After a first charge-discharge cycle within the 4.3-5.2 V range, leading to the formation of a passivation layer, LixCryMn2-yO4 materials with y less than or equal to 0.75 present a good reversiblity contrary to those with y > 0.75. The use of a LiPF6-based, rather than a LiClO4-based electrolyte, enables an easier separation of successive Li deinsertion processes, and strongly decreases the current of electrolyte oxidation above 5.1 V. However, regardless of the electrolyte, the separation of bulk and superficial phenomena on the active material can be done using methods which depend on the evolution of the electrolyte oxidation rate with the voltage. Thanks to these separation methods, the influence of various experimental parameters on the irreversible and cyclable capacities was examined. It is shown that the cyclable capacity does not depend on the scan rate provided that the end-of-charge voltage is high enough to reach the end of the deintercalation process, Furthermore, an optimized composition of the composite electrode is suggested from the variations of both capacities with the mass of active material and the carbon black content.