Litcius/Paper detail

Evaluating Ovonic Threshold Switching Materials with Topological Constraint Theory

J.C. Read, Derek A. Stewart, James W. Reiner, B. D. Terris

2021ACS Applied Materials & Interfaces13 citationsDOI

Abstract

The physical properties of ovonic threshold switching (OTS) materials are of great interest due to the use of OTS materials as selectors in cross-point array nonvolatile memory systems. Here, we show that the topological constraint theory (TCT) of chalcogenide glasses provides a robust framework to describe the physical properties of sputtered thin film OTS materials and electronic devices. Using the mean coordination number (MCN) of an OTS alloy as a comparative metric, we show that changes in data trends from several measurements are signatures of the transition from a floppy to a rigid glass network as described by TCT. This approach provides a means to optimize OTS selector materials for device applications using film-level measurements.

Topics & Concepts

Materials scienceChalcogenideConstraint (computer-aided design)Non-volatile memoryMetric (unit)Topology (electrical circuits)NanotechnologyOptoelectronicsMechanical engineeringElectrical engineeringEconomicsOperations managementEngineeringPhase-change materials and chalcogenidesNonlinear Optical Materials StudiesTransition Metal Oxide Nanomaterials