In the race to become the next technology for computer memory, phase-change memory (PCM) is among the leading contenders. The basis of PCM is a reversible, temperature-induced change between a shiny, low-resistance crystalline phase and a dull, high-resistance amorphous phase. In prototype devices, either the change in reflectivity or the change in resistance is exploited to write and store data. Unfortunately, in most PCM materials, the phase change is accompanied by a change in density that’s large enough to create performance-sapping voids beneath electrodes. And the materials that exhibit the biggest change in reflectivity or resistance also exhibit the biggest change in density. Magali Putero of Aix-Marseille University in France and her colleagues from CNRS and IBM have been systematically investigating the phase-change behavior of a wide range of PCM materials. Most of them shrink when they crystallize, but others swell. Using a beamline at the European Synchrotron Radiation Facility,...
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1 February 2014
February 01 2014
A phase-change alloy that crystallizes without shrinking
Physics Today 67 (2), 19 (2014);
Citation
Charles Day; A phase-change alloy that crystallizes without shrinking. Physics Today 1 February 2014; 67 (2): 19. https://doi.org/10.1063/PT.3.2268
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