Resistive switching of the HfO x /HfO2 bilayer heterostructure and its transmission characteristics as a synapse

Tingting Tan; Yihang Du; Ai Cao; Yaling Sun; Hua Zhang; Gangqiang Zha

doi:10.1039/c8ra06230g

Resistive switching of the HfO _x /HfO₂ bilayer heterostructure and its transmission characteristics as a synapse

RSC Adv. 2018 Dec 14;8(73):41884-41891. doi: 10.1039/c8ra06230g. eCollection 2018 Dec 12.

Authors

Tingting Tan¹, Yihang Du¹, Ai Cao¹, Yaling Sun¹, Hua Zhang¹, Gangqiang Zha¹

Affiliation

¹ State Key Laboratory of Solidification Processing, MIIT Key Laboratory of Radiation Detection Materials and Devices, School of Materials Science and Engineering, Northwestern Polytechnical University Xi'an 710072 China tantt@nwpu.edu.cn zha_gq@nwpu.edu.cn.

Abstract

In this work, HfO _x /HfO₂ homo-bilayer structure based resistive random access memory devices were fabricated, and the resistive switching characteristics of the devices were investigated. The samples with an Ar/O₂ ratio of 12 : 2 exhibited improved switching performance including better uniformity, endurance and retention, which was selected to imitate the "learning" and "forgetting" function of biological synapses. The multilevel conductance of the HfO _x /HfO₂ homo-bilayer structure under the model of pulse voltage suggests its potential to emulate the nonlinear transmission characteristics of the synapse, and a model of multilevel conductance of the HfO _x /HfO₂ homo-bilayer structure was proposed. The device conductance continuously increases (decreases) in accordance with the number of positive (negative) voltage pulses during the potentiation (depression) process, which can emulate the change of synaptic weight in a biological synapse.