Xiaoxin Xie scite author profile

The relatively narrowe lectrochemical steady windowa nd low ionic conductivity are two critical challenges for Li + -conducting solid polymer electrolytes (SPE). Here,afamily of poly-oxalate(POE) structures were prepared as SPE; among them, POEs composed from diols with an odd number of carbons show higher ionic conductivity than those composed from diols with an even number of carbons,a nd the POE composed from propanediol (C5-POE) has the highest Li + conductivity.T he HOMO (highest occupied molecular orbital) electrons of POE were found located on the terminal units.W hen using trifluoroacetate as the terminating unit (POE-F), not only does the HOMO become more negative, but also the HOMO electrons shift to the middle oxalate units, improving the antioxidative capability.F urthermore,t he interfacial compatibility across the Li-metal/POE-F is also improved by the generation of aL iF-based solid-electrolyteinterlayer(SEI). With the trifluoroacetate-terminated C5-POE (C5-POE-F) as the electrolyte and Li + -conducting binder in the cathode,t he all-solid-state Li/LiNi 0.8 Mn 0.1 Co 0.1 O 2 -(NMC811) cells showed significantly improved stability than the counterpart with poly-ether,p roviding ap romising candidate for the forthcoming all-solid-state high-voltage Li-metal batteries.

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Impressive Proton Conductivities of Two Highly Stable Metal–Organic Frameworks Constructed by Substituted Imidazoledicarboxylates

Xie

Zhang

et al. 2019

Inorg. Chem.

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There is great interest in the promising applications of proton-conductive metal–organic frameworks (MOFs) in the field of electrochemistry. Thus, seeking more types of MOFs with high proton conductivity is of great importance. Herein, we designed and prepared two substituted imidazoledicarboxylate-based MOFs, {[Cd(p-TIPhH2IDC)2]·H2O} n [1; p-TIPhH3IDC = 2-p-(1H-1,2,4-triazolyl)phenyl-1H-4,5-imidazoledicarboxylic acid] and [Sr(DMPhH2IDC)2] n [2; DMPhH3IDC = 2-(3,4-dimethylphenyl)-1H-imidazole-4,5-dicarboxylic acid], and fully explored their water-assisted proton conduction. The best conductivity for 1 of 1.24 × 10–4 S·cm–1 is higher than that of most previous conductive Cd-MOFs under similar conditions. 2 has the highest conductivity (0.92 × 10–3 S·cm–1) among the reported conductive Sr-MOFs. Via structural analysis, E a values, water vapor adsorptions, and powder X-ray diffraction and scanning electron microscopy tests, reasonable proton pathways and conduction mechanisms were highlighted. It should be emphasized that the N-heterocyclic units (imidazole and triazole) and carboxyl and hydrogen-bonding networks in the frameworks all play crucial roles in the transmission of proton conductivity. Our research offers more choice for the preparation of desired proton-conductive materials.

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Recent Progress of Polymer Electrolytes for Solid-State Lithium Batteries

Xie

et al. 2023

ACS Sustainable Chem. Eng.

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The critical challenges for lithium-ion batteries today are how to improve the energy densities and solve the safety issues, which can be addressed through the construction of solid-state lithium metal batteries with solid polymer electrolytes (SPEs). Significant efforts have been devoted to the design and synthesis of SPEs, in which their electrochemical windows and corresponding compatibilities with both electrodes are crucial, particularly when taking high-voltage transition metal oxides as cathodes. In this review, the SPEs with different electrochemical windows are summarized and categorized, including (i) anode stable SPEs with good lithium metal compatibilities, (ii) cathode stable SPEs with good oxidation resistances, (iii) multilayer SPEs simultaneously withstanding reduction of a lithium anode and oxidation at high voltage. The impacts of polymer molecular structures and compositions on the SPE properties and performance are discussed. The development of high-performance SPEs that can stabilize or form stable interfacial passivation layers with both cathodes and anodes simultaneously is the desired candidate of future applications.

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Influencing Factors on Li‐ion Conductivity and Interfacial Stability of Solid Polymer Electrolytes, Exampled by Polycarbonates, Polyoxalates and Polymalonates

Xie

Wang

et al. 2023

Angew Chem Int Ed

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The application of solid polymer electrolytes (SPEs) in all‐solid‐state(ASS) batteries is hindered by lower Li+‐conductivity and narrower electrochemical window. Here, three families of ester‐based F‐modified SPEs of poly‐carbonate (PCE), poly‐oxalate (POE) and poly‐malonate (PME) were investigated. The Li+‐conductivity of these SPEs prepared from pentanediol are all higher than the counterparts made of butanediol, owing to the enhanced asymmetry and flexibility. Because of stronger chelating coordination with Li+, the Li+‐conductivity of PME and POE is around 10 and 5 times of PCE. The trifluoroacetyl‐units are observed more effective than −O−CH2−CF2−CF2−CH2−O− during the in situ passivation of Li‐metal. Using trifluoroacetyl terminated POE and PCE as SPE, the interfaces with Li‐metal and high‐voltage‐cathode are stabilized simultaneously, endowing stable cycling of ASS Li/LiNi0.6Co0.2Mn0.2O2 (NCM622) cells. Owing to an enol isomerization of malonate, the cycling stability of Li/PME/NCM622 is deteriorated, which is recovered with the introduce of dimethyl‐group in malonate and the suppression of enol isomerization. The coordinating capability with Li+, molecular asymmetry and existing modes of elemental F, are all critical for the molecular design of SPEs.

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Xiaoxin Xie

Proton conductive carboxylate-based metal–organic frameworks

Fluorinated Poly‐oxalate Electrolytes Stabilizing both Anode and Cathode Interfaces for All‐Solid‐State Li/NMC811 Batteries

Impressive Proton Conductivities of Two Highly Stable Metal–Organic Frameworks Constructed by Substituted Imidazoledicarboxylates

Recent Progress of Polymer Electrolytes for Solid-State Lithium Batteries

Influencing Factors on Li‐ion Conductivity and Interfacial Stability of Solid Polymer Electrolytes, Exampled by Polycarbonates, Polyoxalates and Polymalonates

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