Classical Density Functional Theory Insights for Supercapacitors

Lian, Cheng; Liu, Honglai

doi:10.5772/intechopen.76339

Cited by 5 publications

(4 citation statements)

References 92 publications

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“…[333,356,474]. Finally, electrochemical systems containing ions of different charge [53,184,185,192,349,354,414,415,[475][476][477][478][479][480][481][482][483][484][485] are an important application of DDFT for mixtures (see Section 8.1.10). An option for future work is the investigation of systems with nonreciprocal interactions [547].…”

Section: Mixturesmentioning

confidence: 99%

“…Impedance resonance can be studied by analyzing the effects of a time-dependent external electric field on the ions in DDFT [53]. Further applications include reversible heating [484], viscosity effects [185], ion dynamics in nanopores [480,485,977], and colloid-interface interactions [354]. Lee et al [978] mentioned the assumption that the ion density is low compared to the solvent density as a limitation of DDFT.…”

Section: Electrochemical Systemsmentioning

confidence: 99%

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Classical dynamical density functional theory: from fundamentals to applications

Vrugt

Löwen

Wittkowski

2020

Advances in Physics

177

220

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Classical dynamical density functional theory (DDFT) is one of the cornerstones of modern statistical mechanics. It is an extension of the highly successful method of classical density functional theory (DFT) to nonequilibrium systems. Originally developed for the treatment of simple and complex fluids, DDFT is now applied in fields as diverse as hydrodynamics, materials science, chemistry, biology, and plasma physics. In this review, we give a broad overview over classical DDFT. We explain its theoretical foundations and the ways in which it can be derived. The relations between the different forms of deterministic and stochastic DDFT as well as between DDFT and related theories, such as quantum-mechanical time-dependent DFT, mode coupling theory, and phase field crystal models, are clarified. Moreover, we discuss the wide spectrum of extensions of DDFT, which covers methods with additional order parameters (like extended DDFT), exact approaches (like power functional theory), and systems with more complex dynamics (like active matter). Finally, the large variety of applications, ranging from fluid mechanics and polymer physics to solidification, pattern formation, biophysics, and electrochemistry, is presented.

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Section: Mixturesmentioning

confidence: 99%

Section: Electrochemical Systemsmentioning

confidence: 99%

Classical dynamical density functional theory: from fundamentals to applications

Vrugt

Löwen

Wittkowski

2020

Advances in Physics

177

220

View full text Add to dashboard Cite

show abstract

“…We refer the interested readers to a review by Hartel, 178 which covers the application of DFT to confined ILs before 2017, with a particular focus on technicalities. There is also a more recent review by Lian and Liu, 179 who mainly focused on their own contribution.…”

Section: Application To Ionic Liquids Under Narrow Conducting Confine...mentioning

confidence: 99%

Theory and Simulations of Ionic Liquids in Nanoconfinement

et al. 2023

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Room-temperature ionic liquids (RTILs) have exciting properties such as nonvolatility, large electrochemical windows, and remarkable variety, drawing much interest in energy storage, gating, electrocatalysis, tunable lubrication, and other applications. Confined RTILs appear in various situations, for instance, in pores of nanostructured electrodes of supercapacitors and batteries, as such electrodes increase the contact area with RTILs and enhance the total capacitance and stored energy, between crossed cylinders in surface force balance experiments, between a tip and a sample in atomic force microscopy, and between sliding surfaces in tribology experiments, where RTILs act as lubricants. The properties and functioning of RTILs in confinement, especially nanoconfinement, result in fascinating structural and dynamic phenomena, including layering, overscreening and crowding, nanoscale capillary freezing, quantized and electrotunable friction, and superionic state. This review offers a comprehensive analysis of the fundamental physical phenomena controlling the properties of such systems and the current state-of-the-art theoretical and simulation approaches developed for their description. We discuss these approaches sequentially by increasing atomistic complexity, paying particular attention to new physical phenomena emerging in nanoscale confinement. This review covers theoretical models, most of which are based on mapping the problems on pertinent statistical mechanics models with exact analytical solutions, allowing systematic analysis and new physical insights to develop more easily. We also describe a classical density functional theory, which offers a reliable and computationally inexpensive tool to account for some microscopic details and correlations that simplified models often fail to consider. Molecular simulations play a vital role in studying confined ionic liquids, enabling deep microscopic insights otherwise unavailable to researchers. We describe the basics of various simulation approaches and discuss their challenges and applicability to specific problems, focusing on RTIL structure in cylindrical and slit confinement and how it relates to friction and capacitive and dynamic properties of confined ions.

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“…CDFT has been applied to predict the capacitances by accurately accounting for the excluded volume effect and electrostatic correlation in confined simple electrolytes. [38][39][40] By combining the MDFT and CDFT, the ion desolvation and its contribution to the capacitance of the microporous electrodes are investigated. We show that this combination can unravel the ion desolvation effect to electrochemical properties, and give satisfactory predictions on the capacitances of practical microporous electrodes with liquid electrolytes as long as the pore size distribution (PSD) is provided.…”

Section: Introductionmentioning

confidence: 99%

Ion Desolvation in Microporous Electrodes with Liquid Electrolytes

Qing¹,

Long²,

Yu³

et al. 2020

Preprint

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A deep understanding of ion desolvation in microporous electrodes is helpful for achieving efficient energy storage. Herein, we evaluate the contribution of ion desolvation to electrochemical performance of microporous electrodes with a proposed multiscale approach. By integrating the molecular version with the simple version of classical density functional theory, we first determine the solvation diameters of ions in confined molecular solvent, and then predict the capacitances of microporous electrodes through a solvation-diameter-dependent coarse-grained model. We find that the solvation diameter displays an oscillatory decline as decreasing the pore size of nanoslit, and upon this relation in combination with the pore size distribution of microporous electrode we give satisfactory predictions of the capacitances of practical electrodes compared with experimental measurements. This work not only provides a feasible multiscale tool for predicting the capacitances of microporous electrodes involving liquid electrolytes, but also casts insights for the design and preparation of high-performance supercapacitors.

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Classical Density Functional Theory Insights for Supercapacitors

Cited by 5 publications

References 92 publications

Classical dynamical density functional theory: from fundamentals to applications

Classical dynamical density functional theory: from fundamentals to applications

Theory and Simulations of Ionic Liquids in Nanoconfinement

Ion Desolvation in Microporous Electrodes with Liquid Electrolytes

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