Wetting transition of ionic liquids at metal surfaces: A computational molecular approach to electronic screening using a virtual Thomas-Fermi fluid

Of particular relevance to energy storage, electrochemistry and catalysis, ionic and dipolar liquids display a wealth of unexpected fundamental behaviors – in particular in confinement. Beyond now well-documented adsorption, overscreening and crowding effects1,2,3, recent experiments have highlighted novel phenomena such as unconventional screening4 and the impact of the electronic nature – metallic versus insulating – of the confining surface on wetting/phase transitions5,6. Such behaviors, which challenge existing theoretical and numerical modeling frameworks, point to the need for new powerful tools to embrace the properties of confined ionic/dipolar liquids. Here, we introduce a novel atom-scale approach which allows for a versatile description of electronic screening while capturing all molecular aspects inherent to molecular fluids in nanoconfined/interfacial environments. While state of the art molecular simulation strategies only consider perfect metal or insulator surfaces, we build on the Thomas-Fermi formalism for electronic screening to develop an effective approach that allows dealing with any imperfect metal between these asymptotes. The core of our approach is to describe electrostatic interactions within the metal through the behavior of a `virtual' Thomas-Fermi fluid of charged particles, whose Debye length sets the Thomas-Fermi screening length λ in the metal. This easy-to-implement molecular method captures the electrostatic interaction decay upon varying λ from insulator to perfect metal conditions, while describing very accurately the capacitance behavior – and hence the electrochemical properties – of the metallic confining medium. By applying this strategy to a nanoconfined ionic liquid, we demonstrate an unprecedented wetting transition upon switching the confining medium from insulating to metallic. This novel approach provides a powerful framework to predict the unsual behavior of ionic liquids, in particular inside nanoporous metallic structures, with direct applications for energy storage and electrochemistry.

[1]  L. Bocquet,et al.  Nanotribology of Ionic Liquids: Transition to Yielding Response in Nanometric Confinement with Metallic Surfaces , 2020, 2102.06239.

[2]  B. Rotenberg,et al.  A semiclassical Thomas-Fermi model to tune the metallicity of electrodes in molecular simulations. , 2019, The Journal of chemical physics.

[3]  N. Wilding,et al.  A unified description of hydrophilic and superhydrophobic surfaces in terms of the wetting and drying transitions of liquids , 2019, Proceedings of the National Academy of Sciences.

[4]  Trung Dac Nguyen,et al.  Incorporating surface polarization effects into large-scale coarse-grained Molecular Dynamics simulation , 2019, Comput. Phys. Commun..

[5]  Alexander D. MacKerell,et al.  Molecular Dynamics Simulations of Ionic Liquids and Electrolytes Using Polarizable Force Fields , 2019, Chemical reviews.

[6]  Alexander D. MacKerell,et al.  Polarizable Molecular Dynamics Simulations of Ionic Liquids and Electrolytes. , 2018 .

[7]  A. Kornyshev,et al.  Minimizing the electrosorption of water from humid ionic liquids on electrodes , 2018, Nature Communications.

[8]  Y. Levin,et al.  Simulations of Coulomb systems confined by polarizable surfaces using periodic Green functions. , 2017, The Journal of chemical physics.

[9]  B. Coasne,et al.  Electrostatic interactions between ions near Thomas-Fermi substrates and the surface energy of ionic crystals at imperfect metals. , 2017, Faraday discussions.

[10]  Alessandro Siria,et al.  Nanoscale capillary freezing of ionic liquids confined between metallic interfaces and the role of electronic screening , 2016, Nature materials.

[11]  A. Lee,et al.  Ion-Image Interactions and Phase Transition at Electrolyte-Metal Interfaces. , 2016, The journal of physical chemistry letters.

[12]  A. Lee,et al.  The Electrostatic Screening Length in Concentrated Electrolytes Increases with Concentration. , 2016, The journal of physical chemistry letters.

