Impact of the Specific Surface Area on the Memory Effect in Li‐Ion Batteries: The Case of Anatase TiO<sub>2</sub>

Madej, Edyta; Mantia, Fabio La; Schuhmann, Wolfgang; Ventosa, Edgar

doi:10.1002/aenm.201400829

Cited by 39 publications

(82 citation statements)

References 11 publications

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“…In the memory cycle, the regions with poor diffusion will increase the charge-transfer overpotential in comparison to completely delithiated particles, explaining the observed memory effect. The phase-field simulations show that the charge-transfer overpotential strongly depends on the applied C rate and the surface to volume ratio, explaining the experimental observations [76] of a larger memory effect at high C rates and with smaller surface to volume ratios.…”

Section: Discussionsupporting

confidence: 60%

“…Experimentally, similar observations are reported upon increasing the surface area [74][75][76]. However, higher surface areas are usually achieved by reducing the particle size [74,75], which has a similar impact on the voltage profiles, as shown in Fig.…”

Section: Impact Of Surface Areasupporting

confidence: 68%

“…The strongly concentration-dependent Li diffusion provides an explanation of the memory effect observed for anatase electrodes [76], which presents itself through a decrease in the voltage in the charge cycle (lithiation) following upon an incomplete charge/discharge cycle. The memory effect is caused by particles that are not completely delithiated before they are lithiating again, and thus more regions with poor diffusivity will remain in comparison to a complete charge/discharge cycle.…”

Section: Discussionmentioning

confidence: 99%

“…This leads to larger capacities, as has been demonstrated by various experimental studies on high surface area anatase particles [74][75][76]. To capture the surface area effect simulations were performed on a spherical and a cylindrical particle (infinitely long, i.e., neglecting the top and bottom surface of the cylinder).…”

Section: Impact Of Surface Areamentioning

confidence: 99%

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Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Klerk

Vasileiadis

Smith

et al. 2017

Phys. Rev. Materials

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The improvement of Li-ion battery performance requires development of models that capture the essential physics and chemistry in Li-ion battery electrode materials. Phase-field modeling has recently been shown to have this ability, providing new opportunities to gain understanding of these complex systems. In this paper, a novel electrochemical phase-field model is presented that captures the thermodynamic and kinetic properties of lithium insertion in TiO 2 -anatase, a well-known and intensively studied Li-ion battery electrode material. Using a linear combination of two regular solution models, the two phase transitions during lithiation are described as lithiation of two separate lattices with different physical properties. Previous elaborate experimental work on lithiated anatase TiO 2 provides all parameters necessary for the phase-field simulations, giving the opportunity to gain fundamental insight in the lithiation of anatase and validate this phase-field model. The phase-field model captures the essential experimentally observed phenomena, rationalizing the impact of C rate, particle size, surface area, and the memory effect on the performance of anatase as a Li-ion battery electrode. Thereby a comprehensive physical picture of the lithiation of anatase TiO 2 is provided. The results of the simulations demonstrate that the performance of anatase is limited by the formation of the poor Li-ion diffusion in the Li 1 TiO 2 phase at the surface of the particles. Unlike other electrode materials, the kinetic limitations of individual anatase particles limit the performance of full electrodes. Hence, rather than improving the ionic and electronic network in electrodes, improving the performance of anatase TiO 2 electrodes requires preventing the formation of a blocking Li 1 TiO 2 phase at the surface of particles. Additionally, the qualitative agreement of the phase-field model, containing only parameters from literature, with a broad spectrum of experiments demonstrates the capabilities of phase-field models for understanding Li-ion electrode materials, and its promise for guiding the design of electrodes through a thorough understanding of material properties and their interactions.

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Section: Discussionsupporting

confidence: 60%

Section: Impact Of Surface Areasupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Impact Of Surface Areamentioning

confidence: 99%

See 2 more Smart Citations

Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Klerk

Vasileiadis

Smith

et al. 2017

Phys. Rev. Materials

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“…85 Other studies on anatase TiO 2 nanoparticles, investigating various samples with different crystallite sizes, confirm these findings, which may be explained considering the following points. 29,30,55,82,87 First, the extension of the sloped low potential region might partially originate from the presence of amorphous TiO 2 , for which generally no voltage plateau is observed. 84,88 Second, the formation of the poorly ionically conductive Li 1 TiO 2 phase at the particles surface is much more pronounced for smaller particles, which are intrinsically characterized by a higher surface area, thus hindering further lithium insertion.…”

