Home > Research > Publications & Outputs > Tracking Sodium-Antimonide Phase Transformation...

Research

Associated organisational unit

Links

Text available via DOI:

Keywords

View graph of relations

Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Published

Standard

Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy. / Allan, Phoebe K.; Griffin, John M.; Darwiche, Ali et al.
In: Journal of the American Chemical Society, Vol. 138, No. 7, 24.02.2016, p. 2352-2365.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Allan, PK, Griffin, JM, Darwiche, A, Borkiewicz, OJ, Wiaderek, KM, Chapman, KW, Morris, AJ, Chupas, PJ, Monconduit, L & Grey, CP 2016, 'Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy', Journal of the American Chemical Society, vol. 138, no. 7, pp. 2352-2365. https://doi.org/10.1021/jacs.5b13273

APA

Allan, P. K., Griffin, J. M., Darwiche, A., Borkiewicz, O. J., Wiaderek, K. M., Chapman, K. W., Morris, A. J., Chupas, P. J., Monconduit, L., & Grey, C. P. (2016). Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy. Journal of the American Chemical Society, 138(7), 2352-2365. https://doi.org/10.1021/jacs.5b13273

Vancouver

Allan PK, Griffin JM, Darwiche A, Borkiewicz OJ, Wiaderek KM, Chapman KW et al. Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy. Journal of the American Chemical Society. 2016 Feb 24;138(7):2352-2365. Epub 2016 Jan 29. doi: 10.1021/jacs.5b13273

Author

Allan, Phoebe K. ; Griffin, John M. ; Darwiche, Ali et al. / Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes : Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy. In: Journal of the American Chemical Society. 2016 ; Vol. 138, No. 7. pp. 2352-2365.

Bibtex

@article{e83f71a726b442c5a2706741fa2ca516,
title = "Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes: Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy",
abstract = "Operando pair distribution function (PDF) analysis and ex situ Na-23 magic-angle spinning solid-state nuclear magnetic resonance (MAS ssNMR) spectroscopy are used to gain insight into the alloying mechanism of high-capacity antimony anodes for sodium-ion batteries. Subtraction of the PDF of crystalline NaxSb phases from the total PDF, an approach constrained by chemical phase information gained from Na-23 ssNMR in reference to relevant model compounds, identifies two previously uncharacterized intermediate species formed electro-chemically; a-Na3-xSb (x approximate to 0.4-0.5), a structure locally similar to crystalline Na3Sb (c-Na3Sb) but with significant numbers of sodium vacancies and a limited correlation length, and a-Na1.7Sb, a highly amorphous structure featuring some Sb-Sb bonding. The first sodiation breaks down the crystalline antimony to form first a-Na3-xSb and, finally, crystalline Na3Sb. Desodiation results in the formation of an electrode formed of a composite of crystalline and amorphous antimony networks. We link the different reactivity of these networks to a series of sequential sodiation reactions manifesting as a cascade of processes observed in the electrochemical profile of subsequent cycles. The amorphofis network reacts at higher voltages reforming a-Na1.7Sb, then a-Na3-xSb, whereas lower potentials are required for the sodiation of crystalline antimony, which reacts to form a-Na3-xSb without the formation of a-Na3-xSb. a-Na3-xSb is converted to crystalline Na3Sb at the end of the second discharge. We find no evidence of formation of NaSb. Variable temperature Na-23 NMR experiments reveal significant sodium mobility within c-Na3Sb; this is a possible contributing factor to the excellent rate performance of Sb anodes.",
keywords = "X-RAY-DIFFRACTION, LI-ION, NEGATIVE ELECTRODES, STRUCTURAL-CHANGES, LITHIUM INSERTION, CRYSTAL-STRUCTURE, SB ELECTRODES, HIGH-CAPACITY, BATTERIES, NANOCOMPOSITE",
author = "Allan, {Phoebe K.} and Griffin, {John M.} and Ali Darwiche and Borkiewicz, {Olaf J.} and Wiaderek, {Kamila M.} and Chapman, {Karena W.} and Morris, {Andrew J.} and Chupas, {Peter J.} and Laure Monconduit and Grey, {Clare P.}",
year = "2016",
month = feb,
day = "24",
doi = "10.1021/jacs.5b13273",
language = "English",
volume = "138",
pages = "2352--2365",
journal = "Journal of the American Chemical Society",
issn = "0002-7863",
publisher = "AMER CHEMICAL SOC",
number = "7",

}

RIS

TY - JOUR

T1 - Tracking Sodium-Antimonide Phase Transformations in Sodium-Ion Anodes

T2 - Insights from Operando Pair Distribution Function Analysis and Solid-State NMR Spectroscopy

AU - Allan, Phoebe K.

