Tuning discharge voltage by Schottky electron barrier in P2-Na2/3Mg0.205Ni0.1Fe0.05Mn0.645O2

Recently, Mg doped Na metal oxide layered cathode compounds have attracted strong interest for Na-ion battery applications. Here a new type of asymmetric phase evolution between charge and discharge is found to show much-enhanced discharge voltage in P2-Na2/3Mg0.205Ni0.1Fe0.05Mn0.645O2 over the parent cathode compound. P2 solid solution is found to show an abnormal coexistence with O2-P2 two-phase reaction during discharge with simultaneous reduction of O, Ni, and Fe redoxes, distinct from the conventional P2-O2 two-phase reaction in the charge. Our analysis suggests that the P2 and O2 two-phase boundary forms a novel unidirectional Schottky barrier to impede electron and Na diffusions in discharge only, thus making the kinetically preferred P2 solid solution phase abnormally coexist with the two-phase region for high discharge voltage and low polarization. Our work demonstrates tuning dynamic evolution of electronic Schottky barrier as a new dimension for advanced kinetic design of high-performance battery cathode materials.

Automated summary

Recently, Mg doped Na metal oxide layered cathode compounds have attracted strong interest for Na-ion battery applications. A new type of asymmetric phase evolution between charge and discharge is found in P2-Na2/3Mg0.205Ni0.1Fe0.05Mn0.645O2, showing much-enhanced discharge voltage. The abnormal coexistence of the P2 solid solution with O2-P2 two-phase reaction during discharge, along with the reduction of O, Ni, and Fe redoxes, contributes to the high discharge voltage and low polarization.