Abstract
In solar heating, ventilation, and air-conditioning (S-HVAC), communications are designed to create new 3D mathematical models that address the flow of Sutterby hybridization nanofluids rotating in front of slippery and expandable seats. The heat transfer investigation included effects such as copper (Cu) and aluminum alloys (AA7075) nanoparticles as well as thermal radiation. The activation energy and magneto effects were used to investigate mass transfer with fluid concentration. The limiting terms used were Maxwell's speed and Smoluchowksi's temperature slippage. With the use of fitting changes, numerically expressed partial differential equations (PDEs) strength, energy, and fixation can be reduced to ordinary differential equations (ODEs). To solve ODEs without dimensions, MATLAB's Keller box numerical technique was used. Copper-aluminum alloys/sodium alginate (Cu-AA7075/C6H9NaO7) is intended to address the performance analysis of the present study. Physical attributes, for example, surface drag coefficients, heat moves, and mass exchanges are mathematically processed and displayed as tables and figures when a variety of different factors differ. The field of temperature is increased by increasing the volume fraction of copper and graphene oxide nanoparticles, while the mass fraction field is increased by increasing the activation energy. When thermal radiative flowing upsurges by 55%, the heat transfer rate is boosted by 98% while the mass transfer rate is boosted by 86%.