Magnesium alloys possess high strength-to-weight ratio, good electromagnetic shielding properties, and biocompatibility. Alloying with lithium to form magnesium-lithium alloys can further reduce weight and enhance ductility along with toughness; however, magnesium-lithium alloys are susceptible to corrosion and can lead to disastrous failure, so developing an effective and environmentally friendly anti-corrosion treatment is essential and imperative. This study investigates the corrosion behavior of LZ91 alloy with and without titanate conversion coating treatment in order to clarify the mechanics behind the corrosion and suggest a valid choice to passivate the alloy. The results indicates that LZ91 alloy suffers little from galvanic corrosion; nevertheless, the corrosion of LZ91 actually begins at impurities, e. g. iron, manganese, and calcium rich phases. By applying proper titanate conversion treatment, a two layer conversion coating can be formed on LZ91. The existence of the coating results in lower corrosion current density and higher total impedance in dynamic polarization test and electrochemical impedance spectroscopy seperately. In addition, the in-situ photographing and electrochemical impedance spectroscopy both agree on that although the titanate conversion coating doesn’t drastically change the corrosion behavior of LZ91, it successfully delays the corrosion and lowers the corrosion rate.