论文信息 - Proton mobility in SiO 2 thin films and impact of hydrogen and humidity on the resistive switching effect

Proton mobility in SiO 2 thin films and impact of hydrogen and humidity on the resistive switching effect

Silicon dioxide based Electrochemical Metallization (ECM) cells were intensively studied as a promising candidate for CMOS compatible non-volatile memory devices. The resistance of ECM cells can be switched between a high resistive (OFF) state and a low resistive (ON) state by applying a sufficient voltage or current pulse. This resistance transition is attributed to the formation and rupture of a few nanometers in diameter metallic filament. However, the metal ion transport which is believed to be responsible for the filamentary switching mechanism is not understood in detail. In case of SiO 2 we suppose protons or humidity may enhance the metal ion transport. In this work we report our studies on the proton incorporation in amorphous SiO 2 thin films focused on the impact of hydrogen and humidity on the resistive switching effect. The switching behavior was analyzed by current-voltage measurements performed at different ambient conditions. The incorporation of hydrogen has been confirmed by Time-of-Flight Secondary-Ion-Mass-Spectroscopy (ToF-SIMS). The results led to an expansion of the defect model proposed in the literature. © 2011 Materials Research Society.

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