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The fully transparent indium–tin-oxide/BaSnO3/F-doped SnO2 devices that show a stable bipolar resistance switching effect are successfully fabricated. In addition to the transmittance being above 87% for visible light, an initial forming process is unnecessary for the production of transparent memory. Fittings to the current–voltage curves reveal the interfacial conduction in the devices. The first-principles calculation indicates that the oxygen vacancies in cubic BaSnO3 will form the defective energy level below the bottom of conduction band. The field-induced resistance change can be explained based on the change of the interfacial Schottky barrier, due to the migration of oxygen vacancies in the vicinity of the interface.This work presents a candidate material BaSnO3 for the application of resistive random access memory to transparent electronics.
The fully transparent indium-tin-oxide / BaSnO3 / F-doped SnO2 devices that show a stable bipolar resistance switching effect are successfully fabricated. In addition to the transmittance above 87% for visible light, an initial forming process is unnecessary for the production Fillings to the current-voltage curves reveal the interfacial conduction in the devices. The first-principles calculation indicates that the oxygen vacancies in cubic BaSnO3 will form the defective energy level below the bottom of the conduction band. The field-induced resistance change can be explained based on the change of the interfacial Schottky barrier, due to the migration of oxygen vacancies in the vicinity of the interface. This work presents a candidate material BaSnO3 for the application of resistive random access memory to transparent electronics.