Uncharted Waters: Super-Concentrated Electrolytes

Borodin, Oleg; Self, Julian; Persson, Kristin A.; Wang, Chunsheng; Xu, Kang

doi:10.1016/j.joule.2019.12.007

Cited by 348 publications

(379 citation statements)

References 115 publications

Supporting

Mentioning

373

Contrasting

Order By: Relevance

“…Hence, a key to more performant LIB cells is to improve the Li + conductivity. This can be made by either increasing the Li + mobility or the number of Li + charge carriers‐and employing highly concentrated electrolytes (HCEs) has the promise to do exactly this for LIBs by decoupling the mobility from the viscosity …”

Section: Introductionmentioning

confidence: 99%

“…no “free” solvent molecules exist. This is suggested to lead to changes in physical properties, interfacial chemistry and also alter the (Li + ) ion transport . While vehicular charge transport‐ions diffusing or migrating together with their respective solvation shells‐largely dominates in standard LIB electrolytes, Borodin and Smith showed using molecular dynamics (MD) simulation that in a 1 : 10 LiTFSI:EC electrolyte only ca .…”

Section: Introductionmentioning

confidence: 99%

“…For true HCEs, the situation is somewhat different; as there are too few solvent molecules per Li + to create a “normal” solvation shell, the Li + ions become incompletely solvated which results in both increased ion‐ion interactions and larger aggregates. In such systems, structural re‐organisation, hopping or cooperative ion transport modes are likely contributing to a larger extent . Additionally, while there is no clear picture, some studies report improved Li + transport numbers for HCEs .…”

Section: Introductionmentioning

confidence: 99%

“…In such systems, structural re‐organisation, hopping or cooperative ion transport modes are likely contributing to a larger extent . Additionally, while there is no clear picture, some studies report improved Li + transport numbers for HCEs . Altogether, this seems to render some HCEs adequate performance for LIB cells despite low total ionic conductivities .…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Interactions and Transport in Highly Concentrated LiTFSI‐based Electrolytes

et al. 2020

View full text Add to dashboard Cite

To elucidate what properties control and practically limit ion transport in highly concentrated electrolytes (HCEs), the viscosity, ionic conductivity, ionicity, and transport numbers were studied for nine model electrolytes and connected to the rate capability in Li‐ion battery (LIB) cells. The electrolytes employed the LiTFSI salt in three molar ratio concentrations; 1 : 2, 1 : 4, and 1 : 16 (LiTFSI:X) vs. solvents (X) with different permittivities; tert‐butyl methyl ether (MTBE), tetrahydrofuran (THF) and propylene carbonate (PC). While the low polarity MTBE creates liquid electrolytes, ion‐pairing limits the ionic conductivity despite extremely low viscosities. For the less concentrated 1 : 16 LiTFSI:MTBE and 1 : 16 LiTFSI:THF electrolytes the ionic diffusivities decrease with increased temperature, a sign of aggregation, but still their ionic conductivities and LIB performance increase. In general, the low ionic conductivity and high viscosity both limit the use of HCEs in LIBs, and no compensating mechanism seems to be present.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Interactions and Transport in Highly Concentrated LiTFSI‐based Electrolytes

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Nonetheless, recent works have shown how these electrolytes can be diluted with a non-coordinating fluorinated solvent to maintain the favorable aggregated ionic coordination state, all while improving viscosity and transport properties of the electrolyte and surface stability of the anode. [50,[52][53][54] Dilution also serves to reduce the bulk salt concentration down to an acceptably low value, minimizing mass and reducing overall cost while maintaining a highly aggregated coordination state. In fact, the appeal of fluorinated electrolytes has driven several investigations into their utility for low-temperature performance.…”

Section: Low-temperature Lithium-metal Batteriesmentioning

confidence: 99%

Designing Advanced Lithium‐Based Batteries for Low‐Temperature Conditions

Gupta

Manthiram

2020

Advanced Energy Materials

249

193

View full text Add to dashboard Cite

requirements over the time of use, including variable rates, and pressures, and often most critical, temperatures. [2-4] The required low-temperature capabilities, shown in Figure 1, can present a critical roadblock toward the use of lithium-ion batteries. Commercial state-of-the-art batteries see noticeable drops in capacity retention and rate capability below 0 °C, and will rarely be recommended for use below −20 °C. [5] This limitation is defined by the kinetics of ion-transfer in solution; at low-temperatures, every stage of charge-transfer, from ion diffusion within the electrolyte and electrode materials to charge-transfer across the electrode-electrolyte interfaces, is significantly impeded. Low-temperature conditions, in which the environment itself has relatively limited thermal kinetic energy available, can present significant energetic hurdles within the chemical reaction pathway normally followed during charge and discharge at room temperature. In applications with recurring exposure to low-temperature conditions, particularly electric-vehicles and space applications, there is currently heavy reliance on secondary heating solutions coupled with thermal management systems in order to ensure consistent power delivery during operation. [6] Thermal management solutions can generally be classified as either internal, with thermal management elements integrated directly within the cell itself, or external, where thermal management solutions are applied to an entire pack or module. Internal solutions, including cells with integrated AC self-heating [7] or other internal self-heating structures, [8] are generally not feasible or practical to integrate within every cell used in an application given the added weight and complexity of such systems. [9] More commonly, external heating solutions are applied including thermal heating jackets or heating elements, warm-air heating, or liquid heat-transfer approaches. While these strategies may be more feasible to implement in practice than internal solutions, they also are accompanied by added weight, greater complexity, and reduced overall energy efficiency. [7,9] In space applications, there is often a reliance on radioisotope thermal generators (RTGs), which pair a thermoelectric generator with a decaying radioactive material to ensure consistent and reliable power generation energy. The waste heat from such systems is utilized to heat secondary systems, such Energy-dense rechargeable batteries have enabled a multitude of applications in recent years. Moving forward, they are expected to see increasing deployment in performance-critical areas such as electric vehicles, grid storage, space, defense, and subsea operations. While this at first glance spells great promise for conventional lithium-ion batteries, all of these usecases, unfortunately, share periodic and recurring exposures to extremely low-temperature conditions, a performance constraint where the lithiumion chemistry can fail to perform optimally. Next-generation chemistries employing alternative anodes...

show abstract

Organic Liquid Electrolytes for Sodium‐Ion Batteries

2022

Sodium‐Ion Batteries

View full text Add to dashboard Cite

Uncharted Waters: Super-Concentrated Electrolytes

Cited by 348 publications

References 115 publications

Interactions and Transport in Highly Concentrated LiTFSI‐based Electrolytes

Interactions and Transport in Highly Concentrated LiTFSI‐based Electrolytes

Designing Advanced Lithium‐Based Batteries for Low‐Temperature Conditions

Organic Liquid Electrolytes for Sodium‐Ion Batteries

Contact Info

Product

Resources

About