RESUMEN
Separators are indispensable components in lithium-ion batteries (LIBs), providing efficient pathways for lithium ions to travel and isolating the positive and negative electrodes to avoid short circuits. However, traditional polyolefin-based separators exhibit inferior electrolyte affinities, limited porosities, and low thermal stabilities. In this study, a novel method was developed to prepare chitosan micro/nanofiber membranes as LIB separators using natural materials. The pore sizes of the chitosan micro/nanofibers separators were modulated by changing the diameters of the chitosan fibers. The results demonstrated that the chitosan nanofiber separators (CSNFs) had superior electrolyte uptake (281 %), excellent thermal dimensional stability, and electrochemical performance in LiFePO4/Li half-cell, as indicated by the higher discharge capacity after 100 cycles, and higher rate capacity than commercial Celgard2325 separator. This study paves the way for the fabrication of eco-efficient and environment-friendly separators for high-performance LIBs.
RESUMEN
With the development of portable devices and wearable devices, there is a higher demand for high-energy density and light lithium-ion batteries (LIBs). The separator is a significant component directly affecting the performance of LIBs. In this paper, a thin and porous chitosan nanofiber separator was successfully fabricated using the simple ethanol displacement method. The thickness of the CME15 separator was about half that of mainstream commercial Celgard2325 separators. Owing to its inherent polarity and high porosity, the obtained CME15 separator achieved a small contact angle (18°) and excellent electrolyte wettability (324% uptake). The CME15 separator could maintain excellent thermal dimensional stability at 160 °C. Furthermore, the CME15 separator-based LIBs exhibited excellent cycling performance after 100 cycles (117 mAh g-1 at 1 C). The present work offers a perspective on applying a chitosan nanofiber separator in light and high-performance lithium-ion batteries (LIBs).
RESUMEN
Bone tissue repair is difficult due to the dense structure of the extracellular matrix. To solve this problem, a porous chitosan nanofiber scaffold (CSNFS) with an extracellular matrix-like structure was prepared via a facile cross-linked reaction of root-like chitosan nanofiber (CSNF) and collagen (Col) by using genipin (Gen) as the cross-linker. The optimal preparation conditions of CSNFS is weight ratio of CSNF:Col:Gen =1:1:0.1, crosslinked 48 h under 37 °C. CSNFS shows high porosity with adequate micro-scale pores, and its BET data shows that there are a large number of nano-scale pores. The CSNFS mechanical strength is higher than that of the chitosan scaffold both in dry and wet state. MC3T3 cells grow well on CSNFS, can overgrow the scaffold in three-dimensional space, adhere and differentiate well within those nanofiber structure. The cross-linked CSNFS has good biocompatibility and can be used as a repair material for bone tissue engineering.