Local structure of vanadium in doped LiFePO4

LiFePO₄ composites with 5 at.% vanadium doping are prepared by solid state reactions. X‐ray absorption fine‐structure spectroscopy is used as a novel technique to identify vanadium sites. Both experimental analyses and theoretical simulations show that vanadium does not enter into the LiFePO₄ crystal lattice. When the vanadium concentration is lower then 1 at.%, the dopant remains insoluble. Thus, a single‐phase vanadium‐doped LiFePO₄ cannot be formed and the improved electrochemical properties of vanadium‐doped LiFePO₄ previously reported cannot be associated with crystal structure changes of the LiFePO₄via vanadium doping.     

Electrochemical behavior of Mg-doped 7LiFePO4–Li3V2(PO4)3 composite cathode material for lithium-ion batteries

Mg-doping effects on the electrochemical property of LiFePO₄–Li₃V₂(PO₄)₃ composite materials, a mutual-doping system, are investigated. X-ray diffraction study indicates that Mg doping decreases the cell volume of LiFePO₄ in the composite. The cyclic voltammograms reveal that the reversibility of the electrode reaction and the diffusion of lithium ion is enhanced by Mg doping. Mg doping also improves the conductivity and rate capacity of 7LiFePO₄–Li₃V₂(PO₄)₃ composite material and decreases the polarization of the electrode reaction. The discharge capacity of the Mg-doped composite was 93 mAh?g^?1 at the current density of 1,500 mA?g^?1, and Mg-doped composite has better discharge performance than the original 7LiFePO₄–Li₃V₂(PO₄)₃ composite at low temperature, too. At ?30 °C, the discharge capacity of Mg-doped LFVP is 89 mAh?g^?1, higher than that of the original composite. Electrochemical impedance spectroscopy study shows that Mg²⁺ doping could enhance the electrochemical activity of 7LiFePO₄–Li₃V₂(PO₄)₃ composite. Mg doping has a positive influence on the electrochemical performance of the LiFePO₄–Li₃V₂(PO₄)₃ composite material.     

Recent developments in the doping and surface modification of LiFePO4 as cathode material for power lithium ion battery

Lithium ion batteries have become attractive for portable devices due to their higher energy density compared to other systems. With a growing interest to develop rechargeable batteries for electric vehicles, lithium iron phosphate (LiFePO₄) is considered to replace the currently used LiCoO₂ cathodes in lithium ion cells. LiFePO₄ is a technically important cathode material for new-generation power lithium ion battery applications because of its abundance in raw materials, environmental friendliness, perfect cycling performance, and safety characteristics. However, the commercial use of LiFePO₄ cathode material has been hindered to date by their low electronic conductivity. This review highlights the recent progress in improving and understanding the electrochemical performance like the rate ability and cycling performance of LiFePO₄ cathode. This review sums up some important researches related to LiFePO₄ cathode material, including doping and coating on surface. Doping elements with coating conductive film is an effective way to improve its rate ability.     

Structural and electrochemical properties of LiFe1 − 3x/2Bi x PO4/C synthesized by sol–gel

In this study, LiFe_1???3x/2Bi _x PO₄/C cathode material was synthesized by sol–gel method. From XRD patterns, it was found that the Bi-doped LiFePO₄/C cathode material had the same olivine structure with LiFePO₄/C. SEM studies revealed that Bi doping can effectively decrease the particle sizes. It shortened Li⁺ diffusion distance between LiFePO₄ phase and FePO₄ phase. The LiFe_0.94Bi_0.04PO₄/C powder exhibited a specific initial discharge capacity of about 149.6 mAh g^?1 at 0.1 rate as compared to 123.5 mAh g^?1 of LiFePO₄/C. EIS results indicated that the charge-transfer resistance of LiFePO₄/C decreased greatly after Bi doping.     

Synthesis and electrochemical performance of LiFePO<Subscript>4</Subscript>/C cathode materials from Fe<Subscript>2</Subscript>O<Subscript>3</Subscript> for high-power lithium-ion batteries

Carbon-coated olivine-structured LiFePO₄/C composites are synthesized via an efficient and low-cost carbothermal reduction method using Fe₂O₃ as iron source at a relative low temperature (600 °C). The effects of two kinds of carbon sources, inorganic (acetylene black) and organic (sucrose), on the structures, morphologies, and lithium storage properties of LiFePO₄/C are evaluated in details. The particle size and distribution of the carbon-coated LiFePO₄ from sucrose (LiFePO₄/SUC) are more uniform than that obtained from acetylene black (LiFePO₄/AB). Moreover, the LiFePO₄/SUC nanocomposite shows superior electrochemical properties such as high discharge capacity of 156 mAh g^?1 at 0.1 C, excellent cyclic stability, and rate capability (78 mAh g^?1 at 20 C), as compared to LiFePO₄/AB. Cyclic voltammetric test discloses that the Li-ion diffusion, the reversibility of lithium extraction/insertion, and electrical conductivity are significantly improved in LiFePO₄/SUC composite. It is believed that olivine-structured LiFePO₄ decorated with carbon from organic carbon source (sucrose) using Fe₂O₃ is a promising cathode for high-power lithium-ion batteries.     

