Communication: Conductivity enhancement in plastic-crystalline solid-state electrolytes

Geirhos, Korbinian; Lunkenheimer, P.; Michl, M.; Reuter, D.; Loidl, A.

doi:10.1063/1.4929554

Cited by 33 publications

(117 citation statements)

References 30 publications

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“…5), 16 the dc conductivity for all mixtures investigated in the present study is significantly higher than for the pure SN doped with the same percentage of Li salt (inverted triangles; this data set was remeasured here up to higher temperatures than previously reported in Ref. 16). At high temperatures in the PC phase,  dc is found to considerably increase with increasing molecule size.…”

Section: Sn-ansupporting

confidence: 62%

“…48 In addition to the right flank of the -relaxation peak, in The occurrence of such secondary relaxation peaks is typical for glass-forming liquids 49,50,51 and also found for certain PCs, 19 including various SN-GN mixtures. 16,25,26 A detailed treatment of this feature is out of the scope of the present work.…”

Section: Sn-mnmentioning

confidence: 99%

“…25,26 This enables the observation of glassy freezing of the orientational disorder below about 150 K, leading to a so-called glassy-crystal state (sometimes also termed "orientational glass"). In an earlier work, 16 we have reported dielectric-spectroscopy measurements of SN-GN mixtures with different mixing ratios of up to 80 mol% GN. These experiments revealed successively stronger coupling of molecular reorientation and ionic translation with increasing GN content.…”

Section: Introductionmentioning

confidence: 99%

“…This finding indicates that the mentioned conductivity enhancement of the mixtures can be explained by a "revolving door" or "paddle wheel" mechanism 10,11.27 which becomes optimized when part of the smaller SN molecules is replaced by the larger GN molecules. 16 Within this scenario, the molecule reorientations are assumed to provide transient free volume within the lattice, thus enhancing the ionic mobility. Quite generally, it is often assumed that the typical reorientational motions of the molecules or ions in PCs facilitate translational ionic hopping, thus explaining the high ionic conductivity of many members of this material class.…”

Section: Introductionmentioning

confidence: 99%

“…In the present work, we provide a detailed study of the ionic conductivity and reorientational dynamics of binary mixtures of SN with MN, AN, and pimelonitrile [C 5 H 10 (CN) 2 ; PN] using dielectric spectroscopy. In particular, we have investigated SN 0.85 X 0.15 mixtures (with X = MN, AN, or PN) where 1% LiPF 6 was added to enable a direct comparison to the results of our previous report 16 where the same salt admixture was used. This leads to the overall composition (SN 0.85 X 0.15 ) 0.99 (LiPF 6 ) 0.01 It should be noted that the present study does not aim at achieving exceptionally high values of ionic conductivity (here different salts and higher concentrations may be more favorable 2 ) but, instead, intends to contribute to a better understanding of the fundamental aspects of ion conduction in such mixed PC systems.…”

Section: Introductionmentioning

confidence: 99%

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Plastic-crystalline solid-state electrolytes: Ionic conductivity and orientational dynamics in nitrile mixtures

Reuter

Lunkenheimer

Loidl

2019

The Journal of Chemical Physics

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Many plastic crystals, molecular solids with long-range, center-of-mass crystalline order but dynamic disorder of the molecular orientations, are known to exhibit exceptionally high ionic conductivity. This makes them promising candidates for applications as solid-state electrolytes, e.g., in batteries. Interestingly, it was found that the mixing of two different plasticcrystalline materials can considerably enhance the ionic dc conductivity, an important benchmark quantity for electrochemical applications. An example is the admixture of different nitriles to succinonitrile, the latter being one of the most prominent plastic-crystalline ionic conductors. However, until now only few such mixtures were studied. In the present work, we investigate succinonitrile mixed with malononitrile, adiponitrile, and pimelonitrile, to which 1 mol% of Li ions were added. Using differential scanning calorimetry and dielectric spectroscopy, we examine the phase behavior and the dipolar and ionic dynamics of these systems. We especially address the mixing-induced enhancement of the ionic conductivity and the coupling of the translational ionic mobility to the molecular reorientational dynamics, probably arising via a "revolving-door" mechanism. ____________________________________________________________________________________________________________

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Section: Sn-ansupporting

confidence: 62%

Section: Sn-mnmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plastic-crystalline solid-state electrolytes: Ionic conductivity and orientational dynamics in nitrile mixtures

Reuter

Lunkenheimer

Loidl

2019

The Journal of Chemical Physics

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Exploring Dipolar Dynamics and Ionic Transport in Metal‐Organic Frameworks: Experimental and Theoretical Insights

