The electrochemical reaction with lithium of a vanadium-based metal-organic framework V-IV(O)(bdc) [MIL-47], which is isostructural to the iron compound MIL-53(Fe), was investigated. The large open channels which can accommodate small guest species, such as Li+ ions, together with the redox properties of the tetravalent vanadium ions make this material of potential interest as a rechargeable intercalation electrode for lithium batteries. The electrochemical properties were investigated in Li vertical bar 1 M LiPF6 in ethylene carbonate (EC) and dimethyl carbonate (DMC)vertical bar V(O)(bdc) cells between 4.0 and 1.5 V vs. Li/Li+. V(O)(bdc) cathodes can be reversibly cycled in Li cells with good rate capability and specific capacity. At a current density of C/12, Li/V(O)(bdc) cells can be cycled between 0 <= x <= 0.7 in LixV(O)(bdc) with similar to 100% coulombic efficiency corresponding to 82 mAh g(-1) which is a higher capacity than that found for MIL-53(Fe). The cell performance and electrochemical profiles at various current conditions are discussed. Structural evolution taking place during lithium intercalation was monitored by powder X-ray diffraction on phases of LixV(O)(bdc) (0

Keywords:Vanadium benzenedicarboxylate;Metal-organic framework;Lithium intercalation;Electrode materials;Lithium batteries