We demonstrate nanoscale architectures in real biominerals and their biomimetics. Mimicking biomineralization, that is, crystal design in association with organic molecules, has been demonstrated in recent years. Although the macroscopic morphologies in real biominerals and biomimetics have been extensively studied, the nanoscopic structures in terms of the crystal growth are still not fully understood. We show that both materials form oriented architectures of bridged nanocrystals with incorporated organic polymers. The growth of nanocrystals by association with polymers is a significant step for the understanding and developing of crystal growth. The strategy could be applied to various systems in nanoscale crystal growth leading to functional materials.
To study the effect of different polymer binders on electrochemical performance of the Si composite electrode in rechargeable lithium-ion batteries, sodium polyacrylate (PAANa), sodium carboxymethyl cellulose (CMCNa), and poly(vinylidene fluoride) (PVdF) are utilized as the polymer binders for the preparation of composite electrodes consisting of powdery silicon, graphite, and Ketjen black. The electrodes are examined by cross-sectional observation using a scanning electron microscope after a focused ion beam process, X-ray photoelectron spectroscopy, micro Raman spectroscopy, X-ray diffraction, and a peel test. We report that electrode performance of the Si composites depends on a selection of binders, and PAANa binder remarkably improves the electrochemical lithiation and delithiation performance of the Si–graphite composite electrode compared to that of conventional binders of PVdF and CMCNa. When the electrode is prepared with 30 wt % PAANa binder, the higher initial efficiency is obtained with much improved cyclability. Furthermore, the specific capacity of the electrode reaches 1000 mAh g–1 and exceeds 800 mAh g–1 of reversible capacity during the 30 continuous cycling test. The PAANa polymer binder increases the mechanical strength and adhesive strength as composite electrodes. Furthermore, the polymer layer reduces the electrolyte decomposition at the Si particles and suppresses the capacity deterioration by volume change and pulverization due to Si–Li alloying, compared with PVdF, leading to the better electrochemical reversibility.
The electrochemical behavior of oxygen ͑O 2 ͒/superoxide ion ͑O 2 − ͒ couple was investigated with the aid of the ultramicroelectrode technique in 1-butyl-1-methylpyrrolidinium bis͑trifluoromethylsulfonyl͒imide ͑BMPTFSI͒ room-temperature molten salt ͑ionic liquid͒. The diffusion coefficient of O 2 was ͑1.8 ± 0.2͒ ϫ 10 −6 cm 2 s −1 at 25°C. The activation energy of the diffusion process of O 2 was estimated to be 27 kJ mol −1 from the temperature dependence of the diffusion coefficient. The solubility of O 2 in BMPTFSI was 14 mmol dm −3 at 25°C and decreased with an increase in temperature. The diffusion coefficient of O 2 − was 0.86 ϫ 10 −6 cm 2 s −1 at 25°C. The formal potential of O 2 /O 2 − couple was 1.13 V vs ferrocene/ferrocenium.
Graphite/silicon composite electrodes are prepared with PANa polymer as a binder. Morphological characters and electrode performance are compared with those of PVdF. The PANa layer behaves like SEI at the interface with ionic liquid, resulting in the highly reversible electrode performance.
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