Probing the Physicochemical Behavior of Variously Doped Li4Ti5O12Nanoflowers

Salvatore, Kenna L.; Vila, Mallory N.; Renderos, Genesis D.; Li, Wenzao; Housel, Lisa M.; Tong, Xiao; McGuire, Scott C.; Gan, Joceline; Ariadna, Paltis,; Lee, Katherine; Takeuchi, Kenneth J.; Marschilok, Amy C.; Takeuchi, Esther S.; Wong, Stanislaus S.

doi:10.1021/acsphyschemau.1c00044

Cited by 2 publications

(4 citation statements)

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“…Randles plots Z ′ vs ω –1/2 , as well as the Warburg factor (σ w , eq S5) representing the mass-controlled process, are illustrated in Figure b. The apparent chemical diffusion coefficients can be calculated according to eq D Li = R 2 T 2 2 A 2 n 4 C Li 2 σ 2 …”

Section: Resultsmentioning

confidence: 99%

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries

Lakshmi-Narayana

Dhananjaya

Julien

et al. 2023

ACS Appl. Mater. Interfaces

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A comprehensive and comparative exploration research performed, aiming to elucidate the fundamental mechanisms of rare-earth (RE) metal-ion doping into Li 4 Ti 5 O 12 (LTO), reveals the enhanced electrochemical performance of the nanocrystalline RE-LTO electrodes in high-power Li-ion batteries. Pristi ne Li 4 Ti 5 O 12 (LTO) and rare-earth metal-doped Li 4−x/3 Ti 5−2x/3 Ln x O 12 (RE-LTO with RE = Dy, Ce, Nd, Sm, and Eu; x ≈ 0.1) nanocrystalline anode materials were synthesized using a simple mechanochemical method and subsequent calcination at 850 °C. The X-ray diffraction (XRD) patterns of pristine and RE-LTO samples exhibit predominant (111) orientation along with other characteristic peaks corresponding to cubic spinel lattice. No evidence of RE-doping-induced changes was seen in the crystal structure and phase. The average crystallite size for pristine and RE-LTO samples varies in the range of 50−40 nm, confirming the formation of nanoscale crystalline materials and revealing the good efficiency of the ball-milling-assisted process adopted to synthesize nanoscale particles. Raman spectroscopic analyses of the chemical bonding indicate and further validate the phase structural quality in addition to corroborating with XRD data for the cubic spinel structure formation. Transmission electron microscopy (TEM) reveals that both pristine and RE-LTO particles have a similar cubic shape, but RE-LTO particles are better interconnected, which provide a high specific surface area for enhanced Li + -ion storage. The detailed electrochemical characterization confirms that the RE-LTO electrodes constitute promising anode materials for high-power Li-ion batteries. The RE-LTO electrodes deliver better discharge capacities (in the range of 172−198 mAh g −1 at 1C rate) than virgin LTO (168 mAh g −1 ). Among them, Eu-LTO provides the best discharge capacity of 198 mAh g −1 at a 1C rate. When cycled at a high current rate of 50C, all RE-LTO electrodes show nearly 70% of their initial discharge capacities, resulting in higher rate capability than virgin LTO (63%). The results discussed in this work unfold the fundamental mechanisms of RE doping into LTO and demonstrate the enhanced electrochemical performance derived via chemical composition tailoring in RE-LTO compounds for application in high-power Li-ion batteries.

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Section: Resultsmentioning

confidence: 99%

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries

Lakshmi-Narayana

Dhananjaya

Julien

et al. 2023

ACS Appl. Mater. Interfaces

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“…1D LTO nanomaterials are composed of nanorods [ 122 , 123 , 124 , 125 , 126 , 127 ], nanowires [ 128 , 129 , 130 , 131 , 132 ], nanofibers [ 95 , 133 , 134 , 135 , 136 , 137 , 138 , 139 , 140 ], nanotubes [ 54 , 141 ], nanoflakes [ 142 ], and nanobelts [ 143 , 144 , 145 , 146 ]. 2D LTO nanomaterials encompass nanosheets [ 136 , 147 , 148 , 149 , 150 , 151 ], nanoplates [ 152 ], and wave-like structures [ 153 ]. 3D LTO nanomaterials include nanoflowers [ 153 ], nanoporous structures [ 55 , 154 , 155 , 156 , 157 ], mesoporous structures [ 67 ], hierarchical structures [ 158 ], and nanoarrays [ 159 , 160 , 161 , 162 , 163 ,…”

