Boosting the Power Characteristics of All-Solid-State Batteries Through Improved Electrochemical Stability: Site-Specific Nb Doping in Argyrodite

Yongsun Park; So Yi Lee; Hae Yong Kim; Myeongcho Jang; Sunho Ko; Gwangseok Oh; Seung Deok Seo; Min Jae You; Hanjun Kim; Minwook Pin; Robson S. Monteiro; Seungho Yu; Kyung Wan Nam; Sang Cheol Nam; Ohmin Kwon

doi:10.1002/cey2.70058

Boosting the Power Characteristics of All-Solid-State Batteries Through Improved Electrochemical Stability: Site-Specific Nb Doping in Argyrodite

Yongsun Park
, So Yi Lee
, Hae Yong Kim
, Myeongcho Jang
, Sunho Ko
, Gwangseok Oh
, Seung Deok Seo
, Min Jae You
, Hanjun Kim
, Minwook Pin
, Robson S. Monteiro
, Seungho Yu
, Kyung Wan Nam
, Sang Cheol Nam
, Ohmin Kwon

POSCO
Dongguk University
Korea Institute of Science and Technology
Research Institute of Industrial Science & Technology, Pohang
Companhia Brasileira de Metalurgia e Mineração
Hanyang University

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

Abstract

Enhancing the energy density of all-solid-state batteries (ASSBs) with lithium metal anodes is crucial, but lithium dendrite-induced short circuits limit fast-charging capability. This study presents a high-power ASSB employing a novel, robust solid electrolyte (SE) with exceptionally high stability at the lithium metal/SE interface, achieved via site-specific Nb doping in the argyrodite structure. Pentavalent Nb incorporation into Wyckoff 48h sites enhances structural stability, as confirmed by neutron diffraction, X-ray absorption spectroscopy, magic angle spinning nuclear magnetic resonance, and density functional theory calculations. While Nb doping slightly reduces ionic conductivity, it significantly improves interfacial stability, suppressing dendrite formation and enabling a full cell capable of charging in just 6 min (10-C rate, 16 mA cm⁻²). This study highlights, for the first time, that electrochemical stability, rather than ionic conductivity, is key to achieving high-power performance, advancing the commercialization of lithium metal-based ASSBs.

Original language	English
Article number	e70058
Journal	Carbon Energy
Volume	7
Issue number	11
DOIs	https://doi.org/10.1002/cey2.70058
State	Published - Nov 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

all-solid-state batteries
argyrodites
lithium ionic conductors
solid electrolytes

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10.1002/cey2.70058

Cite this

Park, Y., Lee, S. Y., Kim, H. Y., Jang, M., Ko, S., Oh, G., Seo, S. D., You, M. J., Kim, H., Pin, M., Monteiro, R. S., Yu, S., Nam, K. W., Nam, S. C., & Kwon, O. (2025). Boosting the Power Characteristics of All-Solid-State Batteries Through Improved Electrochemical Stability: Site-Specific Nb Doping in Argyrodite. Carbon Energy, 7(11), Article e70058. https://doi.org/10.1002/cey2.70058

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title = "Boosting the Power Characteristics of All-Solid-State Batteries Through Improved Electrochemical Stability: Site-Specific Nb Doping in Argyrodite",

abstract = "Enhancing the energy density of all-solid-state batteries (ASSBs) with lithium metal anodes is crucial, but lithium dendrite-induced short circuits limit fast-charging capability. This study presents a high-power ASSB employing a novel, robust solid electrolyte (SE) with exceptionally high stability at the lithium metal/SE interface, achieved via site-specific Nb doping in the argyrodite structure. Pentavalent Nb incorporation into Wyckoff 48h sites enhances structural stability, as confirmed by neutron diffraction, X-ray absorption spectroscopy, magic angle spinning nuclear magnetic resonance, and density functional theory calculations. While Nb doping slightly reduces ionic conductivity, it significantly improves interfacial stability, suppressing dendrite formation and enabling a full cell capable of charging in just 6 min (10-C rate, 16 mA cm−2). This study highlights, for the first time, that electrochemical stability, rather than ionic conductivity, is key to achieving high-power performance, advancing the commercialization of lithium metal-based ASSBs.",

