2012
DOI: 10.1021/ja305366r
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Direct Calculation of Li-Ion Transport in the Solid Electrolyte Interphase

Abstract: The mechanism of Li(+) transport through the solid electrolyte interphase (SEI), a passivating film on electrode surfaces, has never been clearly elucidated despite its overwhelming importance to Li-ion battery operation and lifetime. The present paper develops a multiscale theoretical methodology to reveal the mechanism of Li(+) transport in a SEI film. The methodology incorporates the boundary conditions of the first direct diffusion measurements on a model SEI consisting of porous (outer) organic and dense … Show more

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Cited by 587 publications
(578 citation statements)
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References 54 publications
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“…Finally, one may conclude that the AEI likely consists of Li 2 CO 3 domains in a complex amorphous organic matrix, which is similar to those reported for graphite anode materials [44][45][46][47] .…”
Section: Morphology and Electronic Structure Of Nio Nanosheetssupporting
confidence: 80%
See 1 more Smart Citation
“…Finally, one may conclude that the AEI likely consists of Li 2 CO 3 domains in a complex amorphous organic matrix, which is similar to those reported for graphite anode materials [44][45][46][47] .…”
Section: Morphology and Electronic Structure Of Nio Nanosheetssupporting
confidence: 80%
“…Firstly, the chemical environment of AEI at the surface of NiO nanosheets is determined to be Li 2 CO 3 nanoscale domains imbedded in an amorphous organic matrix and its thickness exhibits dependence on the SOC. The chemical environment of AEI on NiO nanosheets is similar to that at the surface of graphite anode materials 44,46,47 . Therefore, these observations represent a step towards leveraging AEI on transition metal oxide materials with the conventional concept of solid-electrolyte interphase on graphite materials 28,45 .…”
Section: Discussionmentioning
confidence: 85%
“…We assume that intermediate As can be seen in Figure 3, net reactions considered in the continuum model are direct pathways from the reactants EC, Li + , and e − to the products C 2 H 4 , LC, LEDC, and the desorbed intermediate species Solid components.-The assumed solid products are LC and LEDC, which have been reported as being the main SEI film components. 6,7,12,31,35,36 LC is reported to be the most important component for SEI functionality 13,37 and formed with ECbased electrolytes. 7 A two-layer structure of the SEI is commonly reported, 13,38 with a dense inner film and a porous outer film.…”
Section: Mathematical Modelingmentioning
confidence: 99%
“…DFT has been applied to determine energy barriers and standard state potentials 12 and transport processes in the solid film. 13,14 Methekar et al 15 proposed the application of kMC to simulate heterogeneous passivation of the interface. Several macroscopic electrode models are available based on PDEs to simulate film growth and resistance 16,17 and for detailed analysis of transport processes and reactions in the SEI.…”
mentioning
confidence: 99%
“…A new Li knock-off mechanism, rather than isolated vacancy hopping, is proposed for Li 2 CO 3 , which accounts for the fast Li diffusion in this material. 153 By incorporating the atomistic diffusivity in mesoscale diffusion equations, good agreement was achieved with experiments. The diffusion barrier and formation energy of various defects in LiF at different potentials have also been investigated using NEB and other computational methods.…”
Section: Silicon and Other Anodesmentioning
confidence: 80%