Operando Studies of Antiperovskite Lithium Battery Cathode Material (Li<sub>2</sub>Fe)SO

Mikhailova, Daria; Giebeler, Lars; Maletti, Sebastian; Oswald, Steffen; Sarapulova, Angelina; Indris, Sylvio; Hu, Zhiwei; Bednarčı́k, J.; Valldor, Martin

doi:10.1021/acsaem.8b01493

Cited by 18 publications

(61 citation statements)

References 33 publications

(46 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As one would expect from the values of ionic radii for transition metal cations (Shannon, 1976), partial substitution of high-spin HS-Fe 2+ (0.78 Å) by HS-Co 2+ (0.745 Å) must result in a slight shrinkage of the crystallographic unit cell, whereas HS-Mn 2+ (0.83 Å) enhances the cell parameter. The values of cell metrics for Li 2 Fe 0.9 Mn 0.1 SO and pure Li 2 FeSO obtained in this work agree well with the results of the previous research related to these materials (Mikhailova et al, 2018;Gorbunov et al, 2020). For the Co-containing phase as expected, the determined cell parameter of 3.9082(5) Å is slightly smaller than that of unsubstituted Li 2 FeSO material (3.914 Å).…”

Section: Synthesis and Primary Physicochemical Characterizationsupporting

confidence: 91%

“…The structural behavior of the Li 2 Fe 0.9 Co 0.1 SO material (Figure 5) strongly resembles that of Li 2 FeSO. No formation of a second isostructural phase was observed, and the change of the lattice parameter is highly non-linear during the charging process, similar to the reported behavior for Li 2 FeSO (Mikhailova et al, 2018). The amount of extracted lithium before this nonlinearity appears, is different, though.…”

Section: Operando Xrd Studiessupporting

confidence: 81%

“…Moreover, the rapid deterioration of the diffusion process at the end of the charge, corresponding to a significant decrease of the diffusion coefficient, occurs earlier for the substituted materials (2.7 V vs. 2.88 V for Li 2 FeSO). However, the effect of partial substitution is opposite for the discharge process: the average Li-diffusion coefficient for substituted phases is one order of magnitude higher than for Li 2 FeSO (Mikhailova et al, 2018). No direct correlation between the lattice parameter a and the lithium diffusion coefficient was observed.…”

Section: Electrochemical Investigations Ofmentioning

confidence: 90%

“…(D) Average oxidation states of metal cations in Li 2 Fe 0.9 Co 0.1 SO estimated from the electrochemical measurements (EC) and XAS studies. The position of the Fe K-edge was defined as the energy at the X-ray absorption coefficient µ(E) = 0.8 of normalized post-edge intensities, similar to Mikhailova et al (2018) and Gorbunov et al (2020).…”

Section: A B D Cmentioning

confidence: 99%

“…Recently reported compounds with the antiperovskite structure represent an interesting class of materials for possible application as cathodes in Li-ion batteries (Lai et al, 2017(Lai et al, , 2018Mikhailova et al, 2018;Gorbunov et al, 2020). Among the studied materials, Li 2 CoSO and Li 2 MnSO (Lai et al, 2018), Li 2 FeSO (Lai et al, 2017;Mikhailova et al, 2018) and Li 2 Fe 0.5 Mn 0.5 SO (Gorbunov et al, 2020), the Li 2 FeSO compound demonstrates the most promising characteristics in terms of specific electrochemical capacities during galvanostatic cycling and rate capability. Other materials mentioned above show much lower specific capacity values not exceeding 100 mAh/g after few cycles (Lai et al, 2018) and quite a poor cycling behavior in lithium cells (Gorbunov et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

et al. 2021

Self Cite

View full text Add to dashboard Cite

Cubic Li2Fe0.9M0.1SO antiperovskites with M–Co2+, or Mn2+ were successfully synthesized by a solid-state technique, and studied as cathode materials in Li-batteries. The influence of the Co, and Mn cation substitution of Fe in Li2FeSO on the resulting electrochemical performance was evaluated by galvanostatic cycling, while the reaction mechanism was explored by applying operando X-ray absorption and X-ray diffraction techniques using synchrotron radiation facilities. Even 10% Fe-substitution by these metals completely changes the structural behavior of the material upon Li-removal and insertion, in comparison to Li2FeSO. The Co-substitution significantly improves cyclability of the material at high current densities in comparison to the non-substituted material, reaching a specific capacity of 250 mAh/g at 1C current density. In contrast, the Mn-substitution leads to deterioration of the electrochemical performance because of the impeded kinetics, which may be caused by the appearance of a second isostructural phase due to formation of Jahn-Teller Mn3+ cations upon delithiation.

