General Strategy for Designing Core–Shell Nanostructured Materials for High-Power Lithium Ion Batteries

Shen, Laifa; Li, Hongsen; Uchaker, Evan; Zhang, Xiaogang; Cao, Guozhong

doi:10.1021/nl302854j

Cited by 200 publications

(131 citation statements)

References 44 publications

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“…It suggests that the 10 nm amorphous layer, to some degree, forms a diffusion barrier for Li + between the electrolyte and the spinel LTO phase, which hinders the charge‐transfer process, which apparently becomes rate limiting at large currents. Although the rate performance does not achieve that of carbon‐coated LTO, nano/porous LTO, or other samples based on methods aiming at improving the conductivity,28, 29, 30, 31, 32, 33 these results demonstrate the importance of the surface quality for the performance of electrode materials, giving guidance to design and produce high‐performance materials.…”

Section: Resultsmentioning

confidence: 96%

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

et al. 2017

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Through a facile sodium sulfide (Na2S)‐assisted hydrothermal treatment, clean and nondefective surfaces are constructed on micrometer‐sized Li4Ti5O12 particles. The remarkable improvement of surface quality shows a higher first cycle Coulombic efficiency (≈95%), a significantly enhanced cycling performance, and a better rate capability in electrochemical measurements. A combined study of Raman spectroscopy and inductive coupled plasma emission spectroscopy reveals that the evolution of Li4Ti5O12 surface in a water‐based hydrothermal environment is a hydrolysis–recrystallization process, which can introduce a new phase of anatase‐TiO2. While, with a small amount of Na2S (0.004 mol L−1 at least), the spinel‐Li4Ti5O12 phase is maintained without a second phase. During this process, the alkaline environment created by Na2S and the surface adsorption of the sulfur‐containing group (HS− or S2−) can suppress the recrystallization of anatase‐TiO2 and renew the particle surfaces. This finding gives a better understanding of the surface–property relationship on Li4Ti5O12 and guidance on preparation and modification of electrode material other than coating or doping.

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Section: Resultsmentioning

confidence: 96%

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

et al. 2017

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“…As the most widely commercialized anode material, the graphite anode suffers from several disadvantages, for instance, severe irreversible lithium dendrites, poor high rate charge capability, formation of a solid electrolyte interface (SEI), and serious safety issues 3, 4, 5, 6. Thus, it cannot satisfy the increasing demand for fast energy storage and large‐scale devices which requires improvement of the battery current densities, cycling stability, safety, and low‐temperature charge properties.…”

Section: Introductionmentioning

confidence: 99%

“…For instance, metal, carbon, and graphene coating have been shown to increase the surface electronic conductivity of LTO. Nanosized LTO possesses high Li‐ion ionic conductivity, for instance, nanoparticles,3, 19 nanofibers,20, 21 nanosheets,9, 22 nanotubes,23 nanowires,24 nanoarrays,23, 24 and nanoscopic porous frameworks 25. Unfortunately, as LTO particle size decreases to the nanoscale, the specific surface area of the materials increased greatly, which significantly introduces irreversible reactions with the electrolyte solution 26, 27.…”

Section: Introductionmentioning

confidence: 99%

High‐Density Microporous Li₄Ti₅O₁₂ Microbars with Superior Rate Performance for Lithium‐Ion Batteries

Tang

Wang

et al. 2017

Advanced Science

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Nanosized Li4Ti5O12 (LTO) materials enabling high rate performance suffer from a large specific surface area and low tap density lowering the cycle life and practical energy density. Microsized LTO materials have high density which generally compromises their rate capability. Aiming at combining the favorable nano and micro size properties, a facile method to synthesize LTO microbars with micropores created by ammonium bicarbonate (NH4HCO3) as a template is presented. The compact LTO microbars are in situ grown by spinel LTO nanocrystals. The as‐prepared LTO microbars have a very small specific surface area (6.11 m2 g−1) combined with a high ionic conductivity (5.53 × 10−12 cm−2 s−1) and large tap densities (1.20 g cm−3), responsible for their exceptionally stable long‐term cyclic performance and superior rate properties. The specific capacity reaches 141.0 and 129.3 mAh g−1 at the current rate of 10 and 30 C, respectively. The capacity retention is as high as 94.0% and 83.3% after 500 and 1000 cycles at 10 C. This work demonstrates that, in situ creating micropores in microsized LTO using NH4HCO3 not only facilitates a high LTO tap density, to enhance the volumetric energy density, but also provides abundant Li‐ion transportation channels enabling high rate performance.

