Modelling of Ion Transport in Solids with a General Bond Valence Based Force-Field

Adams, Stefan; Rao, R. Prasada

doi:10.17146/aij.2010.30

Cited by 10 publications

(6 citation statements)

References 18 publications

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“…44 The potential parameters were taken from the BV Web site and related papers. 45,46 The screened Coulomb repulsions were calculated using the Wolf summation technique. 47 The simulations under the periodic boundary condition were implemented using the LAMMPS CMD package.…”

Section: Methodsmentioning

confidence: 99%

Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions

et al. 2015

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The cobalt-based fluorophosphate Li 2 CoPO 4 F positive electrode has the potential to obtain high energy density in a lithium ion battery since its theoretical capacity is 287 mAh·g −1 when two electrons can react reversibly. This material promises to charge/discharge with an extremely high redox-couple voltage of over 4.8 V vs Li/Li + . Bulk structural analyses including X-ray diffraction, Co K-edge X-ray absorption near-edge structure (XANES), and extended X-ray absorption fine structure (EXAFS) reveal that an orthorhombic Li β CoPO 4 F phase is produced from pristine Li 2 CoPO 4 F by a combination of solid-solution and two-phase reaction manners during the first charging process, and these phases reversibly transform during charge−discharge cycling. The results of 7 Li MAS NMR and classical molecular dynamics simulations suggest that Li ions located at Li(1) sites intercalate/deintercalate through a 1D diffusion path along the b axis, whereas those located at Li(2) and Li(3) sites are fixed. The aforementioned analyses were successfully performed with the enhancement of electrochemical properties by use of a fluoroethylene carbonatebased electrolyte instead of an ethylene carbonate-based one and reducing its volume. Further enhancement was achieved by adding SiO 2 nanoparticles into the electrode slurry. The electrochemical results encourage the possibility of the intercalation/ deintercalation of more than one Li ion from/into Li 2 CoPO 4 F during electrochemical cycling.

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Section: Methodsmentioning

confidence: 99%

Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions

et al. 2015

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“…It has been postulated that the lithium ion pathway is the locus of points r Li,c . 15,17 Adams and Rao 17 define the pathways as follows: "These pathways are visualized as regions enclosed by isosurfaces, ..." which in this case are the points that are enclosed in surfaces where ΔV = ΔV c . Within each pathway, the lithium ion interacts with the other ions and, in particular, the negatively charged oxygen ions, which constitute their first coordination layer.…”

Section: Theoretical Aspectsmentioning

confidence: 99%

“…To consider these near-equilibrium points in a quantitative manner, a small arbitrary cutoff or threshold values Δ V c of Δ V was selected such that any point r Li that possesses a mismatch Δ V ≤ Δ V c will be considered to be close to equilibrium. It has been postulated that the lithium ion pathway is the locus of points r Li,c . , Adams and Rao define the pathways as follows: “These pathways are visualized as regions enclosed by iso-surfaces, ...” which in this case are the points that are enclosed in surfaces where Δ V = Δ V c . Within each pathway, the lithium ion interacts with the other ions and, in particular, the negatively charged oxygen ions, which constitute their first coordination layer.…”

Section: Theoretical Aspectsmentioning

confidence: 99%

Formulation of a Statistical Mechanical Theory To Understand the Li Ion Conduction in Crystalline Electrolytes: A Case Study on Li-Stuffed Garnets

Paul

Thangadurai

2017

J. Phys. Chem. C

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Ionic conductivity in solids is being computed using a wide range of computational methods such as molecular dynamics simulations and is measured using experimental methods, including electrochemical impedance spectroscopy and dc methods, and solid-state nuclear magnetic resonance spectroscopy. We report for the first time a statistical mechanical approach to estimate Li ion conductivity in the crystalline Li-stuffed garnet-type structure

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“…It is noted that the thermal expansion is a quadratic function of the temperature for this range (before the shrinkage). This relation can be written as: 1.9 10 K − − × [6]. This low thermal expansion coefficient, compared to LiFePO 4 , is an advantage for using this material under extrem conditions.…”

Section: Figure 4(c)mentioning

confidence: 99%

“…The thermal expansion coefficient is determined for the temperature range between 30 and 150˚C at the heating rate and is equal to is 10 2 times more important compared to values often found in the literature ( )6 1…”

mentioning

confidence: 99%

Phosphorus Based Ceramics for Positive Electrode Synthesis and Characterization

Kobor

Diallo²,

Tine³

2014

JMP

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Historically, the LiCoO2 is the most used as active material for battery positive electrode because of its great potential (3.7 -4.2 V), its interesting specific capacity (150 mA•h•g −1 ) and its excellent life cycle [1]. However, its toxicity, the cobalt cost and its structural instability oriented research towards new materials more stable that can replace it. In another context, hybrid, electrical vehicles and communication (computers and mobile phones...) have increased the scientific and technological research for new materials capable of storing and return energy through a system called accumulator. And research has identified the phosphate olivine structure as the most prolific ceramic material for positive electrode. LiFePO4 is a promising cathode material for Lithium-ion batteries. It provides high thermal stability and is synthesized using low cost materials. Unfortunately LiFePO4 suffers from a low electrical conductivity, which is harmful to its electrochemical performance. Decreasing the particle size, coating the particles with carbon or doping with metal atoms can increase the conductivity of the material. In this paper, we present the synthesis, physico-chemical and electrical characterization of lithium and iron doped Al-phosphorrus-based ceramic. The NPK Fertiliser was used as Al and phosphorus precursors. The powder XRD spectrum shows a possible presence of LiFePO4 and Fe2(PO)3 in the heterostructure. An important quantity of Al is found by EDX spectra which supposed that the most important based atom is Aluminum and not Phosphorus. This can explain the increase of the conductivity value is 10 2 times more important than those found in the literature for LiFePO4.

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Modelling of Ion Transport in Solids with a General Bond Valence Based Force-Field

Cited by 10 publications

References 18 publications

Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions

Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions

Formulation of a Statistical Mechanical Theory To Understand the Li Ion Conduction in Crystalline Electrolytes: A Case Study on Li-Stuffed Garnets

Phosphorus Based Ceramics for Positive Electrode Synthesis and Characterization

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Modelling of Ion Transport in Solids with a General Bond Valence Based Force-Field

Cited by 10 publications

References 18 publications

Structural Changes in Li2CoPO4F during Lithium-Ion Battery Reactions

Structural Changes in Li2CoPO4F during Lithium-Ion Battery Reactions

Formulation of a Statistical Mechanical Theory To Understand the Li Ion Conduction in Crystalline Electrolytes: A Case Study on Li-Stuffed Garnets

Phosphorus Based Ceramics for Positive Electrode Synthesis and Characterization

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Product

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Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions

Structural Changes in Li₂CoPO₄F during Lithium-Ion Battery Reactions