Abstract
We present a study of the structure and differential capacitance of electric double layers of aqueous electrolytes. We consider electric double layer capacitors (EDLC) composed of spherical cations and anions in a dielectric continuum confined between a planar cathode and anode. The model system includes steric as well as Coulombic ion-ion and ion-electrode interactions. We compare results of computationally expensive, but “exact” , Brownian Dynamics (BD) simulations with approximate, but cheap, calculations based on classical Density Functional Theory (DFT). Excellent overall agreement is found for a large set of system parameters, including variations in concentration, ionic size- and valency-asymmetries, applied voltages and electrode separation, provided the differences between the canonical ensemble of the BD simulations and the grand-canonical ensemble of DFT are properly taken into account. In particular, a careful distinction is made between the differential capacitance C_N at fixed number of ions and C_mu at fixed ionic chemical potential. Furthermore, we derive and exploit their thermodynamic relations. In the future these relations will also be useful for comparing and contrasting experimental data with theories for supercapactitors and other systems. The quantitative agreement between simulation and theory indicates that the presented DFT is capable of accounting accurately for coupled Coulombic and packing effects. Hence it is a promising candidate to cheaply study room temperature ionic liquids at much lower dielectric constants than that of water.
Highlights
Electric double layer capacitors (EDLCs) are promising energy storage devices, in which electric energy is stored in the net ionic charge that is present in the vicinity of an electrode-electrolyte interface
In EDLCs the cathode attracts cations and repels anions and vice versa for the anode; more so the higher the applied voltage between the cathode and the anode [1]. This energy storage mechanism leads to much higher power densities than those of batteries; the discharge of the so-called electric double layer (EDL) of an EDLC can be much faster than the redox reactions in batteries [2, 3]
One of the factors that contributes to the low energy density in EDLCs is the limited potential window in which conventional electrolytes are stable with respect to detrimental chemical reactions
Summary
Electric double layer capacitors (EDLCs) are promising energy storage devices, in which electric energy is stored in the net ionic charge that is present in the vicinity of an electrode-electrolyte interface. In EDLCs the cathode attracts cations and repels anions and vice versa for the anode; more so the higher the applied voltage between the cathode and the anode [1]. This energy storage mechanism leads to much higher power densities than those of batteries; the discharge of the so-called electric double layer (EDL) of an EDLC can be much faster than the redox reactions in batteries [2, 3]. In order to maximise the energy density of EDLCs, one could use alternative electrolytes with a larger potential window [5]. In order to prepare for the challenges posed by ILs, we here focus on the parameter regime of aqueous systems
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