[13]  W. Schmickler,et al.  On the Energetics of Ions in Carbon and Gold Nanotubes. , 2016, Chemphyschem : a European journal of chemical physics and physical chemistry.

[14]  K. Breitsprecher,et al.  Electrode Models for Ionic Liquid-Based Capacitors , 2015 .

[15]  Mfi Statics and Dynamics , 2014 .

[16]  A. Kornyshev,et al.  Ionic liquids at electrified interfaces. , 2014, Chemical reviews.

[17]  A. Kornyshev,et al.  Differential capacitance of ionic liquid interface with graphite: the story of two double layers , 2014, Journal of Solid State Electrochemistry.

[18]  A. Kornyshev,et al.  Interionic interactions in conducting nanoconfinement. , 2013, Chemphyschem : a European journal of chemical physics and physical chemistry.

[19]  Axel Arnold,et al.  Efficient Algorithms for Electrostatic Interactions Including Dielectric Contrasts , 2013, Entropy.

[20]  W. Schmickler,et al.  The electric double layer on graphite , 2012 .

[21]  A. Kornyshev,et al.  Double layer in ionic liquids: overscreening versus crowding. , 2010, Physical review letters.

[22]  A. Kornyshev,et al.  Superionic state in double-layer capacitors with nanoporous electrodes , 2010, Journal of physics. Condensed matter : an Institute of Physics journal.

[23]  Christian Holm,et al.  An iterative, fast, linear-scaling method for computing induced charges on arbitrary dielectric boundaries. , 2010, The Journal of chemical physics.

[24]  E. Charlaix,et al.  Nanofluidics, from bulk to interfaces. , 2009, Chemical Society reviews.

[25]  D. Bonn,et al.  Wetting and Spreading , 2009 .

[26]  P. Renaud,et al.  Transport phenomena in nanofluidics , 2008 .

[27]  Stewart K. Reed,et al.  Electrochemical interface between an ionic liquid and a model metallic electrode. , 2007, The Journal of chemical physics.

[28]  D. Frenkel,et al.  Calculation of the melting point of NaCl by molecular simulation , 2003 .

[29]  R. Netz Debye-Hückel theory for interfacial geometries. , 1999, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[30]  M. Berkowitz,et al.  Ewald summation for systems with slab geometry , 1999 .

[31]  J. Dobson ELECTRON DENSITY FUNCTIONAL THEORY , 1999 .

[32]  S. Herminghaus,et al.  Wetting: Statics and dynamics , 1997 .

[33]  J. Ilja Siepmann,et al.  Influence of surface topology and electrostatic potential on water/electrode systems , 1995 .

[34]  Steve Plimpton,et al.  Fast parallel algorithms for short-range molecular dynamics , 1993 .

[35]  A. Kornyshev Metal electrons in the double layer theory , 1989 .

[36]  H. Gerischer,et al.  Density of the electronic states of graphite: derivation from differential capacitance measurements , 1987 .

[37]  G. Torrie,et al.  Double layer structure at the interface between two immiscible electrolyte solutions , 1986 .

[38]  W. Schmickler,et al.  On the coverage dependence of the partial charge transfer coefficient , 1986 .

[39]  M. A. Vorotyntsev Modern State of Double Layer Study of Solid Metals , 1986 .

[40]  H. Gerischer,et al.  An interpretation of the double layer capacity of graphite electrodes in relation to the density of states at the Fermi level , 1985 .

[41]  M. A. Vorotyntsev,et al.  Nonlocal electrostatic approach to the double layer and adsorption at the electrode-electrolyte interface , 1980 .

[42]  A. Kornyshev,et al.  Image potential near a dielectric–plasma‐like medium interface , 1977 .

[43]  J. C. Inkson Many-body effect at metal-semiconductor junctions. II. The self energy and band structure distortion , 1973 .

[44]  V. V. Batrakov,et al.  Adsorption of Organic Compounds on Electrodes , 1971 .

[45]  D. Newns Fermi-Thomas Response of a Metal Surface to an External Point Charge , 1969 .