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Unravelling the structural and dynamical complexity of the equilibrium liquid grain-binding layer in highly conductive organic crystalline electrolytes

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dc.contributor.author VENKATNATHAN, ARUN en_US
dc.contributor.author Prakash, Prabhat et al. en_US
dc.date.accessioned 2019-09-09T11:36:43Z
dc.date.available 2019-09-09T11:36:43Z
dc.date.issued 2018-02 en_US
dc.identifier.citation Journal of Materials Chemistry A, 6 (10), 4394-4404. en_US
dc.identifier.issn 2050-7488 en_US
dc.identifier.issn 2050-7496 en_US
dc.identifier.uri http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/3984
dc.identifier.uri https://doi.org/10.1039/C7TA10367K en_US
dc.description.abstract Recent developments in organic crystalline electrolytes for lithium and sodium ion conduction have demonstrated bulk conductivities in the range of 10−4 S cm−1 with negligible grain boundary resistance. Experimental results from EM, XRD, and DSC point to a liquid boundary layer at the crystalline surface in equilibrium with the bulk solid that conducts ions between the grains. In this report we examine this behavior in the electrolyte DMF·LiCl (DMF = N,N-dimethylformamide), which has a bulk conductivity of 1.6 × 10−4 S cm−1, but which decomposes between 360–380 K. Molecular dynamics simulations predict a number of quantitative parameters consistent with experimental observation, such as decomposition temperature (Td(theor) = 380 K, Td(obs) = 360 K), bulk conductivity (σheor = 7 × 10−4, σobs = 1.6 × 10−4) and density (dtheor = 1.209 g mL−1, dobs = 1.306 g mL−1). Further, a number of qualitative properties of the material are predicted by simulation, namely, the crystal packing arrangement, the mechanism of decomposition by expulsion of DMF from the LiCl lattice, the existence of a liquid-like grain boundary layer, and most importantly, negligible grain boundary resistance from increased mobility of ions in the boundary layer vs. the bulk. Finally, from quantum mechanical calculations, various interaction energies between fragmental components explain lattice stability and decomposition of the co-crystal, and highlight the contributions from various possible small aggregates. The theoretical calculations predict decomposition of smaller aggregates, such as those expected in the liquid-like surface, to be more facile than larger aggregates that are more likely to be found in the crystal interior. en_US
dc.language.iso en en_US
dc.publisher Royal Society of Chemistry en_US
dc.subject Unravelling the structural en_US
dc.subject Dynamical complexity en_US
dc.subject Equilibrium liquid grain-binding layer en_US
dc.subject Highly conductive en_US
dc.subject Organic crystalline en_US
dc.subject Electrolytes en_US
dc.subject 2018 en_US
dc.title Unravelling the structural and dynamical complexity of the equilibrium liquid grain-binding layer in highly conductive organic crystalline electrolytes en_US
dc.type Article en_US
dc.contributor.department Dept. of Chemistry en_US
dc.identifier.sourcetitle Journal of Materials Chemistry A en_US
dc.publication.originofpublisher Foreign en_US


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