Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue
Kamel, R., Hady, F., Ismaeel, A. (2025). Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue. EKB Journal Management System, 54(2), 20-228. doi: 10.21608/aunj.2025.343101.1110
Rehab Shahir Kamel; Fekry Mohamed Hady; Ahmed Mustafa Ismaeel. "Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue". EKB Journal Management System, 54, 2, 2025, 20-228. doi: 10.21608/aunj.2025.343101.1110
Kamel, R., Hady, F., Ismaeel, A. (2025). 'Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue', EKB Journal Management System, 54(2), pp. 20-228. doi: 10.21608/aunj.2025.343101.1110
Kamel, R., Hady, F., Ismaeel, A. Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue. EKB Journal Management System, 2025; 54(2): 20-228. doi: 10.21608/aunj.2025.343101.1110

Numerical Study of Sutterby Nanofluid Flow Over Unstretched Horizontal Cylinder Enveloped by Heated Tissue

Assiut University Journal of Multidisciplinary Scientific Research
Volume 54, Issue 2, May 2025, Page 20-228  XML PDF (871.09 K)
Document Type: Novel Research Articles
DOI: 10.21608/aunj.2025.343101.1110
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Authors
Rehab Shahir Kamel email 1; Fekry Mohamed Hady2; Ahmed Mustafa Ismaeel3
1Mathematics department, faculty of science, Elminya university
2Mathematics department, faculty of science, Assuit University
3Faculty of Basic Sciences, King Salman International University, Ras Sudr, South Sinai, Egypt.
Abstract
Heat transfer is crucial in various biological applications, impacting physiological processes, medical treatments, and biotechnological innovations.
We created a mathematical model for Sutterby nanofluid on the surface of an unexpended horizontal cylinder exposure to an external heat source and a magnetic field. This led to a nonlinear differential system, which we numerically solved using MATLAB’s built-in solver (bvp4c). We explored the effects of Brownian motion, thermophoresis, interstitial fluid velocity, and tissue thermal absorption. Our findings reveal that increasing K enhances NP accumulation while raising interstitial fluid temperature. Conversely, higher R_d reduces NP concentration, potentially compromising treatment efficacy. The influence of thermophoresis and Brownian motion further underscores the importance of understanding particle behavior within the tumor microenvironment. The results demonstrate that higher thermophoresis parameters can increase NP concentration, while increased Brownian motion leads to a reduction in NP concentration. The magnetic field parameter was found to enhance both temperature and NP concentration, improving treatment efficiency.
Overall, this study emphasizes the critical role of fluid dynamics and thermal properties in optimizing thermal therapy for cancer. The insights gained from this analysis can help in future research and clinical applications, guiding the development of more effective treatment strategies that leverage the unique properties of nanofluids. Future work should focus on further refining these models and exploring additional factors that may influence treatment efficacy.
Keywords
Sutterby nanofluid; interstitial fluid velocity; hyperthermia therapy; Brownian motion; thermophoresis
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