First-Principles Calculations of Migration Energy of Lithium Ions in Halides and Chalcogenides

Kishida, Ippei; Koyama, Yukinori; Kuwabara, Akihide; Yamamoto, Tomoko; Oba, Fumiyasu; Tanaka, Isao

doi:10.1021/jp0559229

Cited by 28 publications

(25 citation statements)

References 22 publications

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“…Then, the value of energy barrier of the diffusion path increases on going from the first to the second stage of path 1a. These remarks are similar to those employed in the Li mobility in Li x CoO 2 by Van der Ven et al 36 and lithium halides by Kishida et al 27 Path 1b presents an opposite trend with regards to path 1a: the first stage presents a barrier height of 4.40 eV and the jumping Li ion overlaps significantly with neighboring oxygen counterions while it passes through, resulting in a significant energy barrier. This structural hindrance is avoided along the second stage since Li ion moves through the center of the triangle made by the three neighboring oxygen anions.…”

Section: At Composition X = 0250supporting

confidence: 83%

Intercalation processes and diffusion paths of lithium ions in spinel-type structuredLi1+xTi2O4: Density functional theory

et al. 2008

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Intercalation processes and corresponding diffusion paths of Li ions into spinel-type structured Li 1+x Ti 2 O 4 ͑0 ഛ x ഛ 0.375͒ are systematically studied by means of periodic density functional theory calculations for different compositions and arrangements. An analysis of the site preference for intercalation processes is carried out, while energy barriers for the diffusion paths have been computed in detail. Our results indicate that the Li insertion is thermodynamically favorable at octahedral sites 16c in the studied composition range, and Li migration from tetrahedral sites 8a to octahedral sites 16c stabilizes the structure and becomes favorable for compositions x ജ 0.25. Diffusion paths from less stable arrangements involving Li migrations between tetrahedral and octahedral sites exhibit the lowest energy barrier since the corresponding trajectories and energy profiles take place across a triangle made by three neighboring oxygen anions without structural modification. Theoretical and experimental diffusion coefficients are in reasonable agreement.

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Section: At Composition X = 0250supporting

confidence: 83%

Intercalation processes and diffusion paths of lithium ions in spinel-type structuredLi1+xTi2O4: Density functional theory

et al. 2008

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“…As shown in the figure, formation energies for Figure 2(b)), which supports the explanation proposed by Delmas et al [45] We infer that the Coulombic interactions are the main reason for the large difference in the migration profile between the bulk and interfacial alkali ion hopping, as observed in spinel compounds. [46] In the bulk hopping mechanism, the energy maximum is located at the tetrahedral vacancy, where the short-range repulsive effect [25,26] is smaller owing to the overlap of the electron clouds of the hopping ion and surrounding oxide ions ( Figure 2 [18]. Note that net volumetric Li transportation performance is smaller than above rate difference (~7600), since fast migration only occur at the interface.…”

Section: Methodsmentioning

confidence: 98%

“…In particular, the ionic radius of Na + is larger than that of Li + , which could increase the migration energy because of the repulsion arising from electron overlap between surrounding ions during hopping. [25,26] Zhu et al reported that the diffusion coefficient of Na + is 1-2 orders of magnitude lower than that of Li + in the olivine-type FePO 4 structure. [18] To understand the difference in the rate performance between LiFePO 4 and NaFePO 4 arising from ion and electron migration, we performed first-principles density functional theory (DFT) calculations for both compounds.…”

Section: Introductionmentioning

confidence: 99%

Density functional studies of olivine-type LiFePO4 and NaFePO4 as positive electrode materials for rechargeable lithium and sodium ion batteries

et al. 2016

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“…32,33 These are in sharp contrast to the Li-ion conducting Li 2 Te envelopes that form around the Li-Pb alloy particles in PbTe electrodes. 16 Li 2 Te has been computationally predicted to be Li-ion conducting, 34 whereas Li 2 S is Li-ion insulating. In the Li 2 S-free system, dissolved polysulfide species may contaminate the electrolyte or damage the lithium counter electrode, 30 leading to the more rapid negative shift of the 0.4-0.5 V reduction peak and reduced cycling performance.…”

