@article{K. S. Balamurugan2_2022, title={Numerical Modeling on Maxwell Nanofluid through Stretching Sheet with Multiple Slip Features}, url={http://thedesignengineering.com/index.php/DE/article/view/8815}, abstractNote={<p>The boundary layer classic case of heat transmission on an upper-convection Nano-Maxwell fluid over stretched sheet is provided by comprehensive manner. Initially, a novel constitutive model, the Cattaneoe Christov upper-convected, is introduced to describe boundary layer shear flow, nanoparticle concentration and thermal diffusion. A linear relationship between temperature and the dynamic viscosity is assumed, along with Brownian motion and thermophoresis effects. Using the proper dimensionless variables, the strongly coupled boundary layer governing equations such as conservation of momentum, energy, and mass are translated into similarity equations. The bvp4c approaches are used to acquire and extensively examine the velocity, temperature, and concentration distributions that are impacted by the relevant relaxation parameters. Aside from velocity slip and thermal and solutal slips on the boundary layer, these impacts have been studied.</p&gt;}, number={1}, journal={Design Engineering}, author={K. S. Balamurugan2G. Dharmaiah,}, year={2022}, month={Jan.}, pages={386-395} }