The study on the effect of hydrothermal temperature on the structure and characteristics of olivine LiCoPO4 cathode materials

Mai Nguyen Thi Tuyet, Hue Dang Thi Minh, Thuy Pham Thi, Thao Le Thi Thu, Hoang Dang Huy, Tuan Hoang Ngoc, Dung Trinh Viet, Chinh Huynh Dang

Abstract


The experiment was conducted to research and fabricate single phase olivine LiCoPO4 materials with nano-meter structure by hydrothermal method at different temperatures of 190oC, 200oC and 240oC. Methods of determining the structure and characteristics of materials include: XRD, FTIR, SEM. The ion conductivity of the LiCoPOpowder materials suspension was measured on a conductivity meter (Hana Instruments HI2314). The results showed that, when the hydrothermal temperature increased from 190-240oC, the crystal formation and development gradually increased. The average crystal sizes of the samples were about 23.04 nm, 25.75 nm and 30.19 nm which were gradual increase with hydrothermal temperature. The wave vibrations in the FTIR spectra showed the bounding vibrations of the O-P-O that were of the tetrahedron PO43- and bonding vibrations of metal-O. The ionic conductivity of the olivine LiCoPO4 powder samples suspension increases when the hydrothermal temperature of samples increases of 190, 200 and 240oC. The maximum electrical conductivity was ~39.4 mS/cm obtained by olivine LiCoPO4 sample which was hydrothermal at 200oC.  

The experiment was conducted to research and fabricate single phase olivine LiCoPO4 materials with nano-meter structure by hydrothermal method at different temperatures of 190oC, 200oC and 240oC. Methods of determining the structure and characteristics of materials include: XRD, FTIR, SEM. The ion conductivity of the LiCoPO4powder materials suspension was measured on a conductivity meter (Hana Instruments HI2314). The results showed that, when the hydrothermal temperature increased from 190-240oC, the crystal formation and development gradually increased. The average crystal sizes of the samples were about 23.04 nm, 25.75 nm and 30.19 nm which were gradual increase with hydrothermal temperature. The wave vibrations in the FTIR spectra showed the bounding vibrations of the O-P-O that were of the tetrahedron PO43- and bonding vibrations of metal-O. The ionic conductivity of the olivine LiCoPO4 powder samples suspension increases when the hydrothermal temperature of samples increases of 190, 200 and 240oC. The maximum electrical conductivity was ~39.4 mS/cm obtained by olivine LiCoPO4 sample which was hydrothermal at 200oC. 


Keywords


Energy materials; cathode materials; Li-ion batteries; olivine LiCoPO4

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References


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DOI: https://doi.org/10.51316/jca.2020.032

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