We have examined the evolution of the oxidation state and atomic structure of vanadium(V) in discharged and charged nanophase vanadium pentoxide (V 2O 5) aerogel cathodes under in situ conditions using X-ray absorption spectroscopy (XAS). We show that the oxidation state of V in V 2O 5 aerogel cathode heated under vacuum (100 μTorr) at 220 °C for 20.5 h is similar to that of V in a commercially obtained sample of orthorhombic V 2O 5. In addition, lithium (Li) insertion during the first cycle of discharging leads to the reduction of V(V) to V(IV) and V(IV) to V(III) in a manner consistent with the stoichiometry of the sample (i.e. Li x V 2O 5). Li extraction during charging leads to oxidation of V(III) to V(IV) and then V(IV) to V(V). Furthermore, the oxidation state of V in fully charged cathodes remains unchanged with cycling (upto at least the 16th cycle) from that of V in the control V 2O 5 aerogel cathode. However, the average oxidation state of V in discharged V 2O 5 cathodes increased with cycling. Moreover, the local structure of V in the discharged state has a higher degree of symmetry than that of the fully charged state. A significant change in the structure of the VV correlation of discharged cathodes is observed with cycling indicating the formation of electrochemically irreversible phases.