Preparation of V-LiFePO4 cathode material for Li-ion batteries

The preparation of vanadium-modified olivine LiFePO₄ was attempted using vanadium-modified FePO₄ precursor which was synthesized by controlled crystallization. The structure and electrochemical behavior of V-LiFePO₄ with different vanadium contents were investigated. The electrochemical behavior of V-LiFePO₄ materials at high rate and low temperature was compared with that of the LiFePO₄ material. Incorporation of vanadium improved the electrochemical performance of LiFePO₄. The investigation showed that the 3%V-modified LiFePO₄ presented the best electrochemical performance.     

Kinetic study on LiFePO<Subscript>4</Subscript>-positive electrode material of lithium-ion battery

LiFePO₄-positive electrode material was successfully synthesized by a solid-state method, and the effect of storage temperatures on kinetics of lithium-ion insertion for LiFePO₄-positive electrode material was investigated by electrochemical impedance spectroscopy. The charge-transfer resistance of LiFePO₄ electrode decreases with increasing the storage temperatures. This suggests that it has a high electrochemical activity at high temperature. The diffusion coefficient of lithium ion is greatly increased with increasing the storage temperatures, indicating that the kinetics of Li⁺ and electron transfer into the electrodes were much fast at high storage temperature.     

Structural properties of composite cathode material LiFePO<Subscript>4</Subscript>–Li<Subscript>3</Subscript>V<Subscript>2</Subscript>(PO<Subscript>4</Subscript>)<Subscript>3</Subscript>

Composite cathode material LiFePO₄–Li₃V₂(PO₄)₃ is synthesized through a chemical reduction and lithiation using FeVO₄·xH₂O as both iron and vanadium sources. The structural properties of LiFePO₄–Li₃V₂(PO₄)₃ are investigated. X-ray diffraction results show the composite material containing olivine type LiFePO₄ and monoclinic Li₃V₂(PO₄)₃ phases. High-resolution transmission electron microscopy and energy-dispersive X-ray spectrometry results indicate that mutual doping effects take place between the LiFePO₄ and Li₃V₂(PO₄)₃ particles with V³⁺ doping the LiFePO₄ while Fe²⁺ dopes the Li₃V₂(PO₄)₃. LiFePO₄–Li₃V₂(PO₄)₃ nanocomposites are formed in the carbon webs. There is no structural compatibility between monoclinic (Li₃V₂(PO₄)₃) and olivine (LiFePO₄) domains in composite material LiFePO₄–Li₃V₂(PO₄)₃.     

CdSe–Au nanorod networks welded by gold domains: a promising structure for nano-optoelectronic components

LiFePO_4?x F _x /C nanorods were prepared by room-temperature solid-state reaction and microwave heating. The structure and morphology of the as-prepared materials were analyzed by X-ray diffractometry and transmission electron microscopy. The results shows that the LiFePO_4?x F _x /C were well crystallized and consisted of nanoparticles with an average diameter of ten to several tens of nanometers, many round grains constituted solid rod-like structure. The length of the rods can be up to several hundreds of nanometers, and their diameters are around 100?nm. The results of electrochemical testing show that the initial discharge capacity of LiFePO_3.85F_0.15/C is 124.7?mAh?g^?1, with a negligible fading after 50 cycles at a constant current density of 1 C at room temperature. The capacity retention rate is 99.5?%, which is higher than that of LiFePO₄/C prepared by the same method. The doping of F helps improve electrical conductivity and Li⁺ diffusion of LiFePO₄/C. This study may provide new insights and understanding on the effect of F-doping on the electrochemical performance of LiFePO₄/C.     

First principles study on electronic properties and occupancy sites of molybdenum doped into LiFePO4

The electronic properties of Mo-doped LiFePO₄ and occupancy sites of Mo are investigated by employing the density functional theory plane-wave pseudopotential method. The calculated results show that Mo doping at Fe site has lower formation energy, which implies that Mo dopants prefer to occupy Fe sites within the LiFePO₄ lattice. Furthermore, the LiFe_1?3/12Mo_1/12PO₄ has wider lithium ion migration channels than Li_1?6/12Mo_1/12FePO₄. For the case of LiFe_1?3/12Mo_1/12PO₄, the calculated narrow band gap (0.18 eV) indicates that the electronic conductivity of LiFePO₄ could be enhanced by doping Mo at the Fe sites. The density of states and charge densities of LiFe_1?3/12Mo_1/12PO₄ demonstrate that the Mo-4d states and MoO bonding play important roles in band gap reduction of LiFe_1?3/12Mo_1/12PO₄.     

