Preparation of Li4Ti5O12/C–C with super long high-rate cycle properties using glucose and polyurethane as double carbon sources for lithium ion batteries
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Li4Ti5O12/C–C (using glucose and polyurethane as double carbon sources) microspheres with particle sizes ranging from 200 to 300 nm were fabricated with a spray drying method, followed by a solid-state reaction. Compared with pure Li4Ti5O12 and Li4Ti5O12/C (using glucose as single carbon source), Li4Ti5O12/C–C exhibits higher rate performance and better cycling properties. The initial discharge capacity of Li4Ti5O12/C–C can reach 152.6 mA h g−1 at 5.0 C, which is much higher than the discharge capacity of pure Li4Ti5O12 (124.7 mA h g−1) and Li4Ti5O12/C (141 mA h g−1). Li4Ti5O12/C–C delivers a reversible capacity of 152.1 mA h g−1 (99.7% of capacity retention) during a cycle test at 5.0 C (400 cycles). This capacity is much higher than that of pure Li4Ti5O12 (118.5 mA h g−1, 95.1%) and Li4Ti5O12/C (140 mA h g−1, 99.3%). What is more gratifying is that the discharge capacity of Li4Ti5O12/C–C is still 131 mA h g−1 after another 1600 cycles, and the Coulombic efficiency remains close to 100%, indicating the crystal structure remains stable. These excellent electrochemical properties are attributed to the different carbon content and contribution from the double carbon source coating, which increases electronic conductivity, the diffusion coefficient of lithium ions, and the effective polarization reduction.
In our work, Li4Ti5O12/C–C exhibits excellent rate capacity and super long high-rate cycle properties by improving lithium ion diffusion coefficient (DLi) and reducing the charge transfer resistance (Rct) which comes from the higher carbon content and double carbon sources.
KeywordsDouble carbon sources Lithium-ion batteries Li4Ti5O12 Polarization Super long high-rate cycle properties
This work was financially supported by National Natural Science Foundation of China (Grant No. 51641206), Shandong Natural Science Foundation Project (Grant No. ZR2015EM013) and Special funds for independent innovation and transformation of achievements in Shandong Province (Grant No. 2014CGZ H0911).
- 17.Wang P, Zhang G, Cheng J, You Y, Li YK, Ding C, Gu JJ, Zheng XS, Zhang CF, Cao FF (2017) Facile Synthesis of carbon-coated spinel Li4Ti5O12/rutile-TiO2 composites as an improved anode material in full lithium-ion batteries with LiFePO4@N-doped carbon cathode. ACS Appl Mater Interfaces 9(7):6138–6143CrossRefGoogle Scholar
- 32.Meng T, Yi FY, Cheng HH, Hao JN, Shu D, Zhao SX, He C, Song XN, Zhang F (2017) Preparation of lithium titanate/reduced graphene oxide composites with three-dimensional “fishnet-like” conductive structure via a gas-foaming method for high-rate lithium-ion batteries. ACS Appl Mater Interfaces 9(49):42883–42892CrossRefGoogle Scholar
- 47.Sheng YP, Fell CR, Son YK, Metz BZ, Jiang JW, Church BC (2014) Effect of calendering on electrode wettability in lithium-ion batteries. Front Energy Res 2(56):1–8Google Scholar