keywords = "all-solid-state batteries, argyrodites, lithium ionic conductors, solid electrolytes",

author = "Yongsun Park and Lee, \{So Yi\} and Kim, \{Hae Yong\} and Myeongcho Jang and Sunho Ko and Gwangseok Oh and Seo, \{Seung Deok\} and You, \{Min Jae\} and Hanjun Kim and Minwook Pin and Monteiro, \{Robson S.\} and Seungho Yu and Nam, \{Kyung Wan\} and Nam, \{Sang Cheol\} and Ohmin Kwon",

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year = "2025",

month = nov,

doi = "10.1002/cey2.70058",

language = "English",

volume = "7",

journal = "Carbon Energy",

issn = "2637-9368",

publisher = "John Wiley \& Sons Inc.",

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T2 - Site-Specific Nb Doping in Argyrodite

AU - Park, Yongsun

AU - Lee, So Yi

AU - Kim, Hae Yong

AU - Jang, Myeongcho

AU - Ko, Sunho

AU - Oh, Gwangseok

AU - Seo, Seung Deok

AU - You, Min Jae

AU - Kim, Hanjun

AU - Pin, Minwook

AU - Monteiro, Robson S.

AU - Yu, Seungho

AU - Nam, Kyung Wan

AU - Nam, Sang Cheol

AU - Kwon, Ohmin

PY - 2025/11

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N2 - Enhancing the energy density of all-solid-state batteries (ASSBs) with lithium metal anodes is crucial, but lithium dendrite-induced short circuits limit fast-charging capability. This study presents a high-power ASSB employing a novel, robust solid electrolyte (SE) with exceptionally high stability at the lithium metal/SE interface, achieved via site-specific Nb doping in the argyrodite structure. Pentavalent Nb incorporation into Wyckoff 48h sites enhances structural stability, as confirmed by neutron diffraction, X-ray absorption spectroscopy, magic angle spinning nuclear magnetic resonance, and density functional theory calculations. While Nb doping slightly reduces ionic conductivity, it significantly improves interfacial stability, suppressing dendrite formation and enabling a full cell capable of charging in just 6 min (10-C rate, 16 mA cm−2). This study highlights, for the first time, that electrochemical stability, rather than ionic conductivity, is key to achieving high-power performance, advancing the commercialization of lithium metal-based ASSBs.

AB - Enhancing the energy density of all-solid-state batteries (ASSBs) with lithium metal anodes is crucial, but lithium dendrite-induced short circuits limit fast-charging capability. This study presents a high-power ASSB employing a novel, robust solid electrolyte (SE) with exceptionally high stability at the lithium metal/SE interface, achieved via site-specific Nb doping in the argyrodite structure. Pentavalent Nb incorporation into Wyckoff 48h sites enhances structural stability, as confirmed by neutron diffraction, X-ray absorption spectroscopy, magic angle spinning nuclear magnetic resonance, and density functional theory calculations. While Nb doping slightly reduces ionic conductivity, it significantly improves interfacial stability, suppressing dendrite formation and enabling a full cell capable of charging in just 6 min (10-C rate, 16 mA cm−2). This study highlights, for the first time, that electrochemical stability, rather than ionic conductivity, is key to achieving high-power performance, advancing the commercialization of lithium metal-based ASSBs.

KW - all-solid-state batteries

KW - argyrodites

KW - lithium ionic conductors

KW - solid electrolytes

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DO - 10.1002/cey2.70058

M3 - Article

AN - SCOPUS:105015457389

SN - 2637-9368

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M1 - e70058

ER -

Boosting the Power Characteristics of All-Solid-State Batteries Through Improved Electrochemical Stability: Site-Specific Nb Doping in Argyrodite

Abstract

UN SDGs

Keywords

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