Structure-Activity Relationships in Ether-Functionalized Solid-State Metal-Organic Framework Electrolytes

ATY Mu and VV Singh and H Kim and DJ Lee and N Kim and CX Ruff and A Levy and TA Young and F Paesani and SM Cohen and TA Pascal and Z Chen, CHEMISTRY OF MATERIALS, 37, 2783-2794 (2025).

DOI: 10.1021/acs.chemmater.4c03384

The structure-property relationships of metal-organic framework (MOF)-based solid-state electrolytes are not well understood. Herein, a systematic investigation of 12 Zr(IV)-based UiO-66 MOFs with varying ether-chain functional groups was carried out to elucidate the critical microscopic interactions that facilitate improved solid-state electrolyte performance. Enhanced sampling molecular dynamics (MD) simulations were employed and revealed a three-tier ion hopping mechanism: linker-linker hopping, linker-counterion hopping, and counterion-counterion hopping. Detailed structural analysis of the MD trajectories revealed that the chemistry and morphology of the linker groups affect the relative stability and population distribution of the electrolyte components, such that crown-ether-based linker groups enhance the probability of extended, low-barrier ion percolation pathways. As a result, we were able to tune the ionic conductivities by rationally manipulating the counterion distributions, linker binding strengths, and the configurational entropy (multivariability of the linkers). The resulting performance of these MOF-based solid-state electrolytes was significantly enhanced, with a methoxy-functionalized framework (UiO-66-L1 100 ) achieving high ionic conductivities of 2.32 x 10-4 S/cm and 2.07 x 10-3 S/cm at 30 degrees C and 90 degrees C, respectively, an order of magnitude greater than other all-solid-state MOF electrolyte systems. The electrolyte stability was evaluated with LiIn|LPSCl|MOF:LiTFSI|LPSCl|LiIn symmetric cells, showing excellent Li plating/stripping processes for over 2 months.

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