论文信息 - Explore physical origins of resistance drift in phase change memory and its implication for drift-insensitive materials

Explore physical origins of resistance drift in phase change memory and its implication for drift-insensitive materials

In this paper, we developed a theory to explain the physical origins of drift mechanism in amorphous Germanium (Ge), antimony (Sb), and tellurium (Te) ternary alloys (GST). The interrelationship between atomic structure and electrical characteristics were extensively studied by first principle Ab initio method and material/device characterization. The proposed method provides an effective guidance to develop drift-insensitive phase change material.

[1] E. Eleftheriou,et al. Drift-Tolerant Multilevel Phase-Change Memory , 2011, 2011 3rd IEEE International Memory Workshop (IMW).

[2] D. Ielmini,et al. Reliability Impact of Chalcogenide-Structure Relaxation in Phase-Change Memory (PCM) Cells—Part II: Physics-Based Modeling , 2009, IEEE Transactions on Electron Devices.

[3] D. Ielmini,et al. Physical interpretation, modeling and impact on phase change memory (PCM) reliability of resistance drift due to chalcogenide structural relaxation , 2007, 2007 IEEE International Electron Devices Meeting.

[4] Yeonwoong Jung,et al. Extremely low drift of resistance and threshold voltage in amorphous phase change nanowire devices , 2010 .

[5] Noboru Yamada,et al. Structural basis for the fast phase change of Ge2Sb2Te5: Ring statistics analogy between the crystal and amorphous states , 2006 .

[6] Laxmikant V. Kalé,et al. Fine-grained parallelization of the Car - Parrinello ab initio molecular dynamics method on the IBM Blue Gene/L supercomputer , 2008, IBM J. Res. Dev..