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Hybrid EDL is proposed by Zhonglin Wang.

Hybrid electric double layer
The Hybrid electric double layer (Hybrid EDL) is a model to describe the formation of electric double layer considering the contribution of electron transfer at liquid-solid interface, which is firstly proposed by Wang et al. in 2018. The major difference between the hybrid EDL model and the traditional EDL model is that the hybrid EDL model considers that there are both electrons and ions on the solid surface in the EDL, while the traditional EDL model considers that the solid surface has only adsorbed ions.

Nomenclature
The Hybrid EDL is also named after Prof. Zhong Lin Wang (Wang model), who proposed it in 2018.

The “two-step” formation process
The formation of the Hybrid EDL can be described by the “two-step” processes. In the first step, the molecules and ions in the liquid impact the solid surface due to the thermal motion and the pressure from the liquid, while the overlap of the electron clouds of the solid atoms and water molecules leads to the electron transfer between them. Then, due to liquid ﬂow or turbulence, the liquid molecules that are adjacent to the solid surface can be pushed off of the interface. The electron transfer process is related to the hopping of electron from high energy state to low energy state. Hence, after the separation, most of the electrons transferred to surface can be maintained, if the energy fluctuations of electrons is lower than the energy barrier. In the second step, free ions in the liquid would be attracted to the electrified surface due to electrostatic interactions, forming an EDL, which is similar as traditional EDL model.

Experimental evidence
The key difference between the Hybrid EDL model and traditional EDL model is whether the electron transfer at liquid-solid interface exists. The electron transfer was verified experimentally at both nano-scale and macro-scale. At nanoscale, it was found that the charges on the solid surface generated by contacting with the liquid can be removed by heating, and the decay of the surface charge density consistent with the thermionic emission theory, suggesting the existence of the electron transfer at liquid-solid interface. At macroscale, it was noticed that the amount of transferred charge on the solid surface is much greater than the number of ions in the liquid that may by adsorbed to the surface, which also implies that the electron transfer play a dominant role in liquid-solid contact electrification (CE).

The solid surface charge density in EDL
In the Hybrid EDL, the surface charge density (electrons and ions) in the liquid-solid CE is not as dense as that appearing in text book drawing. For example, the experiments suggest that highest transferred electron density is −630 mCm-2 in the CE between SiO2 and DI water, which corresponds to ~1 excess electron per 250 nm2. Thus, the probability of electron transfer in liquid-solid CE is usually less than one out of ~2,500 surface atoms. The transferred ion density in CE between SiO2 and DI water is −180 mCm-2, which corresponds to ~1 ion per 1000 nm2. Accordingly, the distance between two adjacent electrons on SiO2 surface is ~16 nm, and the distance between two adjacent O− ions is ~30 nm. These distances are much larger than the thickness of Stern layer, which is of the order of a few ångstroms. Hence, the distance of two adjacent charges (electrons or/and ions) should be considered in the structure of the EDL.

Reference
Category:Chemistry Category:Triboelectric Nanogenerator