A fundamental concept in thermodynamics, heat transmission is important in many engineering applications. The three main ways that heat energy is transferred from hotter regions to colder ones are conduction, convection, and radiation. Energy is transferred within a substance by conduction, which happens when energetic particles contact with nearby, less energetic ones. Different geometries, including flat, cylindrical, and spherical, and their corresponding heat transfer properties are explored in the study of steady-state heat transfer in conduction. Contrarily, convection is a process wherein a surface and a fluid flows across it and exchange energy. Natural convection is where the motion is solely driven by buoyancy forces arising from changes in density while forced convection, is when the motion is solely driven by an external force, such as a pump or fan. The Prandtl Number governs the connection between the thermal and velocity boundaries during the flow and offers important information about the fluid behavior in convection. The third type of heat transfer involves the transfer of energy in the form of electromagnetic waves due to changes in the electronic structures of atoms or molecules. Numerous applications of this phenomenon are common, including heat exchange in space, industrial furnaces, and astrophysics. Applications of these mechanisms have been thoroughly investigated throughout the study of heat transfer, furthering our grasp of their basic principles. This information is frequently used by engineers and researchers to create effective thermal systems, enhance heat dissipation in electronic devices, and solve numerous other heat management-related problems. In conclusion, heat transfer mechanisms and its application play a crucial role in many engineering and scientific disciplines, enabling the development of novel technologies and solutions for a variety of thermal challenges.