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Combined electrochemical, XPS, and STXM study of lithium nitride as a protective coating for lithium metal and lithium–sulfur batteries

Combined electrochemical, XPS, and STXM study of lithium nitride as a protective coating for lithium metal and lithium–sulfur batteries
Combined electrochemical, XPS, and STXM study of lithium nitride as a protective coating for lithium metal and lithium–sulfur batteries
Li3N is an excellent protective coating material for lithium electrodes with very high lithium-ion conductivity and low electronic conductivity, but the formation of stable and homogeneous coatings is technically very difficult. Here, we show that protective Li3N coatings can be simply formed by the direct reaction of electrodeposited lithium electrodes with N2 gas, whereas using battery-grade lithium foil is problematic due to the presence of a native passivation layer that hampers that reaction. The protective Li3N coating is effective at preventing lithium dendrite formation, as found from unidirectional plating and plating–stripping measurements in Li–Li cells. The Li3N coating also efficiently suppresses the parasitic reactions of polysulfides and other electrolyte species with the lithium electrode, as demonstrated by scanning transmission X-ray microscopy, X-ray photoelectron spectroscopy, and optical microscopy. The protection of the lithium electrode against corrosion by polysulfides and other electrolyte species, as well as the promotion of smooth deposits without dendrites, makes the Li3N coating highly promising for applications in lithium metal batteries, such as lithium–sulfur batteries. The present findings show that the formation of Li3N can be achieved with lithium electrodes covered by a secondary electrolyte interface layer, which proves that the in situ formation of Li3N coatings inside the batteries is attainable.
STXM, XPS, artificial SEI, lithium metal anode, lithium-sulfur batteries, operando optical microscopy, polysulfides, protective coating
1944-8244
39198-39210
Fitch, Samuel D.S.
6e21c66c-99c4-4b1b-b8ff-043a0cc2e884
Moehl, Gilles E.
c3f40572-28c6-4467-a118-502000132f8c
Meddings, Nina
3018b390-3284-4da0-a9c6-4be738803717
Fop, Sacha
336731ce-2b16-4bc4-bc50-48b202613a0b
Soule, Samantha
f5b1ff97-bf20-4adb-ba1d-357254158d8f
Lee, Tien-Lin
34f3950c-8c28-40a8-94da-74b3849191b0
Kazemian, Majid
31d6e5e4-dc28-423d-9f8a-ec896e989f9f
Garcia-Araez, Nuria
9358a0f9-309c-495e-b6bf-da985ad81c37
Hector, Andrew L.
f19a8f31-b37f-4474-b32a-b7cf05b9f0e5
Fitch, Samuel D.S.
6e21c66c-99c4-4b1b-b8ff-043a0cc2e884
Moehl, Gilles E.
c3f40572-28c6-4467-a118-502000132f8c
Meddings, Nina
3018b390-3284-4da0-a9c6-4be738803717
Fop, Sacha
336731ce-2b16-4bc4-bc50-48b202613a0b
Soule, Samantha
f5b1ff97-bf20-4adb-ba1d-357254158d8f
Lee, Tien-Lin
34f3950c-8c28-40a8-94da-74b3849191b0
Kazemian, Majid
31d6e5e4-dc28-423d-9f8a-ec896e989f9f
Garcia-Araez, Nuria
9358a0f9-309c-495e-b6bf-da985ad81c37
Hector, Andrew L.
f19a8f31-b37f-4474-b32a-b7cf05b9f0e5

Fitch, Samuel D.S., Moehl, Gilles E., Meddings, Nina, Fop, Sacha, Soule, Samantha, Lee, Tien-Lin, Kazemian, Majid, Garcia-Araez, Nuria and Hector, Andrew L. (2023) Combined electrochemical, XPS, and STXM study of lithium nitride as a protective coating for lithium metal and lithium–sulfur batteries. ACS Applied Materials and Interfaces, 15 (33), 39198-39210. (doi:10.1021/acsami.3c04897).

Record type: Article

Abstract

Li3N is an excellent protective coating material for lithium electrodes with very high lithium-ion conductivity and low electronic conductivity, but the formation of stable and homogeneous coatings is technically very difficult. Here, we show that protective Li3N coatings can be simply formed by the direct reaction of electrodeposited lithium electrodes with N2 gas, whereas using battery-grade lithium foil is problematic due to the presence of a native passivation layer that hampers that reaction. The protective Li3N coating is effective at preventing lithium dendrite formation, as found from unidirectional plating and plating–stripping measurements in Li–Li cells. The Li3N coating also efficiently suppresses the parasitic reactions of polysulfides and other electrolyte species with the lithium electrode, as demonstrated by scanning transmission X-ray microscopy, X-ray photoelectron spectroscopy, and optical microscopy. The protection of the lithium electrode against corrosion by polysulfides and other electrolyte species, as well as the promotion of smooth deposits without dendrites, makes the Li3N coating highly promising for applications in lithium metal batteries, such as lithium–sulfur batteries. The present findings show that the formation of Li3N can be achieved with lithium electrodes covered by a secondary electrolyte interface layer, which proves that the in situ formation of Li3N coatings inside the batteries is attainable.

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Accepted/In Press date: 24 July 2023
e-pub ahead of print date: 8 August 2023
Published date: 8 August 2023
Additional Information: Funding Information: Financial support from EPSRC through the Faraday Institution LiSTAR programme (EP/S003053/1, grant FIRG014) and an early career fellowship to N.G.A. (EP/N024303/1) are gratefully acknowledged. The authors also gratefully acknowledge support from Diamond for beam time at the I08 (SP1860 and SP20639) and I09 (S122619) beamlines. Conventional X-ray photoelectron (XPS) data collection was performed at the EPSRC National Facility for XPS (“HarwellXPS”), operated by Cardiff University and UCL, under contract no. PR16195. We also acknowledge Dr. Mark Isaacs for helpful scientific discussions regarding the XPS measurements. Publisher Copyright: © 2023 The Authors. Published by American Chemical Society.
Keywords: STXM, XPS, artificial SEI, lithium metal anode, lithium-sulfur batteries, operando optical microscopy, polysulfides, protective coating
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Identifiers

Local EPrints ID: 480990
URI: http://eprints.soton.ac.uk/id/eprint/480990
DOI: doi:10.1021/acsami.3c04897
ISSN: 1944-8244
PURE UUID: 129c17bb-fcc8-418a-9935-8cd1c9f949b1
ORCID for Samuel D.S. Fitch: ORCID iD orcid.org/0000-0002-3681-8985
ORCID for Gilles E. Moehl: ORCID iD orcid.org/0000-0003-4910-3601
ORCID for Nina Meddings: ORCID iD orcid.org/0000-0001-7242-6076
ORCID for Nuria Garcia-Araez: ORCID iD orcid.org/0000-0001-9095-2379
ORCID for Andrew L. Hector: ORCID iD orcid.org/0000-0002-9964-2163

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Date deposited: 14 Aug 2023 16:51
Last modified: 18 Mar 2024 03:50

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Contributors

Author: Samuel D.S. Fitch ORCID iD
Author: Gilles E. Moehl ORCID iD
Author: Nina Meddings ORCID iD
Author: Sacha Fop
Author: Samantha Soule
Author: Tien-Lin Lee
Author: Majid Kazemian
Author: Nuria Garcia-Araez ORCID iD
Author: Andrew L. Hector ORCID iD

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