Section: Resultsmentioning

confidence: 99%

Carbon-Coated Anatase TiO₂Nanotubes for Li- and Na-Ion Anodes

Bresser

Oschmann

Tahir

et al. 2014

J. Electrochem. Soc.

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Carbon-coated, anatase titanium dioxide nanotubes were prepared by carbonizing a polyacrylonitrile-based block copolymer grafted on the as-synthesized titanate nanotubes. As revealed by high resolution transmission electron microscopy (HRTEM) and electron energy loss spectroscopy (EELS), this approach results in a very homogeneous and thin carbon coating, which is advantageous for those active materials storing lithium without undergoing significant volume changes upon ion (de-)insertion. As a matter of fact, thus prepared carbon-coated TiO 2 nanotubes presented an excellent long-term cycling stability for more than 500 cycles (0.02% capacity fading per cycle) and a very promising high rate performance (about 130 and 110 mAh g −1 at 10 C and 15 C, respectively). The influence of the tubular morphology on the rate performance is briefly discussed by comparing carbon-coated nanotubes and nanorods. Finally, the carbon-coated nanotubes were also investigated as sodium-ion anode material, showing very promising reversible capacities of around 170, 120, and 100 mAh g −1 at C/10, 1 C, and 2 C, respectively, rendering them as versatile anode material for lithium-and sodium-ion applications © The Author Efficient energy storage, prospected to pave the way for a fully electrified transportation system and the complete energy supply by renewables, is probably one of the major challenges modern society faces.1-3 Lithium-ion batteries and, very recently, sodium-ion batteries are considered as two of the most promising energy storage technologies to achieve these highly desired targets. However, further improvements in terms of energy density, rate capability, and safety are needed to make these devices finally suitable for such large-scale applications.4-14 With respect to stationary energy storage applications, for which weight and volume of the battery are not a real issue while long-term cycling stability, rate performance, and safety are of major importance, in particular, titanium-based materials are considered as highly promising candidates to replace the state-of-theart lithium-ion anode material graphite.15-18 Among these, anatase TiO 2 is certainly of special interest due to its natural abundance, low cost, environmental friendliness, non-toxicity, and large-scale availability.19-21 Additionally, it offers a rather large theoretical specific capacity of 335 mAh g −1 , corresponding to the reversible uptake and release of one lithium or sodium per formula unit of TiO 2 . The practical limit for micro-sized particles, however, is 0.5 lithium per TiO 2 unit (corresponding to a specific capacity of about 168 mAh g −1 ), due to diffusion limitation in the solid phase.22-25 Substantial improvements were realized in recent years by nanostructuring the primary particles [26][27][28][29][30] and the application of carbonaceous coatings 31-42 and matrices, [43][44][45] resulting commonly in enhanced rate capabilities, cycling stability, and increased specific capacities.46-48 One-dimensional nanostructures, such as nanowires,...

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Intelligente elektrochemische Rasterzellmikroskopie für den Nachweis schneller Li‐Ionen‐Speicherung und Dynamik in TiO₂‐Nanopartikeln

Tetteh

Valavanis²,

Daviddi³

et al. 2023

Angewandte Chemie

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Anatas-TiO2 ist ein vielversprechendes Material für Li-Ionen-Batterien (Li + ) mit Schnellladefähigkeit. Die (De-)Interkalationsdynamik von Li + in TiO 2 ist jedoch nach wie vor schwer fassbar, und die beschriebenen Diffusivitäten überspannen viele Größenordnungen. Wir entwickeln ein intelligentes Protokoll für die rasterelektrochemische Zellmikroskopie (SECCM) in Kombination mit in situ optischer Mikroskopie (OM), um die Lade-/Entladeanalyse einzelner TiO 2 -Nanopartikel-Cluster mit hohem Durchsatz zu beobachten. Die direkte Untersuchung aktiver Nanopartikel ergab, dass TiO 2 mit einer Größe von ca. 50 nm mehr als 30 % der theoretischen Kapazität bei einer äußerst schnellen Lade-/Entladerate von ca. 100 C speichern kann. Dieser Nachweis einer schnellen Li + -Speicherung in TiO 2 -Partikeln stärkt ihr Potenzial für schnell ladende Batterien. Die hier vorgeschlagene SECCM-OM ist generell für das elektrochemische Hochdurchsatz-Screening von nanostrukturierten Materialien breit anwendbar.

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Impact of the Specific Surface Area on the Memory Effect in Li‐Ion Batteries: The Case of Anatase TiO₂

Cited by 39 publications

References 11 publications

Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Carbon-Coated Anatase TiO₂Nanotubes for Li- and Na-Ion Anodes

Intelligente elektrochemische Rasterzellmikroskopie für den Nachweis schneller Li‐Ionen‐Speicherung und Dynamik in TiO₂‐Nanopartikeln

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Impact of the Specific Surface Area on the Memory Effect in Li‐Ion Batteries: The Case of Anatase TiO2

Cited by 39 publications

References 11 publications

Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Explaining key properties of lithiation in TiO2 -anatase Li-ion battery electrodes using phase-field modeling

Carbon-Coated Anatase TiO2Nanotubes for Li- and Na-Ion Anodes

Intelligente elektrochemische Rasterzellmikroskopie für den Nachweis schneller Li‐Ionen‐Speicherung und Dynamik in TiO2‐Nanopartikeln

Contact Info

Product

Resources

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Impact of the Specific Surface Area on the Memory Effect in Li‐Ion Batteries: The Case of Anatase TiO₂

Carbon-Coated Anatase TiO₂Nanotubes for Li- and Na-Ion Anodes

Intelligente elektrochemische Rasterzellmikroskopie für den Nachweis schneller Li‐Ionen‐Speicherung und Dynamik in TiO₂‐Nanopartikeln