Nanofluids　are　composed　of　nano-sized　particles　dispersed　in　a　carrier　liquid.　The　present　investigation＇s　aim　is　to　examine　theoretically　the　magneto-thermomechanical　coupling　phenomena　of　a　heated　nanofluid　on　a　stretched　surface　in　the　presence　of　magnetic　dipole　impact.　Fourier＇s　law　of　heat　conduction　is　used　to　evaluate　the　heat　transmission　rate　of　the　carrier　fluids　ethylene　glycol　and　water　along　with　suspended　nanoparticles　of　a　cobalt-chromium-tungsten-nickel　alloy　and　magnetite　ferrite.　A　set　of　partial　differential　equations　is　transformed　into　a　set　of　non-linear　ordinary　differential　equations　via　a　similarity　approach.　The　computation　is　performed　in　Matlab　by　employing　the　shooting　technique.　The　effect　of　the　magneto-thermomechanical　interaction　on　the　velocity　and　temperature　boundary　layer　profiles　with　the　attendant　effect　on　the　skin　friction　and　heat　transfer　is　analyzed.　The　maximum　and　minimum　thermal　energy　transfer　rates　are　computed　for　the　H2O-Fe3O4　and　C2H6O2-CoCr20W15Ni　magnetic　nanofluids.　Finally,　the　study＇s　results　are　compared　with　the　previously　available　data　and　are　found　to　be　in　good　agreement.