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Characteristics of OUM Phase Change Materials and Devices for High Density Nonvolatile Commodity and Embedded Memory Applications

Published online by Cambridge University Press:  01 February 2011

Tyler A. Lowrey
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
Stephen J. Hudgens
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
Wally Czubatyj
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
Charles H. Dennison
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
Sergey A. Kostylev
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
Guy C. Wicker
Affiliation:
Ovonyx, Inc., 1030 E.El Camino Real #276, Santa Clara, CA94087 Tel: 408–653–9742 Fax: 408–653–5244 Email: tlowrey@ovonyx.com
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Abstract

Phase change memory devices were originally reported by S. R.Ovshinsky [1] in 1968. A 256-bit phase-change memory array based on chalcogenide materials was reported in 1970 [2] Recent advances in phase change materials, memory device designs, and process technology have resulted in significant advances in phase change device performance, and a new memory device, called Ovonic Unified Memory (OUM), has been developed. This paper will discuss various device and materials characteristics of OUM phase change memory materials of interest in applications for nonvolatile high-density memories. These materials are generally Te chalcogenide based, exploiting the congruent crystallization of the FCC phase and the associated reduction in resistivity that results from crystallization from the quenched amorphous state. Data storage is a thermally initiated, rapid, reversible structural phase change in the film. While rewriteable DVD disks employ laser heat to induce the phase change and modulate reflectivity, OUM technology uses a short electrical current pulse to modulate resistivity. The device geometry and thermal environment dictate the power and energy required for memory state programming.

Type
Research Article
Copyright
Copyright © Materials Research Society 2004

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References

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