The nucleate boiling regime is widely used in industrial applications as one of the most efficient modes of heat transfer, in which large amounts of heat can be dissipated from a heated surface with small changes in temperature, and is a common phenomenon observed in our daily lives. The mechanism of nucleate boiling is very complex, and its heat transfer efficiency can be characterized by three parameters: Onset of Nucleate Boiling (ONB) superheat, Heat Transfer Coefficient (HTC), and Critical Heat Flux (CHF). In this study, we will focus on the first two, and modify the surfaces in three ways: three copper mesh structures by hot-pressing on pure copper surfaces, a thin film structure by spin-coating nanofluid and four Laser Surface Texturing (LST) structures on the surface of aluminum 6061 alloy, with deionized water as the working fluid, to investigate the effect of pool boiling heat transfer under the saturated state of atmospheric pressure. Finally, the semi-theoretical model proposed by Hsu in 1962 provides the size range of active nucleation cavities. This study will attempt to validate the model experimentally. The experimental results show that compared to the smooth surface, three copper mesh structures and a thin film structure delay the superheat at ONB and decrease the HTC. Four laser surface texturing structures advance the superheat at ONB by 2.3-6.2 °C, and increase the HTC by 90-300% at heat flux of 500 kW/m2. The model proposed by Hsu for predicting the size range of active nucleation cavities is partially validated at a cavity pitch of 400 μm. The overall curve trend of the experimentally obtained nucleation range curve is similar to that of the predicted model, and the experimentally obtained critical radius is similar to that one predicted by some scholars for predicting thermal boundary layer thickness. However, in the case of cavity pitches of 1000 and 2000 μm, there is no trace of the Hsu model.