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Submission: On April 18 via manual from US — Scanned from DE
Submission: On April 18 via manual from US — Scanned from DE
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This website uses cookies to ensure you get the best experience on our website. Got it! * Login * Register JOURNAL OF APPLIED AND COMPUTATIONAL MECHANICS Advanced Search * Home * Browse * Current Issue * By Issue * By Author * By Subject * Author Index * Keyword Index * Journal Info * About Journal * Aims and Scope * Editorial Board * Publication Ethics * Indexing and Abstracting * Related Links * FAQ * Peer Review Process * News * Guide for Authors * Submit Manuscript * Reviewers * Contact Us × × × 1. My Home 2. Reviewer Dashboard 3. Agree/Decline to Review Manuscript Title: Heat transfer analysis of 2D steady laminar mixed convection, CNTs blood base nanofluid together a perpendicular, stretching sheets Abstract: In this research work, the heat transfer properties of a blood-based carbon nanotube (CNT) steady laminar mixed convection flow over perpendicular stretched sheets are studied. The blood-based nanofluid's unique thermal properties brought about by the CNTs make it a useful medium for improving heat transfer in biomedical applications. The governing equations of the momentum, energy, and flow equations are transformed into a set of nonlinear ordinary differential equations by applying the proper similarity transformations. The resulting equations are then solved analytically using the homotopy analysis method (HAM). Numerous significant factors are investigated, and their impact on the temperature and velocity patterns is examined. The investigation also takes into account the skin friction coefficient and Nusselt number. The results demonstrate that adding CNTs significantly raises heat transfer efficiency, which enhances cooling in biological domains. This study adds to our knowledge of the enhancement of heat transmission in blood-based nanofluids with carbon nanotubes and offers important new information for the development and improvement of thermal control systems in biomedical engineering. Furthermore, the results of this investigation can be applied to the creation of novel approaches to raise the effectiveness of cooling devices and heat exchangers in medical applications. This paper presents a theoretical basis for more research in this field and delivers insightful information about the heat transport properties of blood-based nanofluids in biomedical engineering applications. Keywords: Mathematica software, stretching surface, HAM I agree to review manuscript. © Journal Management System. Powered by Sinaweb