Section: Synthesis Methodsmentioning

confidence: 99%

“…2D LTO nanomaterials encompass nanosheets [ 136 , 147 , 148 , 149 , 150 , 151 ], nanoplates [ 152 ], and wave-like structures [ 153 ]. 3D LTO nanomaterials include nanoflowers [ 153 ], nanoporous structures [ 55 , 154 , 155 , 156 , 157 ], mesoporous structures [ 67 ], hierarchical structures [ 158 ], and nanoarrays [ 159 , 160 , 161 , 162 , 163 , 164 , 165 , 166 , 167 , 168 , 169 ].…”

Section: Synthesis Methodsmentioning

confidence: 99%

“…2D LTO nanomaterials encompass nanosheets [136,[147][148][149][150][151], nanoplates [152], and wave-like structures [153]. 3D LTO nanomaterials include nanoflowers [153], nanoporous structures [55,[154][155][156][157], mesoporous structures [67], hierarchical structures [158], and nanoarrays [159][160][161][162][163][164][165][166][167][168][169]. Currently, the growth of LTO nano-powders is achieved by using successive techniques, which can include the synthesis of a precursor at the start and at least one calcination step at the end.…”

Section: Synthesis Methodsmentioning

confidence: 99%

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Fabrication of Li4Ti5O12 (LTO) as Anode Material for Li-Ion Batteries

Julien,

Mauger

2024

Micromachines

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The most popular anode material in commercial Li-ion batteries is still graphite. However, its low intercalation potential is close to that of lithium, which results in the dendritic growth of lithium at its surface, and the formation of a passivation film that limits the rate capability and may result in safety hazards. High-performance anodes are thus needed. In this context, lithium titanite oxide (LTO) has attracted attention as this anode material has important advantages. Due to its higher lithium intercalation potential (1.55 V vs. Li+/Li), the dendritic deposition of lithium is avoided, and the safety is increased. In addition, LTO is a zero-strain material, as the volume change upon lithiation-delithiation is negligible, which increases the cycle life of the battery. Finally, the diffusion coefficient of Li+ in LTO (2 × 10−8 cm2 s−1) is larger than in graphite, which, added to the fact that the dendritic effect is avoided, increases importantly the rate capability. The LTO anode has two drawbacks. The energy density of the cells equipped with LTO anode is lower compared with the same cells with graphite anode, because the capacity of LTO is limited to 175 mAh g−1, and because of the higher redox potential. The main drawback, however, is the low electrical conductivity (10−13 S cm−1) and ionic conductivity (10−13–10−9 cm2 s−1). Different strategies have been used to address this drawback: nano-structuration of LTO to reduce the path of Li+ ions and electrons inside LTO, ion doping, and incorporation of conductive nanomaterials. The synthesis of LTO with the appropriate structure and the optimized doping and the synthesis of composites incorporating conductive materials is thus the key to achieving high-rate capability. That is why a variety of synthesis recipes have been published on the LTO-based anodes. The progress in the synthesis of LTO-based anodes in recent years is such that LTO is now considered a substitute for graphite in lithium-ion batteries for many applications, including electric cars and energy storage to solve intermittence problems of wind mills and photovoltaic plants. In this review, we examine the different techniques performed to fabricate LTO nanostructures. Details of the synthesis recipes and their relation to electrochemical performance are reported, allowing the extraction of the most powerful synthesis processes in relation to the recent experimental results.

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Probing the Physicochemical Behavior of Variously Doped Li₄Ti₅O₁₂Nanoflowers

Cited by 2 publications

References 30 publications

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries

Fabrication of Li4Ti5O12 (LTO) as Anode Material for Li-Ion Batteries

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Probing the Physicochemical Behavior of Variously Doped Li4Ti5O12Nanoflowers

Cited by 2 publications

References 30 publications

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li4Ti5O12Electrodes in High-Power Li-Ion Batteries

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li4Ti5O12Electrodes in High-Power Li-Ion Batteries

Fabrication of Li4Ti5O12 (LTO) as Anode Material for Li-Ion Batteries

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Probing the Physicochemical Behavior of Variously Doped Li₄Ti₅O₁₂Nanoflowers

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries

Enhanced Electrochemical Performance of Rare-Earth Metal-Ion-Doped Nanocrystalline Li₄Ti₅O₁₂Electrodes in High-Power Li-Ion Batteries