Recent advances in hierarchical anode designs of <scp>TiO<sub>2</sub>‐B</scp> nanostructures for lithium‐ion batteries

Pham, Tuyet Nhung; Bui, Vu Khac Hoang; Lee, Young-Chul

doi:10.1002/er.6956

Cited by 19 publications

(7 citation statements)

References 192 publications

(418 reference statements)

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“…These observations also implied that the surface distortion of TIO180_12 was more common, resulting in faster Li diffusion. 18 Nevertheless, the differences in D Li from each material were not significantly distinctive and has not influenced much during cycle performance tests.…”

Section: Electrochemical Measurementmentioning

confidence: 85%

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Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

et al. 2023

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Bronze phase titanium dioxide (TiO 2 (B)) nanorods were successfully prepared via a hydrothermal method together with an ion exchange process and calcination by using anatase titanium dioxide precursors in the alkali hydrothermal system. TiO 2 precursors promoted the elongation of nanorod morphology. The different hydrothermal temperatures and reaction times demonstrated that the synthesis parameters had a significant influence on phase formation and physical morphologies during the fabrication process. The effects of the synthesis conditions on the tailoring of the crystal morphology were discussed. The growth direction of the TiO 2 (B) nanorods was investigated by X-ray diffractometry (XRD) and scanning electron microscopy (SEM). The as-synthesized TiO 2 (B) nanorods obtained after calcination were used as anode materials and tested the efficiency of Li-ion batteries. This research will study the effects of particle morphologies and crystallinity of TiO 2 (B) derived from a modified hydrothermal method on the capacity and charging rate of the Li-ion battery. The TiO 2 (B) nanorods, which were synthesized by using a hydrothermal temperature of 220 °C for 12 h, presented excellent electrochemical performance with the highest Li storage capacity (348.8 mAh/g for 100 cycles at a current density of 100 mA/g) and excellent high-rate cycling capability (a specific capacity of 207.3 mAh/g for 1000 cycles at a rate of 5000 mA/g).

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Section: Electrochemical Measurementmentioning

confidence: 85%

“…), were compared with TiO 2 (B) in the literature, as illustrated in Table S1. It was found that carbon-based materials have a specific capacity close to TiO 2 (B) (theoretical specific capacity 335 mAh/g) , including graphene, which has two faces on the 2-dimensional carbon sheets. However, graphene has some disadvantages.…”

Section: Introductionmentioning

confidence: 99%

Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

et al. 2023

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“…As an anode for lithium-ion batteries, TiO 2 has been widely studied due to its good structural and cyclic stability, long cycle life, good safety, and low cost. − The bronze phase TiO 2 (TiO 2 (B)) has the highest theoretical capacity since it has the lowest density among TiO 2 polycrystals. − Moreover, it has been reported that the magnesium borohydride/tetraglyme electrolyte, , PhMgCl-AlCl 3 + LiCl/THF electrolyte and an all-phenyl complex/THF electrolyte , can be matched with TiO 2 and a Mg-metal electrode, although the options are limited. However, because of the poor mobility of Mg 2+ and the low conductivity of TiO 2 due to the wide band gap (about 3.2 eV), , experiments show that TiO 2 (B) is difficult to be inserted by Mg ions and exhibits low circulation capacity. ,, In addition, TiO 2 (B) has also been reported that when it is used as MIB electrode, it is mainly based on a pseudo capacitive reaction of surface storage, which does not involve the dis/insertion of ions within the host material and shows 110 mAh g –1 at the 0.1C rate. , Therefore, it is necessary to discuss whether the existing modification means can make TiO 2 a reversible MIB electrode by enhancing its performance.…”

