| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 541302 | Microelectronic Engineering | 2014 | 6 Pages |
•The nature of the RRAM switching species has been unambiguously identified.•The kinetics of the moving species has been investigated in detail.•Crystallization process is proposed as a possible RRAM endurance failure mechanism.
First-principles simulations were employed to gain atomistic insights on the working principles of amorphous HfO2 based Resistive Random Access Memory stack: the nature of the defect responsible for the switching between the High and Low Resistive States has been unambiguously identified to be the substoichiometric Hf sites (commonly called oxygen vacancy-VO) and the kinetics of the process have been investigated through the study of O diffusion. Also the role of each material layer in the TiN/HfO2/Hf/TiN RRAM stack and the impact of the deposition techniques have been examined: metallic Hf sputtering is needed to provide an oxygen exchange layer that plays the role of defect buffer. TiN shall be a good defect barrier for O but a bad defect buffer layer. A possible scenario to explain the device degradation (switching failure) mechanism has been proposed – the relaxation of the metastable amorphous phase towards crystalline structure leads to denser, more structured cluster that can increase the defect migration barriers.
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