Electrospun TiO₂–rGO Composite Nanofibers with Ordered Mesopores by Molecular Level Assembly: A High Performance Anode Material for Lithium‐Ion Batteries

Abstract: cycling especially on fast changing rate due to their low lithium intercalation potential (≈0.1 V vs Li/Li + ), resulting the risk of short circuit that may end up with thermal explosion. [7] Whereas, in case of TiO 2 anode materials, not only its relatively high discharge potential (≈1.7 V vs Li/Li + ) suppresses the formation of lithium dendrites but also its low volume expansion during lithiation/delithiation improves long cycling durability and inhibits the formation of solid electrode interface. [8,9] Thu… Show more

“…10 −12 − 10 −7 S/cm)) [ 66 , 83 , 84 , 85 , 86 ]. Designing one-dimensional nanostructures through the electrospinning process is considered an efficient route to overcome the diffusion issue related to the reduced lithium-ion diffusion path and a high surface-to-volume ratio [ 84 ]. Figure 7 shows the representative TiO 2 one-dimensional nanostructures.…”

“…There have been efforts to improve the electrical conductivity of the TiO 2 nanofibers. It is simple and intuitive to composite the TiO 2 nanofibers with conducting materials such as gold or silver nanoparticles [ 83 , 90 ], reduced graphene oxide (rGO) [ 66 , 84 ], and hard carbon [ 85 ]. By extension, silver paste has been used to adhere the TiO 2 active materials and current collector and to provide the electrical conducting pathway to the active materials [ 91 ], and the surfaces of the hollow TiO 2 nanofibers were nitridated to increase electrical conductivity [ 92 ].…”

A Review of Recent Advancements in Electrospun Anode Materials to Improve Rechargeable Lithium Battery Performance

“…10 −12 − 10 −7 S/cm)) [ 66 , 83 , 84 , 85 , 86 ]. Designing one-dimensional nanostructures through the electrospinning process is considered an efficient route to overcome the diffusion issue related to the reduced lithium-ion diffusion path and a high surface-to-volume ratio [ 84 ]. Figure 7 shows the representative TiO 2 one-dimensional nanostructures.…”

“…There have been efforts to improve the electrical conductivity of the TiO 2 nanofibers. It is simple and intuitive to composite the TiO 2 nanofibers with conducting materials such as gold or silver nanoparticles [ 83 , 90 ], reduced graphene oxide (rGO) [ 66 , 84 ], and hard carbon [ 85 ]. By extension, silver paste has been used to adhere the TiO 2 active materials and current collector and to provide the electrical conducting pathway to the active materials [ 91 ], and the surfaces of the hollow TiO 2 nanofibers were nitridated to increase electrical conductivity [ 92 ].…”

A Review of Recent Advancements in Electrospun Anode Materials to Improve Rechargeable Lithium Battery Performance

“…C n is the double layer capacitance on the electrode surface. They represent the ion transport across the six interphases, such as (1) the interphase between HCF and NVP, R ct1 through HCF and insertion capacity (C 1 ), (2) the interphase between NVP and the solid electrolyte interphase (SEI), R ct2 through NVP and insertion capacity (C 2 ), (3) the interphase between the electrolyte and SEI, R ct3 through SEI and insertion capacity (C 3 ), (4) the interphase between the electrolyte and SEI, R ct4 through SEI and insertion capacity (C 4 ), (5) the interphase between the SEI and GN/SiC, R ct5 through GN/SiC and insertion capacity (C 5 ), and (6) the interphase between GN/SiC and HCF, R ct6 through HCF and insertion capacity (C 6 ). According to the Nyquist plots in Fig.…”

“…Developing new and low-cost technologies in environmentally friendly energy storage systems is a life-time goal for researchers. [1][2][3][4][5] With the rapidly increasing demand for versatile energy storage devices, great interest has been aroused in exible/bendable electronic equipment, such as rollup displays, wearable and portable electronic devices and implantable biomedical products. [6][7][8] Nevertheless, exible rechargeable batteries still suffer from the lack of advanced electrodes with high energy density, high reversible capacities, fast chargedischarge rates and a long lifespan.…”

Rational design and kinetics study of flexible sodium-ion full batteries based on binder-free composite film electrodes

“…At present, graphite is widely used as the anode material of LIBs, however, its low theoretical specific capacity (372 mA h g −1 ) and sluggish kinetics for Li + insertion/extraction seriously limit the further application of LIBs in high‐energy and high‐power devices . Under these circumstances, transition metal oxides are attracting significant attention due to their high capacity, low cost, and environmental friendliness . In particular, molybdenum dioxide (MoO 2 ) stands out among numerous potential candidates because of its high theoretical capacity of 838 mA h g −1 and low electrical resistivity .…”

Strongly Surface‐Bonded MoO₂@Carbon Nanocomposites by Nitrogen‐Doping with Outstanding Capability for Fast and Stable Li Storage