Zinc-air batteries have attracted high research attention due to the advantages of high theoretical energy density and good environmental compatibility. The novel secondary zinc-air batteries are actively developing to apply in the fields of energy storage devices, electric vehicles, and defense technology. However, the development of secondary zinc-air batteries still faces several key challenges, including dendritic zinc formation and interfacial side reactions on zinc anodes. The unstable zinc dendrite growth and interfacial side reactions on anodes would promote electrode surface degradation resulting in performance decay and fast failure in battery, thereby obstructing the commercialization process of secondary zinc-air batteries. In this study, the zinc dendrite formation and suppression mechanisms of zinc-air battery anodes are explored by electrochemical curves analysis, structural and morphological measurements, and in operando/in situ X-ray microscopy probing. The in operando/in situ synchrotron transmission X-ray images clearly reveals the microstructural evolution of zinc deposits and the interfacial reaction of electrodes in different applied voltages and PEI additive concentrations. The results show that the zinc dendrite growth on anode can be suppressed by controlling zinc deposition kinetics. The morphology of deposited zinc nuclei is changed from a spiky dendritic structure to dense rock-like and film structures with the applied voltage decreasing and PEI adding. The morphology of formed zinc nuclei further dominates the structural evolution of zinc deposits later on. These results could provide valuable information for the development of secondary zinc-air batteries.