Thermovoltaic Effects of van der Waals Heterojunctions based on Inert Conductor/Solution Interfaces

Abstract

It is found that if the inert conductor P has a larger electron work function φ and surface state function G than the inert conductor N, the inert conductor P and the inert conductor N are isolated by a separator and then immersed in the solution S (abbreviation: inert conductorP conductorN, or as P). Excluding the electrochemical reaction and thermoelectric effect of P, etc., it is measured that the voltage between the two conductors after the open circuit continues to increase to a certain stable maximum value. Then, the current after the closed-circuit continues to decrease to a certain stable minimum value. Analysis of the structure and properties of P shows that the inert conductor/solution interface relies on physical adsorption to construct van der Waals heterojunctions and that two van der Waals heterojunctions of different potentials form a P-N junction for P. The inert conductors P and N have different potentials. This electric field energy is expressed in the outer circuit when the circuit is open, due to the joint action of the electron work function φ and the surface state function G, P generates a larger built-in electric field and obtains a larger voltage. When the circuit is closed, P only has the effect of the surface state function G, which produces a smaller built-in electric field, results in a smaller voltage and current. This Thermoelectric conversion phenomenon is called the thermovoltaic effect.