LiCoO[sub 2] Cathode Material That Does Not Show a Phase Transition from Hexagonal to Monoclinic Phase

Cho, Jaephil; Kim, Yong Jeong; Park, Byungwoo

doi:10.1149/1.1397772

Cited by 230 publications

(157 citation statements)

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“…However, the origin responsible for the increased performance is not well understood. Understanding the mechanism responsible for the enhancement in cycling stability provided by the coatings/surface modification is essential to further stabilize positive electrode materials for applications that demand high cycle life such as electrical vehicles and stationary storage.Enhanced performance in cycling associated with surface coating has been attributed to phase transitions, 3,4,[12][13][14][15] The recent investigation by Dahèron et al,18 showed that the substitution of Al for Co not only increases the ionic nature of the Co-O bond through orbital mixing, but also that the substitution reduces the basicity of the LiCoO 2 surface, thus making the surface less receptive or vulnerable to acidic attack in the electrolyte. However, this benefit can be temporary as recent work indicates that the Li-Al-Co-O surface region is consumed during cycling.…”

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confidence: 99%

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

Quinlan

Kwabi

et al. 2015

J. Electrochem. Soc.

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The "AlPO 4 " coating has been shown to improve the electrochemical performance of LiCoO 2 batteries. We previously showed that the "AlPO 4 " coating promotes the formation of metal fluorides, which could act as a stable surface film and protect LiCoO 2 from continuous degradation upon cycling. In this work, we removed the fluorine source in the LiPF 6 salt by using the LiClO 4 salt and investigated the effectiveness of the "AlPO 4 " coating. Interestingly, the "AlPO 4 " coating was found to improve the voltage efficiency and capacity retention when cycling in the LiPF 6 electrolyte, but was detrimental when cycling in the LiClO 4 electrolyte. XPS revealed that the "AlPO 4 " coating promotes the formation of metal fluoride in both electrolytes, with the surface film formed in LiClO 4 being more electrically resistive compared to that formed in LiPF 6 . The source of fluorine in the coated electrode cycled in LiPF 6 is largely attributed to the LiPF 6 salt whereas the source of fluorine in the coated electrode cycled in LiClO 4 is the binder PVDF. We believe that the coating could react with HF impurity in the LiPF 6 electrolyte or from the binder PVDF and form stable metal fluoride films on the surface. Lithium cobalt oxide, LiCoO 2 , is currently the most common cathode material used in lithium ion battery technology, 1,2 but only half of the theoretical capacity, ≈140 mA h g −1 , is obtained when charged to 4.2 V vs. Li + /Li. Higher capacity is obtainable if cycled to voltages greater than 4.2 V, but this was shown to result in high capacity loss.3,4 Structural instability 3,5 and reactivity of the cathode with the electrolyte 3 have both been proposed as possible mechanisms for the observed capacity fade. Surface modification via coatings with intrinsic materials by thermal treatment during the synthesis process 6 or with extrinsic materials, 7-10 is one successful method of improving performance. These cathodes with surface-modified LiCoO 2 1,2,6-11 have shown improvement when cycled to high voltages compared to bare LiCoO 2 positive electrodes. However, the origin responsible for the increased performance is not well understood. Understanding the mechanism responsible for the enhancement in cycling stability provided by the coatings/surface modification is essential to further stabilize positive electrode materials for applications that demand high cycle life such as electrical vehicles and stationary storage.Enhanced performance in cycling associated with surface coating has been attributed to phase transitions, 3,4,[12][13][14][15] The recent investigation by Dahèron et al.,18 showed that the substitution of Al for Co not only increases the ionic nature of the Co-O bond through orbital mixing, but also that the substitution reduces the basicity of the LiCoO 2 surface, thus making the surface less receptive or vulnerable to acidic attack in the electrolyte. However, this benefit can be temporary as recent work indicates that the Li-Al-Co-O surface region is consumed during cycling. 27 The "AlPO 4 "-coati...

