LONDON – While many experts have expressed doubts about the ability of flash memory to scale and indicated the need for an alternative non-volatile memory technology, Hynix has just gone ahead and produced a 15-nm NAND flash memory cell which it plans to unveil at this year's International Electron Devices Meeting (IEDM).
However, at the same conference Hynix is due to report on an 84-nm pitch memory process for the production of 1-Gbit phase-change memories and beyond. As memory process are usually denoted by the half-pitch that is effectively a 42-nm process.
IEDM is due to take place December 5 to 7 in Washington DC and Hynix looks set to be a star of the conference, at least in terms of memory. Although the final program has not yet been posted, the organizers have tipped as highlights both the NAND flash and PCRAM papers that Hynix researchers are due to present. In the case of PCM whether this star status simply results from the likes of Samsung and Micron scaling back research waits on the release of the full program and the fullness of time.
Last year's IEDM saw the unveiling by Intel and Micron Technologies of the world's first NAND memory built using 25-nm design rules, which introduced the unusual technology of an air-gap to reduce word-line to word-line capacitance.
This year, Hynix Semiconductor researchers have demonstrated a NAND flash memory cell with a geometry somewhere in middle between 10- and 19-nm. At this level of miniaturization it becomes hard to measure the geometry and variability is high. According to the organizers the mid-1X-nm NAND flash memory has "excellent electrical characteristics and reliability" and the memory includes a word-line air-gap. What is not yet clear and will hopefully be included in the paper is the endurance cycling performance. As geometries decrease there is a tendency for NAND flash memory to show lower endurance significantly below the 10^6 cycles that were frequently specified at geometries above 100-nm.
Hynix is also due to present on a process technology for phase-change random access memory plus a 1-Gbit PCRAM implemented in the process. The technology is said to be highly scalable and low-cost, and was used to monolithically integrate a 1-Gbit PCRAM having 4F2 84-nm pitch memory cells occupying 0.007 square microns.
Surprisingly the memory technology is said to have 10-year data retention at temperatures above 200 degrees C. Such robust thermal stability has proved difficult for phase-change memory in the past but is critical for multilayer cell-stacking architectures.
Transmission electron microscope photographs showing cross-sections of phase-change memory cell in 42-nm process and the core/periphery areas.
Paper 3.3 is Highly Productive PCRAM Technology Platform and Full-Chip Operation Based on 4F2 (84-nm pitch) Cell Scheme for 1 Gb and Beyond, S. Lee et al, Hynix Semiconductor. Paper 9.1 is A Middle-1X-nm NAND Flash Memory Cell (M1X-NAND) with
Highly Manufacturable Integration Technologies, J. Hwang et al., Hynix
There are quite a few companies that use As (arsenic) in semiconductor devices. Market research indicates that the GaAs market was projected at $5.2B for 2011, see: http://www.eetimes.com/electronics-news/4212649/Gallium-arsenide-on-a-roll--says-analyst
ZnSe is a common in blue and white light-emitting diodes and diode lasers.
David Patterson, known for his pioneering research that led to RAID, clusters and more, is part of a team at UC Berkeley that recently made its RISC-V processor architecture an open source hardware offering. We talk with Patterson and one of his colleagues behind the effort about the opportunities they see, what new kinds of designs they hope to enable and what it means for today’s commercial processor giants such as Intel, ARM and Imagination Technologies.