Structural and electrochemical properties of Nd-doped LiFePO4/C prepared without using inert gas

To further improve the electrochemical performance of LiFePO₄/C, Nd doping has been adopted for cathode material of the lithium ion batteries. The Nd-doped LiFePO₄/C cathode was synthesized by a novel solid-state reaction method at 750 °C without using inert gas. The Li_0.99Nd_0.01FePO₄/C composite has been systematically characterized by X-ray diffraction, EDS, SEM, TEM, charge/discharge test, electrochemical impedance spectroscopy and cyclic stability. The results indicate that the prepared sample has olivine structure and the Nd³⁺ and carbon modification do not affect the structure of the sample but improve its kinetics in terms of discharge capacity and rate capability. The Li_0.99Nd_0.01FePO₄/C powder exhibited a specific initial discharge capacity of about 161 mAh g^− 1 at 0.1 C rate, as compared to 143 mAh g^− 1 of LiFePO₄/C. At a high rate of 2 C, the discharge capacity of Li_0.99Nd_0.01FePO₄/C still attained to 115 mAh g^− 1 at the end of 20 cycles. EIS results indicate that the charge transfer resistance of LiFePO₄/C decreases greatly after Nd doping.     

Stability of LiFePO4 in water and consequence on the Li battery behaviour

The stability of LiFePO₄ in water was investigated. Changes upon exposure to water can have several important implications for storage conditions of LiFePO₄, aqueous processing of LiFePO₄-based composite electrodes, and eventually for utilisation in aqueous lithium batteries. A Li₃PO₄ layer of a few nanometers thick was characterised at the LiFePO₄ grains surface after immersion in water, accompanied by an increase of Fe^III percentage in the grains. For first charge–discharge cycles in a lithium battery, no effect was observed on electrochemical performances for a sample of LiFePO₄ immersed for 24 h at a concentration of 50 g L⁻¹ without any pH modification. To limit the aging of LiFePO₄ during aqueous electrode processing, it is advised to reduce the immersion duration, to concentrate the LiFePO₄ suspensions, and not to modify the pH. In addition, since immersion in water mimics an accelerated exposure to air humidity, LiFePO₄ should be stored in a dry atmosphere. Paper presented at the 11th EuroConference on the Science and Technology of Ionics, Batz-sur-Mer, Sept. 9–15, 2007.     

Influence of surface modification by vanadium oxide and carbon on the electrochemical performance of LiFePO4/C

Surface modification with metal oxides is an efficient method to improve the performance of LiFePO₄. Carbon and V₂O₃ co-coated LiFePO₄ is synthesized by carbothermal reduction method combined with star-balling technique, and vanadium oxide is produced in situ. The structure and pattern of LiFePO₄/C modified with different amounts of vanadium oxide (0–5 mol%) were studied by X-ray diffraction, field-emission scanning electron microscopy, transmission electron microscopy, and micro-Raman spectroscopy. The electrochemical performance of material electrodes was analyzed by constant current charge–discharge and electrochemical impedance spectra (EIS). Electrochemical test results show that sample B (1.0 mol%) exhibits the best electrochemical performance, whose discharge capacity is up to 160.1, 127.2, and 88.4 mAh?g^?1 at 1, 5, and 10 °C, respectively. It indicates that V₂O₃ modification efficiently improves specific capacity and rate capability. The EIS experiment demonstrates that catalytic activity and reversibility of the cathode electrode are obviously increased by the surface modification of vanadium oxide.     

Surface modification by silver coating for improving electrochemical properties of LiFePO4

LiFePO₄ is a potential candidate for the cathode material of the lithium secondary battery. Fine particle LiFePO₄ was synthesized by the simple co-precipitation method, and aqueous coating on the LiFePO₄ was tried using silver nitrate solution in order to increase electronic conductivity. Highly dispersed silver on the particles enhances the electronic conductivity and increases the capacity. The electrochemical properties of the silver coated LiFePO₄ with the various current densities are analogous to those of highly conductive LiFePO₄. The silver coating can be a promising tool to preserve the capacity even at the high current densities.     

First-principles study on electronic structure of LiFePO4

The electronic structure and band structure of olivine LiFePO₄ and its virtually delithiated product FePO₄ are compared based on first-principles calculations. It is found that Li intercalation mainly impacts the electronic and band structures of the Fe atom. Total static energy calculations indicate that it is more difficult for lithium to transfer in LiFePO₄ than in FePO₄.     

