Taming Active Material-Solid Electrolyte Interfaces with Organic Cathode for All-Solid-State Batteries

Fang, Hao; Chi, Xiaowei; Liang, Yanliang; Zhang, Ye; Xu, Rong; Guo, Hua; Terlier, Tanguy; Dong, Hui; Zhao, Kejie; Lou, Jun; Yao, Yan

doi:10.1016/j.joule.2019.03.017

Cited by 74 publications

(87 citation statements)

References 50 publications

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“…Specific energy in W h kg cathode À1 is exhibited as a product of specific discharge capacity and average discharge cell voltage, as recently proposed to enable performance comparison of all-solid-state batteries between different studies and cell chemistries. 2 Each color symbolizes the SEs used: oxides/polymers (blue), [66][67][68][69] sulfides (green), 21,23,[70][71][72] and hydroborates (orange and red). 41 Fig.…”

Section: Energy and Environmental Science Papermentioning

confidence: 99%

“…6 Comparison of state-of-the-art all-solid-state sodium and lithium battery performance. Specific discharge capacity, average discharge cell voltage, and operating voltage range are plotted for all-solid-state cells exhibiting 480% capacity retention for Z100 cycles, using insertion-type cathode active materials and SEs based on oxides/polymers (blue), [66][67][68][69] sulfides (green), 21,23,[70][71][72] and hydroborates (orange and red). 41 Each specific discharge capacity, normalized by the cathode composite weight in sodiated or lithiated states, 2 was measured at C/10, except for NCM60|Li, NCM75|Li, and NaFePO 4 |hard carbon at C/5, and for Na 4 PTO|Na-Sn at C/7.4 (= C/10 for PTO).…”

Section: Materials Characterizationmentioning

confidence: 99%

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4 V room-temperature all-solid-state sodium battery enabled by a passivating cathode/hydroborate solid electrolyte interface

Asakura

Reber

Duchêne

et al. 2020

Energy Environ. Sci.

105

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Section: Energy and Environmental Science Papermentioning

confidence: 99%

Section: Materials Characterizationmentioning

confidence: 99%

4 V room-temperature all-solid-state sodium battery enabled by a passivating cathode/hydroborate solid electrolyte interface

Asakura

Reber

Duchêne

et al. 2020

Energy Environ. Sci.

105

View full text Add to dashboard Cite

show abstract

“…The Young's modulus of PTO, which is two orders of magnitude smaller than many metal‐oxide‐based cathodes (100–200 GPa), can effectively reduce the mechanical stress during cell cycling and prevent the loss of interparticle mechanical contact with the electrolyte. The soft mechanical properties of PTO compounds will be advantageous for the fabrication of flexible or stretchable battery electrodes . Secondly, the rigid skeleton connected by B 3 O 3 moieties facilitates the stabilization of the porous structure and allows the quick diffusion of lithium ions.…”

Section: Introductionmentioning

confidence: 99%

Two‐Dimensional (2D) Covalent Organic Framework as Efficient Cathode for Binder‐free Lithium‐Ion Battery

et al. 2019

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Searching new organic cathode materials to address the issues of poor cycle stability and low capacity in lithium ion batteries (LIBs) is very important and highly desirable. In this research, a 2D boroxine‐linked chemically‐active pyrene‐4,5,9,10‐tetraone (PTO) covalent organic framework (2D PPTODB COFs) was synthesized as an organic cathode material with remarkable electrochemical properties, including high electrochemical activity (four redox electrons), safe oxidation potential window (between 2.3 and 3.08 V vs. Li/Li+), superb structural/chemical stability, and strong adhesiveness. A binder‐free cathode was obtained by mixing 70 wt % PPTODB and 30 wt % carbon nanotubes (CNTs) as a conductive additive. Promoted by the fast kinetics of electrons/ions, high electrochemical activity, and effective π–π interaction between PPTODB and CNTs, LIBs with the as‐prepared cathode exhibited excellent electrochemical performance: a high specific capacity of 198 mAh g−1, a superb rate ability (the capacity at 1000 mA g−1 can reach 76 % of the corresponding value at 100 mA g−1), and a stable coulombic efficiency (≈99.6 % at the 150th cycle). This work suggests that the concept of binder‐free 2D electroactive materials could be a promising strategy to approach energy storage with high energy density.

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“…Here, in situ EIS of the first two cycles were performed to gain a detailed understanding of the interfacial resistance mechanism in solid‐state batteries (Supporting Information, Figures S10, S11). The initial discharge cycle is shown in Figure A and the evolution of the impedance spectra at the different DOD are illustrated in Figure B . To improve understanding the evolving interfacial resistance mechanism in solid‐state battery electrode, a series of solid‐state batteries at different discharging states were dissembled and the morphologies of FeS 2 composite electrodes were investigated with SEM (Figure C).…”

Section: Resultsmentioning

confidence: 99%

“…Thei nitial discharge cycle is shown in Figure 5A and the evolution of the impedance spectra at the different DOD are illustrated in Figure 5B. [23] To improve understanding the evolving interfacial resistance mechanism in solid-state battery electrode,aseries of solid-state batteries Figure 4. 2D cross-section mapping and heterogeneous phase conversion.…”

Section: Interfacial Resistance Mechanism and Physical Contact Lossmentioning

confidence: 99%

Anisotropically Electrochemical–Mechanical Evolution in Solid‐State Batteries and Interfacial Tailored Strategy

et al. 2019

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All‐solid‐state batteries have attracted attention owing to the potential high energy density and safety; however, little success has been made on practical applications of solid‐state batteries, which is largely attributed to the solid–solid interface issues. A fundamental elucidation of electrode–electrolyte interface behaviors is of crucial significance but has proven difficult. The interfacial resistance and capacity fading issues in a solid‐state battery were probed, revealing a heterogeneous phase transition evolution at solid–solid interfaces. The strain‐induced interfacial change and the contact loss, as well as a dense metallic surface phase, deteriorate the electrochemical reaction in solid‐state batteries. Furthermore, the in situ growth of electrolytes on secondary particles is proposed to fabricate robust solid–solid interface. Our study enlightens new insights into the mechanism behind solid–solid interfacial reaction for optimizing advanced solid‐state batteries.

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Taming Active Material-Solid Electrolyte Interfaces with Organic Cathode for All-Solid-State Batteries

Cited by 74 publications

References 50 publications

4 V room-temperature all-solid-state sodium battery enabled by a passivating cathode/hydroborate solid electrolyte interface

4 V room-temperature all-solid-state sodium battery enabled by a passivating cathode/hydroborate solid electrolyte interface

Two‐Dimensional (2D) Covalent Organic Framework as Efficient Cathode for Binder‐free Lithium‐Ion Battery

Anisotropically Electrochemical–Mechanical Evolution in Solid‐State Batteries and Interfacial Tailored Strategy

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