The absorption of water molecules on surfaces can change the physiochemical properties of the materials, which play significant roles in various fields of science and engineering. Kelvin probe force microscopy (KPFM), a technique that can simultaneously provide topography imaging and work function mapping of a material surface with high spatial resolution at the nanoscale, can potentially be used to detect the absorption of water molecules on a surface under ambient conditions. Here, we will introduce the fundamentals of Kelvin probe force microscopy. Using graphene oxide (GO) as an example, we will also discuss how we can employ KPFM to investigate the impact of water absorption on the work function of GO under various environmental humidity. Our results demonstrate that KPFM can be an effective tool to investigate water absorption on surfaces and how the absorbed water molecules impact the properties of nanomaterials.