Anion Reactivity in Cation‐Disordered Rocksalt Cathode Materials: The Influence of Fluorine Substitution

Crafton, Matthew J.; Yue, Yuan; Huang, Tzu‐Yang; Tong, Wei; McCloskey, Bryan D.

doi:10.1002/aenm.202001500

Cited by 46 publications

(110 citation statements)

References 38 publications

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“…The most dramatic difference between these two materials was the strong near-surface degradation in LTMO, which is correlated to the significant O loss. [20,21,42] In fact, our EELS measurements indicate that the thickness of the O-deficient surface layer in LTMO (≈14 nm) (Figure 2d) after 50 cycles was much larger than that in LTMOF (≈8 nm) (Figure 2h), confirming that much more severe O loss occurred in LTMO. Strong O loss from Li-excess materials is usually triggered by excess usage of O redox.…”

Section: Discussionmentioning

confidence: 69%

Fluorination‐Enhanced Surface Stability of Cation‐Disordered Rocksalt Cathodes for Li‐Ion Batteries

Lun

Chen

et al. 2021

Adv Funct Materials

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Cation-disordered rocksalt (DRX) materials have emerged as a class of novel high-capacity cathodes for Li-ion batteries. However, the commercialization of DRX cathodes will require reducing their capacity decay, which has been associated with oxygen loss during cycling. Recent studies show that fluorination of DRX cathodes can effectively reduce oxygen loss and improve cycling stability; however, the underlying atomic-scale mechanisms remain elusive. Herein, using a combination of electrochemical measurements, scanning transmission electron microscopy, and electron energy loss spectroscopy, the correlation between the electrochemical properties and structural evolution in Mn-redox-based DRX cathodes, Li 1.2 Ti 0.4-x Mn 0.4+x O 2.0-x F x (x = 0 and 0.2) is examined. It is found that fluorination strongly suppresses structural amorphization and void formation initiated from the particle surface, therefore greatly enhancing the cyclability of the cathode. A novel rocksalt-to-spinel-like structural transformation in the DRX bulk is further revealed, which surprisingly contributes to a gradual capacity increase during cycling. The results provide important insight for the design of novel DRX cathodes with high capacity and long cycle life.

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Section: Discussionmentioning

confidence: 69%

Fluorination‐Enhanced Surface Stability of Cation‐Disordered Rocksalt Cathodes for Li‐Ion Batteries

Lun

Chen

et al. 2021

Adv Funct Materials

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“…The low coulombic efficiencies can come from different factors, such as electrolyte decomposition, 45 surface species decomposition, 36,46 and gassing. 31,47 For disordered rock salt materials, O2 gas generation has been shown in the literature to occur mainly during the rst cycle, while CO2 gas generation can also happen during further cycles. 47 XPS was carried out to understand the changes in chemical composition of the CEI layer with the choice of cathode materials and electrolytes.…”

Section: Electrolyte Compatibilitymentioning

confidence: 99%

Experimental considerations to study Li-excess disordered rock salt cathode materials

et al. 2021

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“…No O 2 evolution is observed from LMNOF during the first charge (up to 4.8 V) and subsequent discharge. We know from previously published literature [45] that pristine LMNOF does not release any O 2 at potentials lower than 4.4 V but an onset of O 2 gas is observed starting at 4.45 V and continues as the cell is charged to 4.8 V. It should be noted, that the amount of total oxygen released in Mn-based DRX materials is already significantly lower when compared to Li-rich layered oxides. [49] The lack of O 2 gas release from the pre-treated sample illustrated in Figure 8 indicates that surface exposure to electrolyte tends to stabilize the oxygen based redox reaction.…”

Section: Resultsmentioning

confidence: 82%

“…For the pristine LMNOF a smooth sloped curve indicative of a single phase reaction is observed from 3 À 4:25 V vs: Li, corresponding to the removal of 0.625 moles of Li from the structure as shown previously by Chen et al [22] The second plateau beyond 4.25 V vs. Li is ascribed to an anionic oxygen based redox reaction. [45] The first charge results a total capacity of 330 mAh g À 1 . The theoretical capacity of the material based on full Li extraction from the DRX structure is approximately 347 mAh g À 1 .…”

Section: Resultsmentioning

confidence: 99%

“…LMNOF was synthesized based on a solid state high temperature route previously detailed. [20,25,45] Stoichiometric amounts of lithium carbonate (Li 2 CO 3 , 99 %, Sigma Aldrich), manganese (III) oxide (Sigma 98 % pure), niobium(V) oxide (99 %, Sigma Aldrich) and lithium fluoride (Sigma 99 % pure) were used as precursors. In order to adjust for lithium sublimation at high temperatures 10 % Li excess was used.…”

Section: Synthesismentioning

confidence: 99%

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Exposure History and its Effect Towards Stabilizing Li Exchange Across Disordered Rock Salt Interfaces

et al. 2021

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The application of lithium rich disordered rock salts (DRX) as cathode materials has greatly expanded the materials space for high energy density cathodes. These materials are able to consistently achieve capacities higher than 250 mAhg À 1 via a complex percolation based intercalation mechanism. Most current DRX materials face significant capacity fade when cycled over an extended period. One of the factors responsible for this could be deleterious side effect of interface reactions between the electrode and electrolyte at high voltage. We aim to focus on one aspect of this interaction, i.e the effect of exposure to electrolyte on the surface and its effect on the electrochemical properties of Li 1:2 Mn 0:625 Nb 0:175 O 1:95 F 0:05 (LMNOF) powder. LMNOF was systematically treated in an electrolyte solution for varying periods of time at an elevated temperature. Treated samples exhibit surface layer modification (removal of F rich surface layer), leading to a 10 % improvement in the capacity retention behavior of LMNOF. Surface and bulk based measurements indicate an increase in disorder and gradual removal of F and Li. All of these processes mimic an aging process similar to cycling. This a priori formed interface allows for increased stability with respect to retention of capacity and oxygen loss.

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Anion Reactivity in Cation‐Disordered Rocksalt Cathode Materials: The Influence of Fluorine Substitution

Cited by 46 publications

References 38 publications

Fluorination‐Enhanced Surface Stability of Cation‐Disordered Rocksalt Cathodes for Li‐Ion Batteries

Fluorination‐Enhanced Surface Stability of Cation‐Disordered Rocksalt Cathodes for Li‐Ion Batteries

Experimental considerations to study Li-excess disordered rock salt cathode materials

Exposure History and its Effect Towards Stabilizing Li Exchange Across Disordered Rock Salt Interfaces

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