show abstract

Section: Synthesis and Primary Physicochemical Characterizationsupporting

confidence: 91%

Section: Operando Xrd Studiessupporting

confidence: 81%

Section: Electrochemical Investigations Ofmentioning

confidence: 90%

Section: A B D Cmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

et al. 2021

Self Cite

View full text Add to dashboard Cite

show abstract

Cation Disordered Anti‐Perovskite Cathode Materials with Enhanced Lithium Diffusion and Suppressed Phase Transition

Deng

Chen

et al. 2023

Advanced Energy Materials

View full text Add to dashboard Cite

Recently, a new family of anti‐perovskite Li2TMSO was discovered as promising cathode materials for Li‐ion batteries (LIBs) with superiorities in high specific capacity, low cost, and environmental friendliness. However, the applications of these anti‐perovskite materials meet severe challenges in the cyclability and rate performance. Herein, a cation‐disordered anti‐perovskite type solid solution Li2Fe1−xMnxSO (LFMSO, x = 0, 0.2, 0.5) with excellent electrochemical performance is reported. On the basis of comprehensive structural characterizations, the role of the cation disordering in LFMSO is clarified. In comparison with Li2FeSO (LFSO), the reduced Li‐ion diffusion barrier and the increased Li‐rich octahedral configurations in LFMSO with higher configurational entropy imply the facilitated long‐range Li‐ion diffusion and the suppressed phase transition, which favor the high‐rate capability and cycling stability. In addition, the large lattice distortion and Coulombic interaction between the anions and cations lead to the breathing of the unit cell during charge/discharge. The variation of the unit cell volume decreases to 2.5% upon Li‐ion delithiation. A superstructure is observed in LFMSO for the first time. These findings help to pave the way for the research and development of novel cathode materials for the next generation LIBs.

show abstract

Anti‐perovskite materials for energy storage batteries

Deng

Chen

et al. 2021

InfoMat

View full text Add to dashboard Cite

Anti-perovskites X 3 BA, as the electrically inverted derivatives of perovskites ABX 3 , have attracted tremendous attention for their good performances in multiple disciplines, especially in energy storage batteries. The Li/Na-rich antiperovskite (LiRAP/NaRAP) solid-state electrolytes (SSEs) typically show high ionic conductivities and high chemical/electrochemical stability toward the Li-metal anode, illustrating their great potential for applications in the Limetal batteries (LMBs) using nonaqueous liquid electrolyte or all-solid-state electrolyte. The antiperovskites have been studied as artificial solid electrolyte interphase for Li-metal anode protection, film SSEs for thin-film batteries, and low melting temperature solid electrolyte enabling melt-infiltration for the manufacture of all-solid-state lithium batteries. Transition metal-doped LiRAPs as cathodes have demonstrated a high discharge specific capacity and good rate capability in the Li-ion batteries (LIBs). Additionally, the underlying scientific principles in antiperovskites with flexible structural features have also been extensively studied. In this review, we comprehensively summarize the development, structural design, ionic conductivity and ion transportation mechanism, chemical/electrochemical stability, and applications of some antiperovskite materials in energy storage batteries. The perspective for enhancing the performance of the antiperovskites is also provided as a guide for future development and applications in energy storage. K E Y W O R D S antiperovskite, chemical and electrochemical stability, energy storage, solid-state electrolyte Zhi Deng and Dixing Ni contributed equally to this work.

show abstract

Operando Studies of Antiperovskite Lithium Battery Cathode Material (Li₂Fe)SO

Cited by 18 publications

References 33 publications

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

Cation Disordered Anti‐Perovskite Cathode Materials with Enhanced Lithium Diffusion and Suppressed Phase Transition

Anti‐perovskite materials for energy storage batteries

Contact Info

Product

Resources

About

Operando Studies of Antiperovskite Lithium Battery Cathode Material (Li2Fe)SO

Cited by 18 publications

References 33 publications

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

Studies of Li2Fe0.9M0.1SO Antiperovskite Materials for Lithium–Ion Batteries: The Role of Partial Fe2+ to M2+ Substitution

Cation Disordered Anti‐Perovskite Cathode Materials with Enhanced Lithium Diffusion and Suppressed Phase Transition

Anti‐perovskite materials for energy storage batteries

Contact Info

Product

Resources

About

Operando Studies of Antiperovskite Lithium Battery Cathode Material (Li₂Fe)SO