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Maxwell–Wagner effect and second harmonic generation in gradient structures
For the first time,we have registered, studied, andmodeled the Maxwell–Wagner effect in structures with a smooth gradient of charge carriers’ mobility. The Maxwell–Wagner charge, formed after applying a DC voltage to the gradient
structure at room temperature, is distributed over the entire region of the gradient. The experiments were performed with slides of a soda-lime glass subjected to sodium-to-potassium ion exchange, where the ions concentration gradient provides gradient of conductivity while dielectric permittivity stays the same. The electric field generated by the Maxwell–Wagner charge is concentrated in potassium-enriched less conductive regions of the slide and is sufficiently high to induce the second order optical nonlinearity in the initially isotropic glass. The effect causes over 100-fold increase in a second harmonic signal relative to the signal from the surface of a virgin glass. This phenomenon in graded-concentration structures is perspective for characterizing interfacial charges, geometry of the gradient regions, and spatial distribution of electrical conductivity in micro- and optoelectronic semiconductor structures.