Abstract
Fluorine-doped carbon coated olivine LiFePO4-xFx composite (LFPF/CF) is synthesized by a simple solid-state reaction method, and the Tween 40 and polyvinylidene fluoride were used as carbon source and fluorine sources, respectively. Benefiting from the Tween 40 is attributed to formation a homogeneous carbon layer on the surface of LiFePO4 particles. And polyvinylidene fluoride could produces fluoride in the thermal decomposition process, which is doped into carbon and LiFePO4 to form fluoride-doped carbon layer and LiFePO4-xFx, respectively. In this constructed architecture, the F-doped carbon layer acts as conductive network for LFP, which can enhance the electronic conductivity of overall electrode. Furthermore, the crystal lattice of LFP was enlarged by the F doping, which facilitates the Li+ intercalation/deintercalation. On the other hand, a strong electronic coupling between F-doped carbon and LiFePO4-xFx can effectively suppress the shedding of carbon layer during cycling process, which keep stabilized of the reaction interface, and thus enhance the cycling stability. As a result, LFPF/CF composite shows superior rate performance (164.8, 159.2, 148.6, 135.8 and 102.3 mAh g-1 at 0.1, 0.5, 1, 2, 5 and 10 C), and excellent cycling stability (high capacity retention of 95.6% after 500 cycles at high rate of 5 C).
Highlights
Lithium ion batteries (LIBs) have been considered as one of the promising power sources in practical applications, for examples, electric vehicles (EVs), hybrid electric vehicles (HEVs) (Armand and Tarascon, 2008; Van Noorden, 2014; Whittingham, 2014)
The common strategy combined with cationic doping and the carbon coating is very complicated, which must via a two or three steps including the preliminary synthesis of lithium iron phosphate and subsequent surface coating and cationic doping (Shu et al, 2014; Li et al, 2015)
We focus on study the effect of the F-doped carbon coating and cationic doping on electrochemical performance
Summary
Lithium ion batteries (LIBs) have been considered as one of the promising power sources in practical applications, for examples, electric vehicles (EVs), hybrid electric vehicles (HEVs) (Armand and Tarascon, 2008; Van Noorden, 2014; Whittingham, 2014). Zhang et al prepared Li4SiO4-coated LiFePO4 by solgel method and microwave heating, delivers reversible capacity of 100 mAh g−1 at 5 C (Zhang et al, 2012) These results indicate that the cationic doping or surface coating is effective approach to improve rate performance of LiFePO4. An upgrade strategy combined with cationic doping and carbon coating is used to enhance the rate performance of LiFePO4. As a result, benefiting from combined the advantages of surface coating and cationic doping, the obtained LFPF/CF exhibits high reversible capacity, excellent cycling stability, and rate performance. F-doped carbon coat LiFePO3.938F0.062 composites (LFPF/CF) were prepared by one step solid phase method, using Tween and PVDF as carbon sources and fluorine sources, respectively. Electrochemical impedance spectroscopy (EIS) of the cell was measured by using IM6 electrochemical workstation, with the 5 mV amplitude of the AC signal at the frequency range between 100 kHz and 0.01 Hz
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