AU - Griffin, John M.

AU - Darwiche, Ali

AU - Borkiewicz, Olaf J.

AU - Wiaderek, Kamila M.

AU - Chapman, Karena W.

AU - Morris, Andrew J.

AU - Chupas, Peter J.

AU - Monconduit, Laure

AU - Grey, Clare P.

PY - 2016/2/24

Y1 - 2016/2/24

N2 - Operando pair distribution function (PDF) analysis and ex situ Na-23 magic-angle spinning solid-state nuclear magnetic resonance (MAS ssNMR) spectroscopy are used to gain insight into the alloying mechanism of high-capacity antimony anodes for sodium-ion batteries. Subtraction of the PDF of crystalline NaxSb phases from the total PDF, an approach constrained by chemical phase information gained from Na-23 ssNMR in reference to relevant model compounds, identifies two previously uncharacterized intermediate species formed electro-chemically; a-Na3-xSb (x approximate to 0.4-0.5), a structure locally similar to crystalline Na3Sb (c-Na3Sb) but with significant numbers of sodium vacancies and a limited correlation length, and a-Na1.7Sb, a highly amorphous structure featuring some Sb-Sb bonding. The first sodiation breaks down the crystalline antimony to form first a-Na3-xSb and, finally, crystalline Na3Sb. Desodiation results in the formation of an electrode formed of a composite of crystalline and amorphous antimony networks. We link the different reactivity of these networks to a series of sequential sodiation reactions manifesting as a cascade of processes observed in the electrochemical profile of subsequent cycles. The amorphofis network reacts at higher voltages reforming a-Na1.7Sb, then a-Na3-xSb, whereas lower potentials are required for the sodiation of crystalline antimony, which reacts to form a-Na3-xSb without the formation of a-Na3-xSb. a-Na3-xSb is converted to crystalline Na3Sb at the end of the second discharge. We find no evidence of formation of NaSb. Variable temperature Na-23 NMR experiments reveal significant sodium mobility within c-Na3Sb; this is a possible contributing factor to the excellent rate performance of Sb anodes.

AB - Operando pair distribution function (PDF) analysis and ex situ Na-23 magic-angle spinning solid-state nuclear magnetic resonance (MAS ssNMR) spectroscopy are used to gain insight into the alloying mechanism of high-capacity antimony anodes for sodium-ion batteries. Subtraction of the PDF of crystalline NaxSb phases from the total PDF, an approach constrained by chemical phase information gained from Na-23 ssNMR in reference to relevant model compounds, identifies two previously uncharacterized intermediate species formed electro-chemically; a-Na3-xSb (x approximate to 0.4-0.5), a structure locally similar to crystalline Na3Sb (c-Na3Sb) but with significant numbers of sodium vacancies and a limited correlation length, and a-Na1.7Sb, a highly amorphous structure featuring some Sb-Sb bonding. The first sodiation breaks down the crystalline antimony to form first a-Na3-xSb and, finally, crystalline Na3Sb. Desodiation results in the formation of an electrode formed of a composite of crystalline and amorphous antimony networks. We link the different reactivity of these networks to a series of sequential sodiation reactions manifesting as a cascade of processes observed in the electrochemical profile of subsequent cycles. The amorphofis network reacts at higher voltages reforming a-Na1.7Sb, then a-Na3-xSb, whereas lower potentials are required for the sodiation of crystalline antimony, which reacts to form a-Na3-xSb without the formation of a-Na3-xSb. a-Na3-xSb is converted to crystalline Na3Sb at the end of the second discharge. We find no evidence of formation of NaSb. Variable temperature Na-23 NMR experiments reveal significant sodium mobility within c-Na3Sb; this is a possible contributing factor to the excellent rate performance of Sb anodes.

KW - X-RAY-DIFFRACTION

KW - LI-ION

KW - NEGATIVE ELECTRODES

KW - STRUCTURAL-CHANGES

KW - LITHIUM INSERTION

KW - CRYSTAL-STRUCTURE

KW - SB ELECTRODES

KW - HIGH-CAPACITY

KW - BATTERIES

KW - NANOCOMPOSITE

U2 - 10.1021/jacs.5b13273

DO - 10.1021/jacs.5b13273

M3 - Journal article

VL - 138

SP - 2352

EP - 2365

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

SN - 0002-7863

IS - 7

ER -