In considering the popularly used corrosion-resistant Zn-Ni alloy coatings by electro plating, the environmental compatibility and hydrogen embrittlement problems are generally encountered. Cathodic arc plasma ion plating technology capable of high-speed deposition seems to be an alternative of electroplating. In this study, such a process was chosen to deposit Zn-Ni alloy coatings on AISI 304 stainless steel. The coating surface and cross sectional view of the deposited alloy coatings were observed, and the film composition and crystal structure of Zn-Ni alloy coatings was analyzed. Potentiodynamic polarization experiment was carried in aerated 3.5wt%sodium chloride electrolyte to evaluate the feasibility of corrosion protection for the Zn-Ni alloy coatings deposited by cathodic arc plasma ion plating. Experimental results show that target Zn73Ni27 is brittle and its critical arc current is very small. At low working pressure the slow-moving single arc spot on the target surface induced local overheating on target, and caused chipping near target edge. When the working pressure was increased, the arc was split into multiple spots. The spots may move more rapidly on the target surface thus emitting higher ion flux suitable for Zn-Ni alloy depositing. The major phases in the deposited film are γ-Zn21Ni5 and γ1-Zn3Ni, and the thickness of the deposited film is about 2-3μm,with many microparticles on the film surface. The chemical composition of the Zn-Ni alloy film is Zn87Ni13 with Zn composition higher than that of the target source. The results of potentiodynamic polarization experiment show that Zn-Ni film increases the corrosion resistance. A problem of brittle failure of the target Zn73Ni27 during coating is pending.