Vinylene Carbonate as Co-Solvent for Low-Temperature Mixed Electrolyte Based Supercapacitors

Väli, R.; Jänes, Alar; Lust, Enn

doi:10.1149/2.0541606jes

Cited by 21 publications

(15 citation statements)

References 33 publications

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“…The QRNN computed density, Hvap and CV for each of the pure solvents are in excellent agreement with the experimental data 21,[48][49][50][51][52][53][54][55][56] as shown in Figure 2 (a), (b) and (c), respectively. Similarly, the OPLS4 gives good predictions of the density and the heat of vaporization for all the solvents but overestimates the Cv values as compared to experimental data 21,[48][49][50][51][52][53][54][55][56] .…”

Section: Thermodynamic and Transport Properties Of Liquid Carbonate S...supporting

confidence: 79%

High-dimensional neural network potential for liquid electrolyte simulations

Dajnowicz

Agarwal

Stevenson

et al. 2022

Preprint

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Liquid electrolytes are the most common electrolyte classes used in Li-ion batteries, which are a critical technology of the modern world. However, we still lack the computational tools required to accurately calculate key properties of these materials (viscosity, ionic diffusivity) from first principles necessary to sup-port improved designs. In this work, we report a machine learning-based force field for liquid electrolyte simulations which bridges the gap between the accuracy of range-separated hybrid density functional theory and the efficiency of classical force fields. Predictions of material properties made with this force field are quantitatively accurate compared to experimental data. Our model uses the QRNN deep neural network architecture, which includes both long-range interactions and global charge equilibration. The training dataset is composed solely of non-periodic DFT, allowing the practical use of an accurate theory (here, ωB97X-D3BJ/def2-TZVPD) which would be prohibitively expensive for generating large datasets with periodic DFT. In this report we focus on seven common carbonates and LiPF6, but this methodology has very few assumptions and can be readily applied to any liquid electrolyte system. This provides a promising path forward for large scale atomistic modeling of many important battery chemistries.

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Section: Thermodynamic and Transport Properties Of Liquid Carbonate S...supporting

confidence: 79%

High-dimensional neural network potential for liquid electrolyte simulations

Dajnowicz

Agarwal

Stevenson

et al. 2022

Preprint

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show abstract

“…The strong dependence of the capacitance values on solvents has been applied to expanding the available voltage, improving the reversibility of charge‐discharge processes, selecting materials of cells and electrodes, and suppressing leakage of the charge. As industrial applications, mixed solvents have been used for developing properties of supercapacitors . Mixed solvents have an advantage in providing the opportunity to vary continuously the conditions.…”

Section: Introductionmentioning

confidence: 99%

Double Layer Impedance in Mixtures of Acetonitrile and Water

Aoki¹,

Chen

Tang

2018

Electroanalysis

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Double layer (DL) impedances were evaluated in mixed solutions of water and acetonitrile at various ratios in the polarized potential domain in order to find competitive orientation of the two solvent molecules on the platinum electrode. The DL capacitance at any ratio of the mixture shows the common power law of the ac‐frequency. The capacitance at molar fractions of water less than 0.2 increases linearly with the fraction, and reaches the value for aqueous solution. This variation indicates accumulation of water molecules on the electrode excluding acetonitrile molecules. It is modelled on the concept of the Langmuir‐type isotherm in which water and acetonitrile molecules have competitive interaction with the electrode. The experimental variations by the use of the isotherm yield the difference in the interaction energy, 6 kJ mol−1. The accumulation of water in the DL is supported by the formation of the adsorbed layer by insoluble ferrocene.

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“…At low frequencies, the Warburg component, that is, the sloping line corresponds to the diffusion process occurring in the bulk material. 27 The LTO–HC 20–80 mixed anode impedance resembles that of pristine HC, whereas that of the LTO–HC 50–50 mixed anode exhibits a second semicircle. The semicircle at high frequencies corresponds to the diffusion through pores of the electrode.…”

Section: Resultsmentioning

confidence: 97%

Hard Carbon and Li₄Ti₅O₁₂-Based Physically Mixed Anodes for Superior Li-Battery Performance with Significantly Reduced Li Content: A Case of Synergistic Materials Cooperation

et al. 2017

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Li 4 Ti 5 O 12 (LTO) and hard carbon (HC) are commonly used anodes in the Li-ion batteries. LTO has an operating voltage of 1.55 V and exhibits high-rate performance but with limited capacity. HC has high specific capacity but extremely low operating voltage. Herein, we show that a simple physical mixture of the two enhances the half-cell as well as full-cell performance through a synergistic cooperation between the materials. Specifically, the LTO–HC mixed anodes exhibit impressive performance even at high C-rates. This results from a quick internalization of Li ions by LTO followed by their distribution to HC regions via the high density of the winding internal interfaces between the two. The full cells of the LTO–HC mixed anodes with LiCoO 2 (LCO) evince an enhanced operating voltage window and a well-defined plateau. Because of a reduced irreversible capacity loss in the LCO/mixed anode full cells, the overall specific capacity is better than the LCO/pristine anode full cells. Also, with the LTO–HC 20–80 anode (Li content reduced by 80%), the full cell exhibits an impressive performance when compared to pristine anodes without pre-lithiation. The LCO/mixed anode full cells have excellent cycling stability up to 500 cycles at a current density of 100 mA g –1 .

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Vinylene Carbonate as Co-Solvent for Low-Temperature Mixed Electrolyte Based Supercapacitors

Cited by 21 publications

References 33 publications

High-dimensional neural network potential for liquid electrolyte simulations

High-dimensional neural network potential for liquid electrolyte simulations

Double Layer Impedance in Mixtures of Acetonitrile and Water

Hard Carbon and Li₄Ti₅O₁₂-Based Physically Mixed Anodes for Superior Li-Battery Performance with Significantly Reduced Li Content: A Case of Synergistic Materials Cooperation

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Vinylene Carbonate as Co-Solvent for Low-Temperature Mixed Electrolyte Based Supercapacitors

Cited by 21 publications

References 33 publications

High-dimensional neural network potential for liquid electrolyte simulations

High-dimensional neural network potential for liquid electrolyte simulations

Double Layer Impedance in Mixtures of Acetonitrile and Water

Hard Carbon and Li4Ti5O12-Based Physically Mixed Anodes for Superior Li-Battery Performance with Significantly Reduced Li Content: A Case of Synergistic Materials Cooperation

Contact Info

Product

Resources

About

Hard Carbon and Li₄Ti₅O₁₂-Based Physically Mixed Anodes for Superior Li-Battery Performance with Significantly Reduced Li Content: A Case of Synergistic Materials Cooperation