LiCaFeF 6 : A zero-strain cathode material for use in Li-ion batteries

Biasi, Lea de; Lieser, Georg; Dräger, Christoph; Indris, Sylvio; Rana, Jatinkumar; Schumacher, G.; Mönig, Reiner; Ehrenberg, Helmut; Binder, Joachim R.; Geßwein, Holger

doi:10.1016/j.jpowsour.2017.07.007

Cited by 26 publications

(29 citation statements)

References 46 publications

(81 reference statements)

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“…However, the small interfacial lattice train between the two phases can gradually accumulate and finally lead to mechanical damage after long‐term cycling. [ 11 ] In contrast, the “zero‐strain” γ‐LCSVO compound with a solid‐solution reaction can efficiently avoid this issue, due to the reduced lattice distortion and strain during the solid‐solution reaction. Therefore, the solid‐solution type “zero‐strain” characteristic of γ‐LCSVO undoubtedly corresponded to its excellent cycling stability.…”

Section: Resultsmentioning

confidence: 99%

Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Liang

Yang

Han

et al. 2020

Advanced Energy Materials

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some issues, such as insufficient battery longevity, safety risks, and limited driving ranges/speeds. [1] Thus, high-performance LIBs with long-term cycle life, good safety, and high energy/power densities are pursued. Particularly, the cycle life is essential in actual applications. Capacity decay of LIBs primarily derives from the fact that electrode materials generally suffer mechanical stresses since the strains associated with phase transitions or lattice-parameter variations during Li + insertion-extraction are generally obvious. Mismatched lattice parameters between dominated and coexisting phases in two-phase reactions or large unitcell volume variations in solid-solution reactions can lead to the fracture phase interfaces, thus significantly contributing to the capacity decay. These issues can be completely avoided in "zero-strain" electrode materials whose unit-cell volume variations are negligible (<1%) during discharging-charging. Spinel Li 4 Ti 5 O 12 , a typical "zero-strain" anode material, has been demonstrated for thousands cycles in LIBs. This excellent cycling stability stems from its tiny volume variation (≈0.2%) upon cycling. [2] Other "zero-strain" anode materials, such as LiCrTiO 4 and LiY(MoO 4 ) 2 , also present decent cycling stability. [3] Clearly, "zero-strain" materials are ideal for a long operational energy storage. To the best of our knowledge, however, the very limited "zero-strain" anode materials explored for LIBs so far commonly present small reversible capacities "Zero-strain" compounds are ideal energy-storage materials for long-term cycling because they present negligible volume change and significantly reduce the mechanically induced deterioration during charging-discharging. However, the explored "zero-strain" compounds are very limited, and their energy densities are low. Here, γ phase Li 3.08 Cr 0.02 Si 0.09 V 0.9 O 4 (γ-LCSVO) is explored as an anode compound for lithium-ion batteries, and surprisingly its "zero-strain" Li + storage during Li + insertion-extraction is found through using various state-of-the-art characterization techniques. Li + sequentially inserts into the 4c(1) and 8d sites of γ-LCSVO, but its maximum unitcell volume variation is only ≈0.18%, the smallest among the explored "zero-strain" compounds. Its mean strain originating from Li + insertion is only 0.07%. Consequently, both γ-LCSVO nanowires (γ-LCSVO-NW) and micrometer-sized particles (γ-LCSVO-MP) exhibit excellent cycling stability with 90.1% and 95.5% capacity retention after as long as 2000 cycles at 10C, respectively. Moreover, γ-LCSVO-NW and γ-LCSVO-MP respectively deliver large reversible capacities of 445.7 and 305.8 mAh g −1 at 0.1C, and retain 251.2 and 78.4 mAh g −1 at 10C. Additionally, γ-LCSVO shows a suitably safe operating potential of ≈1.0 V, significantly lower than that of the famous "zero-strain" Li 4 Ti 5 O 12 (≈1.6 V). These merits demonstrate that γ-LCSVO can be a practical anode compound for stable, high-energy, fast-charging, and safe Li + storage.The ORCID identificati...

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Section: Resultsmentioning

confidence: 99%

Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Liang

Yang

Han

et al. 2020

Advanced Energy Materials

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“…[ 137 ] For most electrodes, the volume change will take place during lithiation and delithiation process ( Figure 13 A). [ 138 ] During lithiation process, the active material undergone crystal expansion. Mechanical degradation of SEs was caused by intercalation‐induced expansion of electrode particles, within the constrain of a dense solid‐state electrode.…”