Section: Introductionmentioning

confidence: 99%

Effect of Oxygen Vacancies and F-Doping on TiO₂(B) as Anode for Mg-Ion Batteries

Wang

et al. 2023

J. Phys. Chem. C

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To find alternatives to lithium-ion batteries, much effort is being devoted to finding electrode materials that allow reversible Mg2+ disinsertion/insertion. Due to the strong Coulomb force between Mg2+ and electrode materials, certain modification methods are often needed to reduce the energy barrier of Mg jumping in materials. The bronze-phase TiO2(B) has attracted considerable attention as a promising anode for lithium-ion batteries, but it has proven to be difficult for Mg to insert therein. The PBE+U calculations show that the low capacity of perfect TiO2 as the anode of magnesium-ion batteries (MIB) is mainly due to the high diffusion energy barrier of the Mg ion (at least 1.27 eV). Both the defects of oxygen vacancies and F-doping can significantly reduce the band gap value and the Mg-ion migration barriers. The results of CM5 charges and charge density differences prove that the local lattice distortion caused by oxygen vacancies can cause the distribution of Ti3+ away from Mg, resulting in a significant decrease in the Mg–O binding energy, which is beneficial to the reduction of the migration barrier. F-doping can make the binding energy of Mg at each site tend to be the same, so that the energy barrier of Mg jumping along the way is lower. In addition, the coexistence of oxygen vacancy and F doping in TiO2(B) has synergistic effects in improving Mg-ion diffusion.

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“…[8] Since the discovery of photochemical water splitting using titania (TiO 2 ) electrode in 1972, [13] this environmentally benign, cost-effective oxide has become the most used semiconducting material as photocatalyst. [14] Due to its surface, electronic and photocatalytic properties it has been used in the fields of photochemical dye degradation [15] , fuel cell [16] , lithium ion batteries [17] and biosensors [18] . In the current study, the anatase form of TiO 2 has been preferred over its other polymorphs because of its highest electron mobility.…”

Section: Introductionmentioning

confidence: 99%

A Nanohybrid Containing Cyan‐Emitting Copper Nanoclusters and TiO₂ Nanoparticles: Tuning of Optoelectronic Properties

et al. 2022

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Nanohybrid materials are designed to cover up the weaknesses of individual components. In this current work, an environment‐friendly synthesis was used to produce a cyan‐emitting copper nanocluster (Cu NC) with a quantum yield of 8.7 %. This negatively charged nanocluster was successfully used to make a nanohybrid with anatase titanium dioxide mesoporous nanoparticles having Lewis‐acidic pores. The nanohybrid formation was characterized by time‐correlated single‐photon counting studies (TCSPC), solid‐state UV‐visible absorption spectroscopy and valence band X‐ray photoelectron spectroscopy. A systematic increase of Cu NC loading on the TiO2 showed an increase of current from a range of 10−7 A (in native TiO2) to 10−4 A (1 : 10 Cu NC‐TiO2 hybrid). Interestingly, the photocurrent response of TiO2 also dramatically improved from 8.9×10−3 mA to 4.1 mA in1 : 10 Cu NC−TiO2 hybrid. Systematic variation of their weight ratio vividly demonstrated that 10 % w/w TiO2−Cu NC hybrid was the most effective current generator, keeping the semiconducting and photovoltaic nature intact. The increase in photocurrent can be attributed to the long‐lived electron‐hole separation in the nanohybrid system.

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Recent advances in hierarchical anode designs of TiO₂‐B nanostructures for lithium‐ion batteries

Cited by 19 publications

References 192 publications

Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

Effect of Oxygen Vacancies and F-Doping on TiO₂(B) as Anode for Mg-Ion Batteries

A Nanohybrid Containing Cyan‐Emitting Copper Nanoclusters and TiO₂ Nanoparticles: Tuning of Optoelectronic Properties

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Recent advances in hierarchical anode designs of TiO2‐B nanostructures for lithium‐ion batteries

Cited by 19 publications

References 192 publications

Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

Development of Bronze Phase Titanium Dioxide Nanorods for Use as Fast-Charging Anode Materials in Lithium-Ion Batteries

Effect of Oxygen Vacancies and F-Doping on TiO2(B) as Anode for Mg-Ion Batteries

A Nanohybrid Containing Cyan‐Emitting Copper Nanoclusters and TiO2 Nanoparticles: Tuning of Optoelectronic Properties

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Recent advances in hierarchical anode designs of TiO₂‐B nanostructures for lithium‐ion batteries

Effect of Oxygen Vacancies and F-Doping on TiO₂(B) as Anode for Mg-Ion Batteries

A Nanohybrid Containing Cyan‐Emitting Copper Nanoclusters and TiO₂ Nanoparticles: Tuning of Optoelectronic Properties