā€“Baleanu and Caputoā€“Fabrizio fractional models
    • Cited by: 51
  • Parametric simulation of hybrid nanofluid flow consisting of cobalt ferrite nanoparticles with second-order slip and variable viscosity over an extending surface
    • Cited by: 49
  • Analysis and numerical simulation of fractal-fractional order non-linear couple stress nanofluid with cadmium telluride nanoparticles
    • Cited by: 45
  • Fractional mathematical modeling of malaria disease with treatment & insecticides
    • Cited by: 44
  • Atanganaā€“Baleanu fractional model for the flow of Jeffrey nanofluid with diffusion-thermo effects: applications in engine oil
    • Cited by: 41

 

 

 

Mr. Muhammad Aoun Abbas | Nanoscale Awards | Best Researcher Award

Mr. Muhammad Aoun Abbas | Nanoscale Awards | Best Researcher Award

Mr. Muhammad Aoun Abbas , Sejong University , South Korea

Muhammad Aoun Abbas, a Pakistani researcher currently pursuing a combined Master’s and Ph.D. at Sejong University in Seoul, South Korea, specializes in nanotechnology and advanced materials engineering. His research focuses on titanium-based alloys and high-entropy alloys, contributing to significant advancements in the field. Abbas has published several notable papers in journals such as the Journal of Alloys and Compounds and Intermetallics. He actively participates in international conferences and seminars related to materials science. In addition to his academic work, he is involved in volunteering with the Korea Islamic Culture Exchange Association, supporting blood donation drives and social initiatives.

Professional Profile:

Google Scholar

Suitability of Muhammad Aoun Abbas for Best Researcher Award:

Summary of Suitability:

Muhammad Aoun Abbas is an outstanding candidate for the Best Researcher Award due to his significant contributions to the field of nanotechnology and advanced materials engineering. Currently pursuing a combined Masterā€™s and Ph.D. at Sejong University, Abbas specializes in titanium-based alloys and high-entropy alloys, which are critical areas of research with substantial implications for material science.

šŸŽ“Education:

Muhammad Aoun Abbas is currently pursuing a combined Masterā€™s and Ph.D. in Nanotechnology and Advanced Materials Engineering at Sejong University in Seoul, South Korea, starting from March 2020. This advanced program reflects his commitment to specializing in cutting-edge materials science, focusing on innovations in nanotechnology and advanced materials.

šŸ¢Work Experience:

Since March 2020, Muhammad Aoun Abbas has been working as a University Research Assistant at Sejong University in the Department of Nanotechnology and Advanced Materials Engineering. His research focuses on titanium-based alloys and high-entropy alloys, contributing to advancements in these specialized fields.

Publication Top Notes:

  1. Nano-scale structural evolution of quaternary AlCrFeNi based high entropy alloys by the addition of specific minor elements and its effect on mechanical characteristics
    Cited by: 42
  2. Evolution of microstructure and mechanical characteristics of (CrFeNiCu)100ā€“xTix high-entropy alloys
    Cited by: 6
  3. Evolution of microstructure and mechanical properties of a Ti80 (CoFeNi) 20 ultrafine eutectic composite during thermal processing
  4. Large enhancement of yield strength in Ti80Cr20āˆ’x (CoFeNi)x alloys by modulating phase stability and introducing ultrafine eutectic structure
  5. Microstructural Evolution of Quaternary AlCoCrNi High-Entropy Alloys during Heat Treatment