AI Article Synopsis
- LiNiCoAlO is a promising cathode material for lithium-ion batteries, known for its high energy density and affordability, but conventional synthesis methods struggle to produce it with consistent quality and performance.
- A new synthesis strategy using CoAl-layered double hydroxide nanosheets as a coating for Ni(OH) precursors results in LiNiCoAlO with improved sphericity, uniform particle size, and pure phase.
- The process enhances electrochemical performance through a buffer layer formation and synergistic effects between Co and Al, which prevent undesired phases and promote uniform element distribution.
Article Abstract
Ni-rich layered oxide LiNiCoAlO is a promising cathode material for high-power lithium-ion batteries due to its high energy density and low cost. However, obtaining LiNiCoAlO with a large and uniform particle size and without undesired Al-related phases using some conventional synthesis methods is quite difficult. These problems seriously affect the electrochemical performance of LiNiCoAlO, thus impeding its wide application. Here, we propose a simple strategy to synthesize LiNiCoAlO using CoAl-layered double hydroxide (CoAl-LDH) nanosheet-coated Ni(OH) as the precursor. Compared with LiNiCoAlO synthesized from nickel-cobalt-aluminum hydroxide and Al(OH)-coated nickel-cobalt hydroxide precursors, LiNiCoAlO produced using the proposed approach showed good sphericity, a large and uniform particle size, a pure phase, and excellent electrochemical performance. The superior properties are attributed to the dual effects of the buffer layer and synergistic diffusion. Specifically, the CoAl-LDH coating layer reacts with LiOH during the lithiation-calcination process to form a Li(CoAl)O mesophase as the buffer layer, which increases the formation temperature of the layered structure and reduces Li/Ni cation mixing, making a well-ordered crystal structure. Moreover, spectroscopic analysis results and density functional theory calculations indicated a synergistic diffusion effect between Co and Al, and the presence of Co on the surface promotes the diffusion of Al during the lithiation-calcination process, thus avoiding the formation of undesired Al-related phases and allowing for a uniform element distribution.
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