In order to improve the poor electronic conductivity, the bare Li

In order to improve the poor electronic conductivity, the bare Li2NiTiO4 nanoparticles are carbon-coated by simple ball milling with conductive carbon. The carbon content in the Li2NiTiO4/C composite is 19.8 wt.%. The TEM image of Figure 2b demonstrates that the Li2NiTiO4 nanoparticles are in close contact with the dispersed carbon particles. Thus, the active material particles are interconnected

by a carbon network, Tideglusib manufacturer which is favorable for fast electron transfer and lithium extraction/insertion kinetics. Figure 2 SEM image of Li 2 NiTiO 4 (a) and TEM image of Li 2 NiTiO 4 /C (b). The valence variations of Ni element in the Li2NiTiO4 electrode during cycling are analyzed by the XPS spectra and fitted in Figure 3. The characteristic binding energy located at 854.6 eV with a satellite peak at 860.5 eV in

the Ni 2p3/2 XPS spectrum for uncharged Li2NiTiO4 electrode could be assigned to Ni2+ species. The above observations are in agreement with the reported values in LiNi0.5Mn0.5O2, LiNi1/3Mn1/3Co1/3O2 and LiNi0.5Mn1.5O4[12–14]. The Ni 2p3/2 binding energy gives positive shift when the electrode is charged to 4.9 V, and the two peaks at 855.5 and 856.9 eV are corresponding to the binding energy of Ni3+ and Ni4+[15], respectively. When discharged to 2.4 V, the Ni 2p3/2 binding energy moves back to almost the original position. The best fit for the Ni 2p3/2 spectrum consists of a major peak at 854.6 eV and a less prominent one at 855.5 eV. The above BTK inhibitor purchase results ARRY-438162 purchase indicate that Ni2+ is oxidized to Ni3+ and Ni4+ during charging, Cediranib (AZD2171) and most of the high valence Ni3+/4+ is reduced to Ni2+ in the discharge process. Figure 3 XPS spectra of Ni

2p 3/2 at different charge-discharge state. Figure 4 exhibits the CV curves of the Li2NiTiO4/C nanocomposite. For the first CV curve, a sharp oxidation peak at 4.15 V corresponds to the oxidation of Ni2+ to Ni3+/Ni4+. Another oxidation peak appears around 4.79 V and almost disappears in the second and third cycles, which might be attributed to the electrolyte decomposition and the irreversible structure transitions [8, 9]. The wide reduction peak at 3.85 V is assigned to the conversion from Ni3+/Ni4+ to Ni2+. The second and third CV curves are similar, indicating a good electrochemical reversibility of the Li2NiTiO4/C electrode. Figure 4 CV curves of the Li 2 NiTiO 4 /C nanocomposite. Figure 5a shows the galvanostatic charge-discharge curves of the Li2NiTiO4/C nanocomposite at 0.05 C rate (14.5 mA g-1) under room temperature. The charge/discharge capacities in the first, second, and third cycles are 180/115 mAh g-1, 128/111 mAh g-1, and 117/109 mAh g-1, respectively, with corresponding coulombic efficiencies of 64%, 87%, and 94%. The Li2NiTiO4/C exhibits superior electrochemical reversibility after the first cycle, which is in accordance with the CV result. The dQ/dV vs. potential plot for the first charge-discharge curve is presented in the inset in Figure 5a. Two oxidation peaks located at 4.2 and 4.

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