An evaluation of the capacitive behavior of supercapacitors as a function of the radius of cations using simulations with a constant potential method.

We report on the atomistic molecular dynamics, applying the constant potential method to determine the structural and electrostatic interactions at the electrode-electrolyte interface of electrochemical supercapacitors as a function of the cation radius (Cs, Rb, K, Na, Li). We find that the electrical double layer is susceptible to the size, hydration layer volume, and cations' mobility and analyzed them. Besides, the transient potential shows an increase in magnitude and length as a function of the monocation size, , Cs > Rb > K > Na > Li.

Exploring doped or vacancy-modified graphene-based electrodes for applications in asymmetric supercapacitors.

We report here density functional theory calculations and molecular dynamics atomistic simulations to determine the total capacitance of graphene-modified supercapacitors. The contributions of quantum capacitance to the total capacitance for boron-, sulfur-, and fluorine-doped graphene electrodes, as well as vacancy-modified electrodes, were examined. All the doped electrodes presented significant variations in quantum capacitance (ranging from 0 to ∼200 μF cm-2) due to changes in the electronic structure of pristine graphene.

Elucidating the amphiphilic character of graphene oxide.

The amphiphilic character of graphene oxide was analysed in terms of its interfacial activities, using atomistic molecular dynamics. Graphene oxides at four different degrees of oxygenation were investigated considering both the effects of oxidation and carboxyl edge-functionalization. Solvation free energies are strongly negative and of increasing magnitude with the concentration for all systems, even in the toluene phase, indicating that GO presents a favourable solvation in both pure liquids as well as interfaces.

Impact of Edge Groups on the Hydration and Aggregation Properties of Graphene Oxide.

Molecular dynamics simulations were used to describe and quantify the role of edge groups on the hydrating properties of graphene oxide (GO). For this, six different oxygen concentrations were investigated, and in four of them, carboxyl groups were present. Structural analysis indicates a greater probability for the water solvation around the GO edges in detriment of the region of its basal plane, while hydrogen bonding analyses indicates that edge groups are very expressive, participating in about 60% of the total number of bonds.

Hydration peculiarities of graphene oxides with multiple oxidation degrees.

Hydration properties of graphene oxide (GO) are essential for most of its potential applications. In this work, we employ atomistic molecular dynamics simulations to investigate seven GO compositions with different levels of oxygenation. Two atomic charge models for GO are compared: (1, a simplified model) sp carbons are purely Lennard-Jones sites; (2, a CHELPG model) sp carbon charges are consistent with the CHELPG scheme.