Freund,

Schulz,

Lunkenheimer

et al. 2024

Adv Funct Materials

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The present study examines the potential coupling between dipolar dynamics and ionic charge transport in metal‐organic framework (MOF) compounds. MOFs are known for their high porosity and customizable properties. By integrating freely rotating dipolar groups into the ligands, a novel structure, CFA‐25, akin to the known BUT‐2 framework, is synthesized. This facilitated the investigation of local and macroscopic effects, particularly the possible interplay between dipolar units and Cs cations. The research aimed to understand fundamental dipolar dynamics and ionic charge transport, employing Cs ions for their X‐ray diffraction characterizability. Experimental analysis using dielectric spectroscopy, complemented by theoretical simulations, explored questions regarding glassy freezing of re‐orientational dynamics, Cs cation motion within the network, and the influence of dipolar units on transport. Contrary to previous reports, this work finds that Cs transport exhibits substantial barriers, necessitating specialized simulation techniques for accurate characterization. This interdisciplinary approach sheds light on the intricate dynamics of MOFs and offers insights into their potential applications involving ion transport phenomena.

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A New Version of the Lithium Ion Conducting Plastic Crystal Solid Electrolyte

Klein

Zhao

Davidowski

et al. 2018

Advanced Energy Materials

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Excluding aqueous solutions, the highest ambient temperature conductivities of lithium containing materials have been found, not in liquid, but in glassy, mixed glass-crystal and crystal phases. The partly recrystallized thiophosphate glass reported by Tatsumisago and co-workers [3] exhibited an ambient temperature conductivity of a remarkable 17 mS cm −1 , significantly higher than the highest reported in nonaqueous electrolyte solutions, and that has now been exceeded by a chlorinecontaining variant of the Kamaya et al. thiophosphogermanate superionic crystal [4] that exhibits σ 25 °C = 25 mS cm −1 . [5] Part of the success of these solid electrolytes is due to the fact that the alkali cation is now, not only the most mobile ion, but usually the only mobile ion. However, as rigid materials, they tend to be mechanically fragile and are prone to encounter junction problems with anode and cathode materials. Excellent cell performance has nonetheless been reported. [5] An alternative approach that avoids the liquid state is to dissolve salts in plastic crystal phases. Two types of plastic crystal solvents have been explored: (i) molecular solvent [6,7] (succinonitrile (SSN) in which a salt like LiN(Tf) 2 is dissolved) and (ii) organic cation salts in which salts like LiBF 4 and LiN(Tf) 2 are dissolved, of which many variants [8][9][10] have been employed. Although it was not mentioned in the initial publication, [6] the success of the plastic crystal state as a solvent lies primarily in the ability of the molecular solvent (or molecular ions), to reorient on short time scales (t reor ≈0.1 ns in the case of SSN [11] ) thus providing a high entropy medium within which the ions enjoy high mobility. While each case has been considered successful, the disadvantage of each is that the Li + species proves to be the least mobile species. This is because, due to its high charge radius ratio, the Li cation dominates competition for ligands and "digs itself a hole" in the same way as it does in a typical nonaqueous molecular liquid electrolyte. A consequence is low mobility of the electroactive species relative to others, and consequent polarization problems during operation at high currents.It is against this backdrop that we have sought to develop an improved type of ambient temperature plastic crystal ion conductor, one in which the only mobile species is the alkali cation so that (as in superionic glasses and crystals) the conductivity Portable electronic devices are predominantly powered by lithium ion batteries in which the electrolyte is a liquid or gel of lithium salts dissolved in molecular solvents. There have been many attempts to replace the flammable liquid component of the electrolyte by alternative alkali metal transporting media, such as superionic crystals, alkali-conducting glassy solids, ionic liquids, saltin-molecular plastic crystal solvent, and salt-in-ionic plastic crystal solvents. Except for the first two of the above, which have their own problems, all the above have the disadvantage that the alkali ...

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Communication: Conductivity enhancement in plastic-crystalline solid-state electrolytes

Cited by 33 publications

References 30 publications

Plastic-crystalline solid-state electrolytes: Ionic conductivity and orientational dynamics in nitrile mixtures

Plastic-crystalline solid-state electrolytes: Ionic conductivity and orientational dynamics in nitrile mixtures

Exploring Dipolar Dynamics and Ionic Transport in Metal‐Organic Frameworks: Experimental and Theoretical Insights

A New Version of the Lithium Ion Conducting Plastic Crystal Solid Electrolyte

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