vehicles and the grid.[ 2 ] Future large-scale LIB designs could benefi t from metalcation-based electrode materials capable of multiple-electron transfers (METs) per metal cation, [ 3 ] resulting in higher energy density compared to commonly employed intercalation-type electrodes. [ 4 ] Many electrode materials were reported to undergo MET reactions, such as metal oxides, fl uorides, nitrides and sulfi des, [ 4 a,f ] layered dichalcogenides, layered oxides, vanadyl phosphate, [ 4 g,h] and also mixed-anion and mixed-cation compounds. [ 5 a,c] Many of these electrode materials share a common feature in their structures, i.e., the closepacked anion framework with tetra hedral and octahedral sites being occupied by cations. The MET reactions in these materials very often involve both intercalation and conversion processes, leading to multiple phase transformations that can profoundly affect the rate capability and cycling stability. [ 6 ] Thus, a detailed mechanistic investigation is needed for better understanding of the complex MET reactions and associated structural changes. Metal oxides of the general formula, M 3 O 4 , such as Fe 3 O 4 , [ 4 b ,d, 7 ] Co 3 O 4 , [ 8 ] and Mn 3 O 4 , [ 9 ] have been considered as possible MET compounds; although they share the same formulation and have similar metal oxidation states, Fe 3 O 4 is an inverse spinel, Co 3 O 4 is a normal spinel, and Mn 3 O 4 is a tetragonally distorted spinel. For a spinel structure, M 2+ and M 3+ cations are located in tetrahedral (8a) and octahedral (16d) sites of a cubicclose-packed (ccp) O-anion array, respectively, while for an inverse spinel, the tetrahedral site is occupied by one of the M 3+ cations while the other M 3+ cation and the M 2+ cation occupy octahedral sites of a ccp O-anion array. These metal oxides are currently under active investigation for potential use as lithium insertion electrodes, [ 10 ] as well as conversion electrodes capable of delivering theoretically high capacities through full reduction of the transition metals. [ 1 , 6 a] One of the inverse spinel oxides, Fe 3 O 4 , has been intensely studied for battery applications, due to its low cost, natural abundance, and low toxicity. [ 6 b] A recent review highlights the signifi cance of the particle size and morphology of Fe 3 O 4 , as well as the role of the heterostructure encompassing the active material. [ 11 ] The mesoscale electrode environment of nanocrystalline Fe 3 O 4 has also been recently evaluated, indicating the signifi cant infl uence of agglomeration on functional capacity. [ 12 ] Metal oxides, such as Fe 3 O 4 , hold promise for future battery applications due to their abundance, low cost, and opportunity for high lithium storage capacity. In order to better understand the mechanisms of multiple-electron transfer reactions leading to high capacity in