Electrochemical performance of Mo-doped LiFePO4/C composites prepared by two-step solid-state reaction

To improve the performance of LiFePO₄, LiFe_1?x Mo _x PO₄/C (x?=?0, 0.005, 0.010, 0.015, 0.020, 0.025) cathode materials were synthesized via two-step ball milling solid-state reaction. The prepared samples were characterized by X-ray diffraction (XRD), field-emission scanning electron microscopy, cyclic voltammetry, electrochemical impedance spectra, and galvanostatic charge–discharge test. It is apparent from XRD analysis that Mo doping enlarges the interplanar distance of crystal plane parallel to [010] direction in LiFePO₄. In other words, it widens one-dimensional diffusion channels of Li⁺ along the [010] direction. The results of electrochemical test indicate that the LiFe_0.99Mo_0.01PO₄/C composite exhibits a discharge capacity of 144.8 mAh g^?1 at 1 C rate, a decreased charge transfer resistance of 162.4 Ω and better reversibility of electrode reactions. The present synthesis route is promising and practical for the preparation of LiFePO₄ materials.     

Stable cycle-life properties of Ti-doped LiFePO4 compounds synthesized by co-precipitation and normal temperature reduction method

Submicron-sized LiFePO₄ and Ti-doped LiFePO₄ cathode materials were synthesized by a reformative co-precipitation and normal temperature reduction method, for which Ti ions were added in the process of preparing precursors to pursue a kind of sufficient and homogenous doping way. ICP and XRD analyses indicate that Ti ions were sufficiently doped in LiFePO₄ and did not alter its crystal structure. It is noted that higher Ti ions doping levels are conducive to electrochemical performance of LiFePO₄, especially on the aspect of stable cycle-life at higher C rates. The sample doped with 3 at% Ti shows the most impressive cycling performance, even after 100 cycles, discharge capacity of 133 mAh g⁻¹ was obtained (102.3% of its initial value) at 1C rate, and the discharge decreased little from 124 to 120 mAh g⁻¹ (96.8% of its initial value) at 2C rate.     

Ab initio prediction for the ionic conduction of lithium in LiInSiO4 and LiInGeO4 olivine materials

In this paper, olivine-type LiInSiO₄ and LiInGeO₄ as fast ionic conductors are predicted by ab initio density functional studies. The nudged elastic band approach showed extremely small energy barrier for lithium ion hopping to neighboring sites with 0.23 eV for LiInGeO₄ and 0.36 eV for LiInSiO₄. However, formation energy for the intrinsic defects including lithium ion vacancy sites is expected to be large (more than ～1.5 eV), which suppresses ionic conductivity severely. Therefore it is expected that doping these olivine-type materials with higher valent cations may be a better option to create lithium ion vacancies.     

Revisiting lithium K and iron M₂,₃ edge superimposition: the case of lithium battery material LiFePO₄

Experimental electron energy-loss spectra are presented for FePO₄, LiFePO₄ and NaFePO₄ from 0 to 80 eV. With the help of the NaFePO₄ spectrum in the 50-80 eV range, the double peak observed in LiFePO₄ could be ascribed to the presence of Fe^II and not to the Li K edge, contrary to what was thought previously. Crystal field multiplet calculations confirm this attribution. Using VASP programme based on density functional theory, dielectric response calculations including local field effects in the Hartree approximation are then proven to properly simulate the fine structures due to the lithium K edge. By comparing absolute spectrum intensities, it is shown that the lithium K edge cannot be used to quantify lithium in such compounds. This detailed comparison between theoretical calculations and experimental spectra helps defining the relevant parameters governing intensities in the 50-80 energy range.     

Synthesis of spherical LiFePO4/C via Ni doping

Spherical LiFePO₄/C powders were synthesized by the conventional solid-state reaction method via Ni doping. Low-cost asphalt was used as both the reduction agent and the carbon source. An Ni-doped spherical LiFePO₄/C composite exhibited better electrochemical performances compared to an un-doped one. It presented an initial discharge capacity of 161 mAhg⁻¹ at 0.1 C rate (the theoretical capacity of LiFePO₄ with 5 wt% carbon is about 161 mAhg⁻¹). After 50 cycles at 0.5 C rate, its capacity remained 137 mAhg⁻¹ (100% of the initial capacity) compared to 115 mAhg⁻¹ (92% of the initial capacity) for an un-doped one. The electrochemical impedance spectroscopy analysis and cyclic voltammograms results revealed that Ni doping could decrease the resistance of LiFePO₄/C composite electrode drastically and improve its reversibility.