Abstract
Rechargeable electrochemical cells with metallic anodes are of increasing scientific and technological interest. The complex composition, poorly defined morphology, heterogeneous chemistry, and unpredictable mechanics of interphases formed spontaneously on the anodes are often examined but rarely controlled. Here, we couple computational studies with experimental analysis of well-defined LiAl electrodes in realistic electrochemical environments to design anodes and interphases of known composition. We compare phase behavior, Li binding energies, and activation energy barriers for adatom transport and study their effects on the electrochemical reversibility of battery cells. As an illustration of potential practical benefits of our findings, we create cells in which LiAl anodes protected by Langmuir-Blodgett MoS(2) interphases are paired with 4.1 mAh cm(-2) LiNi(0.8)Co(0.1)Mn(0.1)O(2) cathodes. These studies reveal that small- and larger-format (196 mAh, 294 Wh kg(-1), and 513 Wh liter(-1)) cells based on protected LiAl anodes exhibit high reversibility and support stable Li migration during recharge of the cells.