Galvanostatic interruption of lithium insertion into magnetite: Evidence of surface layer formation

Nicholas W. Brady; K. W. Knehr; Christina A. Cama; Christianna N. Lininger; Zhou Lin; Amy C. Marschilok; Kenneth J. Takeuchi; Esther S. Takeuchi; Alan C. West

doi:10.1016/j.jpowsour.2016.04.117

Galvanostatic interruption of lithium insertion into magnetite: Evidence of surface layer formation

Nicholas W. Brady
, K. W. Knehr
, Christina A. Cama
, Christianna N. Lininger
, Zhou Lin
, Amy C. Marschilok
, Kenneth J. Takeuchi
, Esther S. Takeuchi
, Alan C. West

Stony Brook University

Columbia University
Stony Brook University

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Magnetite is a known lithium intercalation material, and the loss of active, nanocrystalline magnetite can be inferred from the open-circuit potential relaxation. Specifically, for current interruption after relatively small amounts of lithium insertion, the potential first increases and then decreases, and the decrease is hypothesized to be due to a formation of a surface layer, which increases the solid-state lithium concentration in the remaining active material. Comparisons of simulation to experiment suggest that the reactions with the electrolyte result in the formation of a thin layer of electrochemically inactive material, which is best described by a nucleation and growth mechanism. Simulations are consistent with experimental results observed for 6, 8 and 32-nm crystals. Furthermore, simulations capture the experimental differences in lithiation behavior between the first and second cycles.

Original language	English
Pages (from-to)	106-111
Number of pages	6
Journal	Journal of Power Sources
Volume	321
DOIs	https://doi.org/10.1016/j.jpowsour.2016.04.117
State	Published - Jul 30 2016

Keywords

Avrami model
Lithium ion batteries
Multi-scale model
SEI
Voltage recovery

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10.1016/j.jpowsour.2016.04.117

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@article{b1046004c825411b80965028c547b80f,

title = "Galvanostatic interruption of lithium insertion into magnetite: Evidence of surface layer formation",

abstract = "Magnetite is a known lithium intercalation material, and the loss of active, nanocrystalline magnetite can be inferred from the open-circuit potential relaxation. Specifically, for current interruption after relatively small amounts of lithium insertion, the potential first increases and then decreases, and the decrease is hypothesized to be due to a formation of a surface layer, which increases the solid-state lithium concentration in the remaining active material. Comparisons of simulation to experiment suggest that the reactions with the electrolyte result in the formation of a thin layer of electrochemically inactive material, which is best described by a nucleation and growth mechanism. Simulations are consistent with experimental results observed for 6, 8 and 32-nm crystals. Furthermore, simulations capture the experimental differences in lithiation behavior between the first and second cycles.",

keywords = "Avrami model, Lithium ion batteries, Multi-scale model, SEI, Voltage recovery",

author = "Brady, \{Nicholas W.\} and Knehr, \{K. W.\} and Cama, \{Christina A.\} and Lininger, \{Christianna N.\} and Zhou Lin and Marschilok, \{Amy C.\} and Takeuchi, \{Kenneth J.\} and Takeuchi, \{Esther S.\} and West, \{Alan C.\}",

year = "2016",

month = jul,

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doi = "10.1016/j.jpowsour.2016.04.117",

language = "English",

volume = "321",

pages = "106--111",

journal = "Journal of Power Sources",

issn = "0378-7753",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - Galvanostatic interruption of lithium insertion into magnetite

T2 - Evidence of surface layer formation

AU - Brady, Nicholas W.

AU - Knehr, K. W.

AU - Cama, Christina A.

AU - Lininger, Christianna N.

AU - Lin, Zhou

AU - Marschilok, Amy C.

AU - Takeuchi, Kenneth J.

AU - Takeuchi, Esther S.

AU - West, Alan C.

PY - 2016/7/30

Y1 - 2016/7/30

N2 - Magnetite is a known lithium intercalation material, and the loss of active, nanocrystalline magnetite can be inferred from the open-circuit potential relaxation. Specifically, for current interruption after relatively small amounts of lithium insertion, the potential first increases and then decreases, and the decrease is hypothesized to be due to a formation of a surface layer, which increases the solid-state lithium concentration in the remaining active material. Comparisons of simulation to experiment suggest that the reactions with the electrolyte result in the formation of a thin layer of electrochemically inactive material, which is best described by a nucleation and growth mechanism. Simulations are consistent with experimental results observed for 6, 8 and 32-nm crystals. Furthermore, simulations capture the experimental differences in lithiation behavior between the first and second cycles.

AB - Magnetite is a known lithium intercalation material, and the loss of active, nanocrystalline magnetite can be inferred from the open-circuit potential relaxation. Specifically, for current interruption after relatively small amounts of lithium insertion, the potential first increases and then decreases, and the decrease is hypothesized to be due to a formation of a surface layer, which increases the solid-state lithium concentration in the remaining active material. Comparisons of simulation to experiment suggest that the reactions with the electrolyte result in the formation of a thin layer of electrochemically inactive material, which is best described by a nucleation and growth mechanism. Simulations are consistent with experimental results observed for 6, 8 and 32-nm crystals. Furthermore, simulations capture the experimental differences in lithiation behavior between the first and second cycles.

KW - Avrami model

KW - Lithium ion batteries

KW - Multi-scale model

KW - SEI

KW - Voltage recovery

UR - https://www.scopus.com/pages/publications/84965070752

U2 - 10.1016/j.jpowsour.2016.04.117

DO - 10.1016/j.jpowsour.2016.04.117

M3 - Article

SN - 0378-7753

VL - 321

SP - 106

EP - 111

JO - Journal of Power Sources

JF - Journal of Power Sources

ER -

Galvanostatic interruption of lithium insertion into magnetite: Evidence of surface layer formation

Abstract

Keywords

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