Abstract
Efforts to improve the energy density and cycling stability of lithium-ion batteries have focused on replacing LiCoO(2) in cathodes with LiNi(x)Mn(y)Co(1-x-)(y)O(2). However, reliance on polyvinylidene fluoride (PVdF) as the binder limits the application of the LiNi(x)Mn(y)Co(1-x-)(y)O(2) composite electrode for lithium-ion batteries. Here, we evaluate the electrochemical properties of a LiNi(1/3)Mn(1/3)Co(1/3)O(2) (NMC111) powder electrode formed using a waterborne-styrene-acrylic-rubber (SAR) latex binder combined with sodium carboxymethylcellulose. The composite electrodes prepared with the SAR-based binder copolymerized with the butyl acrylate monomer and styrene exhibited high adhesive strength and excellent cyclability and rate capability. The results of surface analysis via X-ray photoelectron spectroscopy suggested that the electrode with the SAR-based binder is more resistant to electrolyte decomposition during charge and discharge cycling compared with the NMC111 electrode comprising the conventional PVdF binder. The SAR-derived passivation resulted in enhanced capacity retention during long-term cycling tests of both half- and full-cells (NMC111//graphite). An electrode with a higher Ni content, LiNi(0.6)Mn(0.2)Co(0.2)O(2) (NMC622), fabricated using the SAR-based binder, retained 87.1% of its capacity after 50 cycles at 4.6 V and exhibited excellent cycling stability.