There are two topics discussed in this study: evaporation of water droplet containing silicon dioxide nanoparticles on homogeneous surfaces with different hydrophobicities and evaporation of liquid droplet on chemically heterogeneous striped surface. First, the evaporation mechanism of pure water droplet and water droplet containing silica nanoparticles on silicon wafer with different self-assembled-monolayers were observed and compared from top and side view in this study. The evaporation mechanism generally starts with constant contact radius mode and turns into constant contact angle mode when the receding contact angle is reached. Finally, the mechanism enters the mixed mode. The major differences of the evaporation process are an additional contact line pinning during the mixed mode and a ring-like structure left on the surface after the droplet drying. For each surface, it is found that the concentration at pinning moment is rather a constant and independent of initial concentration. Moreover, the concentration is highly related to the hydrophobicity of the surface. Second, chemically heterogeneous striped surfaces consisting of alternating and parallel hydrophobic/hydrophilic self-assembled monolayer were prepared on silicon substrate by micro-contact printing. The evaporation of a sessile droplet on the heterogeneous surface was studied by enhanced video microscopy system to record the evolution of contact angle and contact radius along two different viewing angles (normal or parallel to the stripe) in the evaporation process. At the very beginning of the evaporation process in these two viewing angles, the contact angle decreases dramatically while the radius of three phase contact line remains almost constant. Then, the angle decreases slowly while the radius decreases. It is interesting to note that the angle in the direction parallel to the stripe exhibits the stick-slip-jump phenomenon and the radius decreases with a step jump while the contact angle and radius in the direction normal to stripe decrease disorderly. In addition, the corrugation of the three phase contact line of ethanol droplet and dynamic shrinkage of contact line during evaporation are observed. Besides, in an appropriate initial concentration of ethanol-based droplet containing silica nanoparticle, a regular pattern of nanoparticles on hydrophilic lines can be observed after the droplet drying.