A spot laser modulated resistance switching effect observed on n-type Mn-doped ZnO/SiO(2)/Si structure

In this work, a spot laser modulated resistance switching (RS) effect is firstly observed on n-type Mn-doped ZnO/SiO(2)/Si structure by growing n-type Mn-doped ZnO film on Si wafer covered with a 1.2 nm native SiO(2), which has a resistivity in the range of 50–80 Ω∙cm. The I–V curve obtained in dark condition evidences the structure a rectifying junction, which is further confirmed by placing external bias. Compared to the resistance state modulated by electric field only in dark (without illumination), the switching voltage driving the resistance state of the structure from one state to the other, shows clear shift under a spot laser illumination. Remarkably, the switching voltage shift shows a dual dependence on the illumination position and power of the spot laser. We ascribe this dual dependence to the electric filed produced by the redistribution of photo-generated carriers, which enhance the internal barrier of the hetero-junction. A complete theoretical analysis based on junction current and diffusion equation is presented. The dependence of the switching voltage on spot laser illumination makes the n-type Mn-doped ZnO/SiO(2)/Si structure sensitive to light, which thus allows for the integration of an extra functionality in the ZnO-based photoelectric device.