Section: Cathode/garnet Interfacementioning

confidence: 99%

Interfaces in Garnet‐Based All‐Solid‐State Lithium Batteries

Wang

Zhu

et al. 2020

Advanced Energy Materials

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liquid electrolytes. ASSLBs exhibit overwhelming advantages as follows: 1) No electrolyte leakage. The most obvious advantage of ASSLBs is the avoidance of electrolyte leakage, and related issues such as fire hazard, electrical short circuit and corruption. In addition, ASSLBs do not need advance sealants, pressurizing electrolyte, and flame retardant failsafe. [1,2] 2) No thermal runaway. Thermal runaway will cause the rise of internal temperature, pressure, and vent of flammable gases in conventional LIBs, at a risk of explosion and shrapnel. [3,4] ASSLBs avoid the use of organic electrolytes and prevent the thermal runaway for a large extent. [5] 3) High resistance to lithium dendrite. The lithium dendrite may form during deposition process and penetrate through the separator, potentially cause a short circuit in conventional LIBs. [6] ASSLBs using solid electrolytes (SEs) with high shear modulus are expected to prevent/alleviate the dendrite penetration and extend the cell life. 4) Higher energy density. [7] The conventional LIBs are not suitable for the application of high voltage cathode and lithium metal anode because of narrow electrochemical window of liquid electrolytes, as well as failure in preventing lithium dendrite. ASSLBs facilitate the application of high voltage cathode materials and high energy density lithium metal anode, therefore increasing the energy density of the whole cell. Figure 1 shows the scheme of a typical ASSLB. Similar with conventional LIBs, the main components of ASSLB are cathode, SE, and anode. The distinctive component is SE, and its properties support the great advantages of ASSLBs. These properties include stability at ultrahigh and ultralow temperature, high mechanical strength, [8] wider electrochemical window (with passivation), and so on. [9-11] According to the category of SE, ASSLBs are divided into polymer-based, oxide-based, and sulfide-based systems, corresponding to the polymer, oxide, and sulfide electrolytes, respectively. Therein, oxide electrolytes exhibit moderate ionic conductivity, high shear modulus, and better stability with atmosphere and electrodes, are promising candidates for ASSLB. Specifically, oxide electrolytes are classified into LISICON (Li 14 ZnGe 4 O 16), NASICION (LiTi 2 (PO 4) 3), perovskite (Li 3x La 0.67-x □ 0.33-2x TiO 3), garnet (Li 3-7 LnMO 12 , Ln = Y, Pr, Nd, La, Sm-Lu, M = Zr, Sb, W, etc.), and so on based on their structure. Without reductive Ge, Ti elements in the composition, garnets are normally considered most promising among oxide electrolytes. [12,13] Garnet-type electrolytes in the formula of Li 3-7 Ln 3 M 2 O 12 , show a space group 3 Ia d. Lithium content ranges from 3 to 7 based on the substitution elements at Ln and M sites. [14,15] All-solid-state lithium batteries (ASSLBs) are considered to be the nextgeneration energy storage system, because of their overwhelming advantages in energy density and safety compared to conventional lithium ion batteries. Among various systems, garnet-based ASSLBs are one of the most promis...

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“…16,17 Thus far, only a few zero-strain materials have been reported. [18][19][20][21][22][23][24][25][26] These materials showed very small or no change in lattice dimension during lithium or sodium insertion/extraction. Their crystal structures have a large space that can accommodate Li ions, which effectively suppresses dimensional change during lithium insertion.…”

Section: Introductionmentioning

confidence: 95%

“…The volumetric capacity and dimensional change of zerostrain Li2Ni0.2Co1.8O4 was compared with those of other lithium insertion materials (Figure 13). 10,[18][19][20]22,24,36,[40][41][42][43][44] All zero-strain materials except LTO has a crystal structure with a large space that can accommodate Li ions. Such a large space is expected to reduce lattice distortion during lithium insertion/extraction, leading to a small dimensional change.…”

Section: Introductionmentioning

confidence: 99%

Li₂Ni_0.2Co_1.8O₄ having a spinel framework as a zero-strain positive electrode material for lithium-ion batteries

et al. 2019

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LiCaFeF 6 : A zero-strain cathode material for use in Li-ion batteries

Cited by 26 publications

References 46 publications

Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Interfaces in Garnet‐Based All‐Solid‐State Lithium Batteries

Li₂Ni_0.2Co_1.8O₄ having a spinel framework as a zero-strain positive electrode material for lithium-ion batteries

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LiCaFeF 6 : A zero-strain cathode material for use in Li-ion batteries

Cited by 26 publications

References 46 publications

Conductive Li3.08Cr0.02Si0.09V0.9O4 Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li+ Storage

Conductive Li3.08Cr0.02Si0.09V0.9O4 Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li+ Storage

Interfaces in Garnet‐Based All‐Solid‐State Lithium Batteries

Li2Ni0.2Co1.8O4 having a spinel framework as a zero-strain positive electrode material for lithium-ion batteries

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Product

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Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Conductive Li_3.08Cr_0.02Si_0.09V_0.9O₄ Anode Material: Novel “Zero‐Strain” Characteristic and Superior Electrochemical Li⁺ Storage

Li₂Ni_0.2Co_1.8O₄ having a spinel framework as a zero-strain positive electrode material for lithium-ion batteries