Electron Bottleneck in the Charge/Discharge Mechanism of Lithium Titanates for Batteries

Ventosa, Edgar; Skoumal, Marcel; Vázquez, Francisco Javier Ordiz; Flox, Cristina; Arbiol, Jordi; Morante, Joan Ramón

doi:10.1002/cssc.201500349

Cited by 21 publications

(12 citation statements)

References 32 publications

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“…Among those new developments, the semisolid flow battery (SSFB), which breaks the solubility limit of redox species by employing a flowable slurry of lithium‐ion battery (LIB) materials, presents an interesting approach to enhance the energy density. However, the high viscosity and large quantity of conducting additives engender complex fluid dynamics and reduce volumetric energy density, thereby compromising the energy efficiency and imposing challenges in scaling up the system and maintenance. Another approach that breaks the boundary for liquid and solid energy storage is redox‐targeting‐based flow batteries .…”

Section: The Marriage Of Liquid and Solid Redox Chemistrymentioning

confidence: 99%

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

2018

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Redox-targeting reactions of battery materials by redox molecules are extensively studied for energy storage since the first report in 2006. Implementation of the "redox-targeting" concept in redox flow batteries presents not only an innovative idea of battery design that considerably boosts the energy density of flow-battery system, but also an intriguing research platform applied to a wide variety of chemistries for different applications. Here, a critical overview of the recent progress in redox-targeting-based flow batteries is presented and the development of the technology in the various aspects from mechanistic understanding of the reaction kinetics to system optimization is highlighted. The limitations presently lying ahead for the widespread applications of "redox targeting" are also identified and recommendations for addressing the constraints are given. The adequate development of the redox-targeting concept should provide a credible solution for advanced large-scale energy storage in the near future.

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Section: The Marriage Of Liquid and Solid Redox Chemistrymentioning

confidence: 99%

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

2018

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“…5 However, this approach requires the use of highly conducting additives, leading to complex fluid dynamics and drop of the volumetric energy density. [6][7][8] Alternatively, Wang et al studied in 2006 the so-called redox-targeting flow battery that combines the concept of charge storage of solid batteries and the electrochemical properties of soluble redox species. 9 Typically, the insoluble solid energy storage material (LiFePO4) is stored in the electrolyte composed of a Li-salt and one or more soluble redox active molecules acting as 'redox mediators'.…”

Section: Introductionmentioning

confidence: 99%

Solid electrochemical energy storage for aqueous redox flow batteries: The case of copper hexacyanoferrate

Zanzola

Gentil

Gschwend

et al. 2019

Electrochimica Acta

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All redox flow batteries suffer from low energy storage density in comparison with conventional Li-ion batteries. However, this issue can be mitigated by utilization of solid energy storage materials to enhance the energy storage capacity. In this paper we demonstrate the utilization of copper hexacyanoferrate (CuHCF) Prussian blue analogue for this purpose, coupled with N,N,N-2,2,6,6-heptamethylpiperidinyl oxy-4-ammonium chloride (TEMPTMA) as a soluble redox mediator to target the redox transitions of the solid material. In this case, indirect charging and discharging of a solid material suspended in the electrolyte by electrochemically oxidized/reduced TEMPTMA was observed by chronoamperometry.Secondly, electrochemistry of different CuHCF composites with carbon black and multi-walled carbon nanotubes investigated, highlighting that the high conductivity of the solid energy storage materials is crucial to access the maximal charge storage capacity of the solid material.Finally, a CuHCF-TEMPTMA/Zn aqueous redox flow battery achieved stable cycling performances with high coulombic efficiency of 95% and volumetric capacity of 350 C mL -1 .

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“…[24,25] In this scenario, TiO 2 is au seful materialf or photocatalysis, [26] gas sensors, [27][28][29] Li-ion batteries, [30,31] and catalysis. [24,25] In this scenario, TiO 2 is au seful materialf or photocatalysis, [26] gas sensors, [27][28][29] Li-ion batteries, [30,31] and catalysis.…”

Section: Introductionmentioning

confidence: 99%

“…It is well-known that many metal oxidesh ave good resistance to corrosion and offer outstanding catalytic properties. [24,25] In this scenario, TiO 2 is au seful materialf or photocatalysis, [26] gas sensors, [27][28][29] Li-ion batteries, [30,31] and catalysis. [32,33] In addition, TiO 2 is wells uited to work at low pH values and shows interesting electrochemical properties as well as stability to corrosion,e specially concerning the HER.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen‐Treated Rutile TiO₂ Shell in Graphite‐Core Structure as a Negative Electrode for High‐Performance Vanadium Redox Flow Batteries

et al. 2017

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Hydrogen-treated TiO as an electrocatalyst has shown to boost the capacity of high-performance all-vanadium redox flow batteries (VRFBs) as a simple and eco-friendly strategy. The graphite felt-based GF@TiO :H electrode is able to inhibit the hydrogen evolution reaction (HER), which is a critical barrier for operating at high rate for long-term cycling in VRFBs. Significant improvements in charge/discharge and electron-transfer processes for the V /V reaction on the surface of reduced TiO were achieved as a consequence of the formation of oxygen functional groups and oxygen vacancies in the lattice structure. Key performance indicators of VRFB have been improved, such as high capability rates and electrolyte-utilization ratios (82 % at 200 mA cm ). Additionally, high coulombic efficiencies (ca. 100 % up to the 96th cycle, afterwards >97 %) were obtained, demonstrating the feasibility of achieving long-term stability.

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Electron Bottleneck in the Charge/Discharge Mechanism of Lithium Titanates for Batteries

Cited by 21 publications

References 32 publications

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

Solid electrochemical energy storage for aqueous redox flow batteries: The case of copper hexacyanoferrate

Hydrogen‐Treated Rutile TiO₂ Shell in Graphite‐Core Structure as a Negative Electrode for High‐Performance Vanadium Redox Flow Batteries

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Electron Bottleneck in the Charge/Discharge Mechanism of Lithium Titanates for Batteries

Cited by 21 publications

References 32 publications

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

Redox‐Targeting‐Based Flow Batteries for Large‐Scale Energy Storage

Solid electrochemical energy storage for aqueous redox flow batteries: The case of copper hexacyanoferrate

Hydrogen‐Treated Rutile TiO2 Shell in Graphite‐Core Structure as a Negative Electrode for High‐Performance Vanadium Redox Flow Batteries

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Product

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Hydrogen‐Treated Rutile TiO₂ Shell in Graphite‐Core Structure as a Negative Electrode for High‐Performance Vanadium Redox Flow Batteries