Effects of Al-dopant at Ni or Co sites in LiNi(0.6)Co(0.3)Ti(0.1)O(2) on interlayer slabs (Li–O) and intralayer slabs (TM–O) and their influence on the electrochemical performance of cathode materials

In order to satisfy the energy demands of the electromobility market, further improvements in cathode materials are receiving much attention, especially high energy density cathode materials for Li-ion batteries (LIBs). In this work, the self-propagating combustion (SPC) method is use to synthesise undoped LiNi(0.6)Co(0.3)Ti(0.1)O(2) (LNCT), novel nano-sized Al-doped LiNi(0.6)Co(0.3−x)Al(x)Ti(0.1)O(2) (LCA) and LiNi(0.6−x)Co(0.3)Al(x)Ti(0.1)O(2) (LNA) (x = 0.01) cathode materials. LNCT, LCA and LNA were annealed at 700 °C for 24 h. Following the synthesis, the phase, chemical structure and purity of the materials were analysed using X-ray diffraction (XRD). Based on the XRD results, all materials exhibit a single-phase structure with rhombohedral layered structure. Based on the HRTEM and EDX results, all samples exhibit polyhedral-like shapes, while the Al-doped samples display smaller crystallite sizes compared to the undoped sample. As for the electrochemical performances, the initially discharged capacity of LCA (238.6 mA h g(−1)) is higher than that of LNA (214.7 mA h g(−1)) and LNCT (150.5 mA h g(−1)). However, LNA has a lower loss of capacity after the 50(th) cycle compared to the LCA sample, which makes it a more excellent candidate for electrochemical applications. The main reason for the excellent electrochemical behaviour of LNA is due to lower cation mixing. Furthermore, Rietveld refinements reveal that the LNA sample has a longer atomic distance of Li–O and shorter TM–O in the cathode structure, which makes Li(+) ion diffusion more efficient, leading to excellent electrochemical performance. These findings further proved the potential of the novel nano cathode material of LiNi(0.6−x)Co(0.3)Al(x)Ti(0.1)O(2) (LNA) to replace the existing commercialized cathode materials for rechargeable Li-ion batteries.