Abstract
Shear-phase early transition metal oxides, mostly of Nb, and comprising edge- and corner-shared metal–oxygen octahedra have seen a resurgence in recent years as fast-charging low-voltage electrodes for Li–ion batteries. Mo oxides, broadly, have been less well studied. Here we examine the reduced Mo oxide Mo4O11 that has a structure comprising only corner-connected MoO4 tetrahedra and MoO6 octahedra. Here we show that an electrode formed using micron sized particles of Mo4O11 as the active material can function as a high-rate Li–ion electrode against Li metal, with a stable capacity of over 200 mAh g-1 at the high rate of 5C. Operando X-ray diffraction (XRD), Raman spectroscopy, and entropic potential measurements are employed to understand the nature of charge storage. It is found that the structure dramatically changes upon the first lithiation, and subsequent cycling is completely reversible with low capacity fade. It is the newly formed, and potentially more layered structure that demonstrates high-rate cycling and small voltage polarization. This finding expands the scope of candidate high-rate electrode materials to those beyond the expected Nb-containing shear-phase oxide materials.
Figure 1