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confidence: 99%

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

Quinlan

Kwabi

et al. 2015

J. Electrochem. Soc.

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“…It was shown by many that the cycle life of LiCoO 2 at higher voltages (i.e., >4.2 V) can be improved by metal oxide coatings such as Al 2 O 3 , SnO 2 , ZrO 2 , TiO 2 , MgO, [34,[38][39][40][41][42], metal phosphate coatings such as AlPO 4 [43][44][45][46], metal fluoride coatings such as AlF 3 and LaF 3 [47,48] and multicomponent metal fluoride coatings such as aluminum-tungsten-fluoride (AlW x F y ) [49]. Although the underlying reasons for such an improvement in cycle life of LiCoO 2 at higher cut-off voltages due to coatings are still debatable [35,50,51], following mechanisms have been suggested: coating (i) inhibits the structural transformation [34,52], (ii) acts as a physical barrier, Figure 9, between the electrolyte and the active material, and prevents the trace amounts of hydrogen fluoride (HF) and water present in the electrolyte from reaching the active material thus effectively suppresses cobalt dissolution and the associated oxygen evolution [53,54], (iii) converts Lewis acids which in return corrode the insulating surface species and improves the electronic conductivity of the solid electrolyte interface (SEI) layer on LiCoO 2 [50]. Appl.…”

Section: Cathodementioning

confidence: 99%

A Review on Nanocomposite Materials for Rechargeable Li-ion Batteries

2017

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Li-ion batteries are the key enabling technology in portable electronics applications, and such batteries are also getting a foothold in mobile platforms and stationary energy storage technologies recently. To accelerate the penetration of Li-ion batteries in these markets, safety, cost, cycle life, energy density and rate capability of the Li-ion batteries should be improved. The Li-ion batteries in use today take advantage of the composite materials already. For instance, cathode, anode and separator are all composite materials. However, there is still plenty of room for advancing the Li-ion batteries by utilizing nanocomposite materials. By manipulating the Li-ion battery materials at the nanoscale, it is possible to achieve unprecedented improvement in the material properties. After presenting the current status and the operating principles of the Li-ion batteries briefly, this review discusses the recent developments in nanocomposite materials for cathode, anode, binder and separator components of the Li-ion batteries.

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“…The realized capacity of the LiCoO 2 based electrode may be increased by charging beyond 4.2 V, but must also avoid the associated structural change that occurs at higher voltages. This has been achieved by encapsulating LiCoO 2 particles with stable ceramic compounds such as TiO 2 , Al 2 O 3 , and ZrO 2 [4][5][6][7][8], and by novel surface modification techniques [4]. An additional advantage of this technique is related to a "barrier effect" that occurs by the formation of an outer shell, which shields the active LiCoO 2 core from the electrolyte and inhibits detrimental side reactions.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and improved electrochemical performance of LiCo_1‐xSn_xO₂ (x= 0 to 0.1) powders

Valanarasu¹,

Chandramohan

2010

Cryst. Res. Technol.

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Layered intercalation compounds LiCo 1-x Sn x O 2 (x= 0 to 0.1) have been prepared using a simple combustion route method. X-ray diffraction patterns and Laser Raman spectrum suggest that the synthesized materials had the R-3m structure. Scanning electron images show that particles are well-crystallized with a size distribution in the range of 50-100 nm. The room temperature electrical conductivity of the sample increased with Sn content. For LiCo 1-x Sn x O 2 (x = 0, 0.01, 0.03, 0.05 and 0.1), the first discharge capacity increased with increase in Sn content. Among these samples, LiCo 0.95 Sn 0.05 O 2 had produced the best performance of all others with a stable reversible capacity of 186 mAhg -1 after 30 cycles.

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LiCoO[sub 2] Cathode Material That Does Not Show a Phase Transition from Hexagonal to Monoclinic Phase

Cited by 230 publications

References 13 publications

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

A Review on Nanocomposite Materials for Rechargeable Li-ion Batteries

Synthesis and improved electrochemical performance of LiCo_1‐xSn_xO₂ (x= 0 to 0.1) powders

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LiCoO[sub 2] Cathode Material That Does Not Show a Phase Transition from Hexagonal to Monoclinic Phase

Cited by 230 publications

References 13 publications

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO2and “AlPO4”-Coated LiCoO2Composite Electrodes

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO2and “AlPO4”-Coated LiCoO2Composite Electrodes

A Review on Nanocomposite Materials for Rechargeable Li-ion Batteries

Synthesis and improved electrochemical performance of LiCo1‐xSnxO2 (x= 0 to 0.1) powders

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XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

XPS Investigation of the Electrolyte Induced Stabilization of LiCoO₂and “AlPO₄”-Coated LiCoO₂Composite Electrodes

Synthesis and improved electrochemical performance of LiCo_1‐xSn_xO₂ (x= 0 to 0.1) powders