This paper explores the complexity of three-dimensional Von-Karman flow in a water-based ternary hybrid nanoliquid system caused by a spinning disc with radially linear stretching. The surface is regarded as a primary contributor to radiative heat transfer, with the inclusion of ohmic and viscous dissipations caused by the medium. In addition, a magnetic field with a consistent strength and direction is applied along the axis. The nanostructures present include spherical magnetite, cylindrical alumina, and platelet-shaped silver. An extensive examination of similarity solutions is conducted for the governing partial differential system under significant multi-slip boundary conditions. The converted system is analysed using the MATLAB pre-existing code, bvpa4c. The study centres on doing a comparative investigation of magnetic nanoparticles, numerous slips, and radiation effects on the given problem. Significantly, higher rotation rates have a beneficial effect on both the radial and axial movement of the surface. The heat transfer rate is positively affected by an increase in the radiation parameter, while it is negatively affected by a rising Eckert number.