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“…Along these strategies, LTO has been fabricated into various nanostructures, for example, nanoparticles, 6,8,13 nanofibers/nanowires, 14,15 nanosheets 16,17 and porous networks, 7,10 or integrated with highly conductive carbons. 11,[18][19][20] Because graphene has excellent electrical conductivity, LTO/ graphene composites have received significant attention lately. Xiang et al 21 synthesized an LTO/graphene composite through a sol-gel method using lithium acetate, tetrabutyl titanate and graphene sheets; however, the capacity of as-obtained LTO/graphene decayed from 146 to 110 mAh g − 1 within 100 cycles at a 10 C rate, which may be due to the difficulties with controlling the morphology of LTO/ graphene from the sol-gel method.…”

Section: Introductionmentioning

confidence: 99%

“…[4][5][6][7][8] In addition, LTO possesses excellent Li ion insertion and removal reversibility with almost zero volume change during the charge/discharge process. 9,10 However, as demonstrated in previous studies, it is still a challenge to achieve good battery performance at high charge/discharge rates using LTO as the anode material because of the low electrical conductivity (o10 − 13 S cm − 1 ) of LTO,11,12 and thus there have been many efforts to improve the rate capability and the cycling performance of LTO-based batteries. Commonly applied strategies include engineering the proper LTO structure to reduce the transport path length of Li ions and enhancing the electrical conductivity by surface coating or forming composites with…”

mentioning

confidence: 99%

One-step, continuous synthesis of a spherical Li4Ti5O12/graphene composite as an ultra-long cycle life lithium-ion battery anode

et al. 2015

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We report, for the first time, a one-step, continuous synthesis of spherical lithium titanate (Li 4 Ti 5 O 12 , LTO)/graphene composites through direct aerosolization of a graphene oxide (GO) suspension mixed with Li and Ti precursors. The resulting crumpled graphene-sphere-supported LTO nanocrystals has a three-dimensional structure with a high electrical conductivity, a high surface area and good stability in electrolyte. The LTO/CG composite, as an anode in LIBs, exhibited excellent rate capability (for example, at a high current density of 5000 mA g − 1 it delivered 60% of the capacity obtained at 12.5 mA g − 1 ) and an outstanding cycling performance (a capacity retention of 88% after 5000 cycles at 1,250 mA g − 1 ). The one-step, continuous synthesis of the LTO/graphene composite offers a high-producing efficiency compared with conventional multi-step preparations, and can be generally applied for synthesizing lithium metal oxides/graphene (cathode or anode) materials for lithium-ion batteries. NPG Asia Materials (2015) 7, e224; doi:10.1038/am.2015.120; published online 6 November 2015 INTRODUCTION Lithium-ion batteries (LIBs) have a high-rate capacity and long cycle life, and thus are critical for many important applications, such as electric vehicles (EVs) and portable electronic devices. 1-3 The use of combustible graphite (especially in lithiated states) is highly risky in the application of EVs and hybrid EVs (HEVs); therefore, alternative anode materials with a higher power density, better stability, and higher safety performance are greatly needed and deserve greater scientific exploration.Compared with graphitic carbon, spinel lithium titanate Li 4 Ti 5 O 12 (LTO) exhibits a relatively high lithium insertion/extraction voltage of 1.55 V (vs Li + /Li), which prevents the formation of the solid electrolyte interphase (SEI) and suppresses lithium dendrite deposition on the surface of the anode (most electrolyte materials or solvents are reduced below 1 V), thereby greatly decreasing the short-circuit risk of the battery. [4][5][6][7][8] In addition, LTO possesses excellent Li ion insertion and removal reversibility with almost zero volume change during the charge/discharge process. 9,10 However, as demonstrated in previous studies, it is still a challenge to achieve good battery performance at high charge/discharge rates using LTO as the anode material because of the low electrical conductivity (o10 − 13 S cm − 1 ) of LTO,11,12 and thus there have been many efforts to improve the rate capability and the cycling performance of LTO-based batteries. Commonly applied strategies include engineering the proper LTO structure to reduce the transport path length of Li ions and enhancing the electrical conductivity by surface coating or forming composites with

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General Strategy for Designing Core–Shell Nanostructured Materials for High-Power Lithium Ion Batteries

Cited by 200 publications

References 44 publications

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

High‐Density Microporous Li₄Ti₅O₁₂ Microbars with Superior Rate Performance for Lithium‐Ion Batteries

One-step, continuous synthesis of a spherical Li4Ti5O12/graphene composite as an ultra-long cycle life lithium-ion battery anode

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General Strategy for Designing Core–Shell Nanostructured Materials for High-Power Lithium Ion Batteries

Cited by 200 publications

References 44 publications

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li4Ti5O12 in Lithium‐Ion Battery

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li4Ti5O12 in Lithium‐Ion Battery

High‐Density Microporous Li4Ti5O12 Microbars with Superior Rate Performance for Lithium‐Ion Batteries

One-step, continuous synthesis of a spherical Li4Ti5O12/graphene composite as an ultra-long cycle life lithium-ion battery anode

Contact Info

Product

Resources

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A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

A Facile Surface Reconstruction Mechanism toward Better Electrochemical Performance of Li₄Ti₅O₁₂ in Lithium‐Ion Battery

High‐Density Microporous Li₄Ti₅O₁₂ Microbars with Superior Rate Performance for Lithium‐Ion Batteries