Section: Resultsmentioning

confidence: 99%

Lithiation and Delithiation of Lead Sulfide (PbS)

Wood

Powell

Heller

et al. 2015

J. Electrochem. Soc.

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The lithiation and delithiation of PbS was studied. Below 1.0 V vs. Li/Li + , lithiation produced a series of Li-Pb alloys and Li 2 S. The Li-Pb alloys were reversibly lithiated and delithiated, but at a 1 C rate their capacity faded through 100 cycles. Above 1.5 V vs. Li/Li + , Li 2 S is electrooxidized to Li + and soluble polysulfides, and the sulfide is irreversibly depleted. © The Author(s) 2015. Published by ECS. This is an open access article distributed under the terms of the Creative Commons Attribution 4.0 License (CC BY, http://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse of the work in any medium, provided the original work is properly cited. [DOI: 10.1149/2.0241507jes] All rights reserved.Manuscript submitted January 23, 2015; revised manuscript received March 19, 2015. Published March 31, 2015 Presently, 86% of lead consumed in the U.S. is used in conventional automotive lead-acid batteries.1 However, hybrid and electric vehicles do not use these conventional lead-acid batteries, and so as these alternative vehicles are more widely adopted, an excess lead production capacity is likely to develop. Because lead forms a series of lithium alloys, the excess lead could be diverted for use in a different type of battery chemistry such as lithium-ion batteries. 15 Our previous study of PbTe nanoparticles showed that the combination of Li-Pb alloys and Li 2 Te formed during the first lithiation cycled stably at relatively high rates. For example, we were able to attain a capacity of 500 mAh g −1 at a C/5 rate and 300 mAh g −1 at a 10 C rate with PbTe. 16Past studies have found that GeS 17 and SnS 18 exhibit improved cycling performance over their base-metal and oxide counterparts. Here we probe whether PbS confers similar benefits over Pb and PbO and conclude that it does not. ExperimentalSynthesis and characterization.-All chemicals were purchased from Sigma-Aldrich, unless otherwise noted, and used as received. Based on a procedure by Zhang et al., PbS nanoparticles were prepared as follows.19 10 mmol of elemental sulfur was added to 100 mL of deionized water with magnetic stirring. 0.2 mol of NaOH was added in order to dissolve the sulfur. The solution was heated to ∼80• C to facilitate dissolution of the sulfur. The solution was dark yellow, but still transparent. A second solution was created by dissolving 10.2 mmol of Pb(Ac) 2 •3H 2 O in 10 ml of DI water. The first solution was allowed to cool to room temperature, and the second solution was added all at once. A black precipitate appeared immediately. The resultant PbS particles were collected by centrifugation and washed twice with DI water and once with acetone. They were then dried under vacuum at 70• C overnight. X-Ray Diffraction (XRD) measurements were performed on a Spider R-axis diffractometer with a Cu Kα radiation source at 40 kV and 40 mA. Scanning Electron Microscopy (SEM) micrographs were obtained using a Hitachi S-5500 electron microscope.Electrochemical measurements.-A slurry of PbS nanoparticles (60 wt%), p...

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First-Principles Calculations of Migration Energy of Lithium Ions in Halides and Chalcogenides

Cited by 28 publications

References 22 publications

Intercalation processes and diffusion paths of lithium ions in spinel-type structuredLi1+xTi2O4: Density functional theory

Intercalation processes and diffusion paths of lithium ions in spinel-type structuredLi1+xTi2O4: Density functional theory

Density functional studies of olivine-type LiFePO4 and NaFePO4 as positive electrode materials for rechargeable lithium and sodium ion batteries

Lithiation and Delithiation of Lead Sulfide (PbS)

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