Mitigating Strain Accumulation in Li2RuO3 via Fluorine Doping

Yanfang Wang; Hongzhi Wang; Yongcong Huang; Yingzhi Li; Zongrun Li; Joshua Makepeace; Quanbing Liu; Fucai Zhang; Phoebe Allan; Zhouguang Lu

doi:10.1021/acs.jpclett.4c00748

Mitigating Strain Accumulation in Li₂RuO₃ via Fluorine Doping

Yanfang Wang, Hongzhi Wang, Yongcong Huang, Yingzhi Li, Zongrun Li, Joshua Makepeace, Quanbing Liu, Fucai Zhang^*, Phoebe Allan^*, Zhouguang Lu^*

^*Corresponding author for this work

Chemistry

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Abstract

Lithium ruthenium oxide (Li₂RuO₃) is an archetypal lithium rich cathode material (LRCM) with both cation and anion redox reactions (ARRs). Commonly, the instability of oxygen redox activities has been regarded as the root cause of its performance degradation in long-term operation. However, we find that not triggering ARRs does not improve and even worsens its cyclability due to the detrimental strain accumulation induced by Ru redox activities. To solve this problem, we demonstrate that F-doping in Li₂RuO₃ can alter its preferential orientation and buffer interlayer repulsion upon Ru redox, both of which can mitigate the strain accumulation along the c-axis and improve its structural stability. This work highlights the importance of optimizing cation redox reactions in LRCMs and provides a new perspective for their rational design.

Original language	English
Pages (from-to)	5359–5365
Number of pages	7
Journal	Journal of Physical Chemistry Letters
Volume	15
Issue number	20
Early online date	10 May 2024
DOIs	https://doi.org/10.1021/acs.jpclett.4c00748
Publication status	Published - 23 May 2024

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title = "Mitigating Strain Accumulation in Li2RuO3 via Fluorine Doping",

abstract = "Lithium ruthenium oxide (Li2RuO3) is an archetypal lithium rich cathode material (LRCM) with both cation and anion redox reactions (ARRs). Commonly, the instability of oxygen redox activities has been regarded as the root cause of its performance degradation in long-term operation. However, we find that not triggering ARRs does not improve and even worsens its cyclability due to the detrimental strain accumulation induced by Ru redox activities. To solve this problem, we demonstrate that F-doping in Li2RuO3 can alter its preferential orientation and buffer interlayer repulsion upon Ru redox, both of which can mitigate the strain accumulation along the c-axis and improve its structural stability. This work highlights the importance of optimizing cation redox reactions in LRCMs and provides a new perspective for their rational design.",

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doi = "10.1021/acs.jpclett.4c00748",

language = "English",

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TY - JOUR

T1 - Mitigating Strain Accumulation in Li2RuO3 via Fluorine Doping

AU - Wang, Yanfang

AU - Wang, Hongzhi

AU - Huang, Yongcong

AU - Li, Yingzhi

AU - Li, Zongrun

AU - Makepeace, Joshua

AU - Liu, Quanbing

AU - Zhang, Fucai

AU - Allan, Phoebe

AU - Lu, Zhouguang

PY - 2024/5/23

Y1 - 2024/5/23

N2 - Lithium ruthenium oxide (Li2RuO3) is an archetypal lithium rich cathode material (LRCM) with both cation and anion redox reactions (ARRs). Commonly, the instability of oxygen redox activities has been regarded as the root cause of its performance degradation in long-term operation. However, we find that not triggering ARRs does not improve and even worsens its cyclability due to the detrimental strain accumulation induced by Ru redox activities. To solve this problem, we demonstrate that F-doping in Li2RuO3 can alter its preferential orientation and buffer interlayer repulsion upon Ru redox, both of which can mitigate the strain accumulation along the c-axis and improve its structural stability. This work highlights the importance of optimizing cation redox reactions in LRCMs and provides a new perspective for their rational design.

AB - Lithium ruthenium oxide (Li2RuO3) is an archetypal lithium rich cathode material (LRCM) with both cation and anion redox reactions (ARRs). Commonly, the instability of oxygen redox activities has been regarded as the root cause of its performance degradation in long-term operation. However, we find that not triggering ARRs does not improve and even worsens its cyclability due to the detrimental strain accumulation induced by Ru redox activities. To solve this problem, we demonstrate that F-doping in Li2RuO3 can alter its preferential orientation and buffer interlayer repulsion upon Ru redox, both of which can mitigate the strain accumulation along the c-axis and improve its structural stability. This work highlights the importance of optimizing cation redox reactions in LRCMs and provides a new perspective for their rational design.

U2 - 10.1021/acs.jpclett.4c00748

DO - 10.1021/acs.jpclett.4c00748

M3 - Letter

C2 - 38728665

SN - 1948-7185

VL - 15

SP - 5359

EP - 5365

JO - Journal of Physical Chemistry Letters

JF - Journal of Physical Chemistry Letters

IS - 20

ER -

Mitigating Strain Accumulation in Li2RuO3 via Fluorine Doping

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Mitigating Strain Accumulation in Li₂RuO₃ via Fluorine Doping