Probing the Electrode–Electrolyte Interface of Sodium/Glyme-Based Battery Electrolytes

Senadheera, Dodangodage Ishara; Carrillo-Bohorquez, Orlando; Nachaki, Ernest O.; Jorn, Ryan; Kuroda, Daniel G.; Kumar, Revati

doi:10.1021/acs.jpcc.3c08083

J. Phys. Chem. C

2024

DOI: 10.1021/acs.jpcc.3c08083

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Probing the Electrode–Electrolyte Interface of Sodium/Glyme-Based Battery Electrolytes

Dodangodage Ishara Senadheera,

Orlando Carrillo-Bohorquez,

Ernest O. Nachaki

et al.

Abstract: Sodium-ion batteries (NIBs) are promising systems for large-scale energy storage solutions; yet, further enhancements are required for their commercial viability. Improving the electrochemical performance of NIBs goes beyond the chemical description of the electrolyte and electrode materials as it requires a comprehensive understanding of the underlying mechanisms that govern the interface between electrodes and electrolytes. In particular, the decomposition reactions occurring at these interfaces lead to the … Show more

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Cited by 3 publications

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Direct observation of sodium dendrites to decipher the complicated behavior of electrolyte systems

Yadav,

Soni,

Bera

et al. 2024

Electrochimica Acta

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Direct observation of sodium dendrites to decipher the complicated behavior of electrolyte systems

Yadav,

Soni,

Bera

et al. 2024

Electrochimica Acta

View full text Add to dashboard Cite

The Challenge of Characterizing High-Concentration Electrolytes at the Molecular Level: A Perspective

Carrillo-Bohórquez,

Kumar,

Kuroda

2024

J. Phys. Chem. C

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High-concentration electrolytes (HCEs) are promising materials composed of highly concentrated salt solutions in organic solvents. HCEs have many desirable properties and are particularly important in the field of batteries. However, the number of ways in which these materials can be tuned is very large, which is crucial for tailored electrolyte design. Moreover, the molecular characterization of HCEs is challenging both experimentally and computationally, but it is necessary for their rational design. Therefore, currently the structure−property−performance relationship of these electrolytes has not been directly derived from their characterization. In this Perspective we present a brief overview of the HCEs and discuss the state-of-the-art characterization methods used to study them at the molecular level. We also address the challenges associated with these methods, including both experimental techniques and computational tools currently available. Emphasis is placed on methods aimed at understanding the physical phenomena that govern the molecular structure and dynamics occurring on the subnanosecond and nanometer time and length scales. Finally, we discuss new strategies for obtaining a comprehensive characterization of HCEs at the molecular level.

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A transferable classical force field to describe glyme based lithium solvate ionic liquids

Carrillo-Bohórquez,

Kuroda,

Kumar

2024

The Journal of Chemical Physics

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A non-polarizable force field for lithium (Li+) and bis(trifluoromethanesulfonyl)imide (TFSI−) ions solvated in diglyme at around 0.2 mol fraction salt concentration was developed based on ab initio molecular dynamics (AIMD) simulations and a modified polymer consistent force field model. A force–torque matching based scheme, in conjunction with a genetic algorithm, was used to determine the Lennard-Jones (LJ) parameters of the ion–ion and ion–solvent interactions. This force field includes a partial charge scaling factor and a scaling factor for the 1–4 interactions. The resulting force field successfully reproduces the radial distribution function of the AIMD simulations and shows better agreement compared to the unmodified force field. The new force field was then used to simulate salt solutions with glymes of increasing chain lengths and different salt concentrations. The comparison of the MD simulations, using the new force field, with experimental data at different salt concentrations and AIMD simulations on equimolar concentrations of the triglyme system demonstrates the transferability of the force field parameters to longer glymes and higher salt concentrations. Furthermore, the force field appears to reproduce the features of the experimental x-ray structure factors, suggesting accuracy beyond the first solvation shell, for equimolar salt solutions using both triglyme and tetraglyme as the solvent. Overall, the new force field was found to accurately reproduce the molecular descriptions of LiTFSI-glyme systems not only at various salt concentrations but also with glymes of different chain lengths. Thus, the new force field provides a useful and accurate tool to perform in silico studies of this family of systems at the atomistic level.

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Probing the Electrode–Electrolyte Interface of Sodium/Glyme-Based Battery Electrolytes

Cited by 3 publications

References 61 publications

Direct observation of sodium dendrites to decipher the complicated behavior of electrolyte systems

Direct observation of sodium dendrites to decipher the complicated behavior of electrolyte systems

The Challenge of Characterizing High-Concentration Electrolytes at the Molecular Level: A Perspective

A transferable classical force field to describe glyme based lithium solvate ionic liquids

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