RT Journal Article ID 4f7f93cd0bdaac07 A1 Mishra, Ashish A1 Pandey, Alok Kumar A1 Kumar, Manoj T1 NUMERICAL INVESTIGATION OF HEAT TRANSFER OF MHD NANOFLUID OVER A VERTICAL CONE DUE TO VISCOUS-OHMIC DISSIPATION AND SLIP BOUNDARY CONDITIONS JF Nanoscience and Technology: An International Journal JO NST YR 2019 FD 2019-07-23 VO 10 IS 2 SP 169 OP 193 K1 heat generation/absorption K1 nanofluid K1 viscous-ohmic dissipation K1 slip boundary conditions K1 suction/injection K1 vertical cone AB An analysis is made of heat transfer characteristics of Ag–water nanofluid flow towards a permeable vertical cone due to the ambiguity of thermal conductivity in the presence of magnetic force, viscous-ohmic dissipation, heat generation/absorption, and suction/blowing effects. Adequate transformations yield a nonlinear system of ODEs, and the fourth-fifth-order RKF technique with a shooting scheme is used to attain the solution of involved ODEs in cooperation with auxiliary boundary conditions. Two models of thermal conductivity of shape-dependent nanoparticles with dynamic viscosity are considered. The influence of the solid volume fraction on dimensionless skin friction and Nusselt number along with velocity slip, thermal slip, magnetic parameter, Eckert number, heat generation/absorption, and suction/blowing parameters are depicted by graphs and tables. The upshots show that an increment in the volume fraction of solid particles decreases the Nusselt number for each value of velocity slip, thermal slip, and magnetic parameter. Moreover, it is accelerated when injection shifts to the suction region for each value of solid volumetric fraction of silver nanoparticles in both models of thermal conductivity. The acquired data are compared with prior investigation, and excellent agreement is obtained. PB Begell House LK https://www.dl.begellhouse.com/journals/11e12455066dab5d,301f634c15166576,4f7f93cd0bdaac07.html