Title :
Modeling of Threshold Voltage Drift in Phase Change Memory (PCM) Devices
Author :
Ciocchini, N. ; Cassinerio, M. ; Fugazza, D. ; Ielmini, D.
Author_Institution :
Dipt. di Elettron. e Inf., Politec. di Milano, Milan, Italy
Abstract :
The stability of the amorphous phase in phase- change-memory (PCM) devices can be affected by temperature-activated crystallization and resistance drift due to structural relaxation (SR). While amorphous chalcogenides are relatively stable with respect to crystallization, thanks to a high activation energy of about 2.5 eV, the lower activation energy of SR can result in a change of the electronic properties of the PCM, including band-gap, resistance and threshold voltage VT for threshold switching. This work presents a physics- based model for VT drift based on physical models for electrical conduction, threshold switching and SR. We derive an analytical law relating the drift slopes of resistance and VT through the sub- threshold slope (STS) of the I-V curve. A numerical model is then presented, capable of predicting the time evolution of VT for reset and intermediate states in PCM multilevel cell (MLC).
Keywords :
amorphous semiconductors; crystallisation; energy gap; phase change memories; MLC; PCM devices; PCM multilevel cell; activation energy; amorphous chalcogenide; amorphous phase stability; band-gap; electrical conduction; electronic properties; phase change memory device; physics-based model; resistance drift; structural relaxation; temperature-activated crystallization; threshold switching; threshold voltage drift; Electrical resistance measurement; Numerical models; Phase change materials; Resistance; Strontium; Switches; Time measurement;
Conference_Titel :
Memory Workshop (IMW), 2012 4th IEEE International
Conference_Location :
Milan
Print_ISBN :
978-1-4673-1079-6
DOI :
10.1109/IMW.2012.6213673
