La-Mg-Ni-based superlattice structure compounds are believed to be a promising negative electrode material with high power and superior hydrogen storage capacity for nickel-metal hydride batteries. They are built with [AB(5)] and [A(2)B(4)] subunits, stacked along the c axis, with the following two sequences: one of rhombohedral and the other of hexagonal symmetry, called 3R and 2H, respectively. In this paper, we present the synthesis conditions and detailed structural characterization of rhombohedral La0.63Nd0.16Mg0.21Ni3.53Al0.11 with the AB(4)-type structure. It is demonstrated that the AB(4) phase is formed by a peritectic reaction between Pr5Co19-type (2H) phase and one liquid phase in a range of 1000 -1010 degrees C. The compound exhibits a high discharge capacity of 391.2 mAh g(-1) and can reach 286.2 mAh g(-1) even at a discharge current of 1800 mA g(-1). The superior high rate dischargeability performance could be attributed to its preferable charge transfer rate and hydrogen diffusion speed. Furthermore, the cycling life of the AB(4) compound is up to 83.3% after 200 cycles. As a result of these desirable electrochemical properties, the AB(4)-type La-Mg-Ni-based compound with high power is considered to promote applications for high power battery materials. (C) 2019 Elsevier Ltd. All rights reserved.