The Memory Guy recently encountered some stories in the press about “UltraRAM” which is the name for a new type of NVRAM developed by researchers at Lancaster University in the UK. These researchers published one paper last June in Nature: Room-temperature Operation of Low-voltage, Non-volatile, Compound-semiconductor Memory Cells, and another just this month in the IEEE’s Transactions on Electron Devices: Simulations of Ultralow-Power Nonvolatile Cells for Random-Access Memory.
According to the papers, the new Continue reading “University of Lancaster Invents Yet Another Memory”
[The following is a guest post written by Ron Neale.]
Until now designers of PCM devices have tried to make PCM meet their expectations by experimenting with an almost infinite number of possible multi-element glass compositions, in order to tinker with or emphasise a particular composition-related device characteristic. The apparent advantage of this great variety of materials comes with the baggage of reliability and performance-compromising element separation, driven by the forces of electro-migration, electrostatic effects and phase separation.
Is it possible to cast aside the problems of the multi-element PCM compositions and look at the possibility of monatomic PCMs? For a team at IBM, Zurich and Aachen University the answer is an unequivocal “Yes!” and recently they have published details of the remarkable progress they have made with amorphous antimony (Sb), as an initial candidate element. This research was published in a June 2018 paper in Nature Materials Letters titled: Monatomic phase change memory, by Martin Salinga et al, IBM and Aachen University).
A difficulty faces those venturing in this new direction: While it is possible to bring many elements to the amorphous state, they very quickly crystallize at room temperature and higher. The IBM researchers used simulations to find that the keys to obtaining a stable amorphous state is to control the quenching rate and the volume of the sample. That part of the antimony research is underpinned by some very impressive simulations that use only about 200 atoms.
Here’s the issue that this approach Continue reading “Monatomic PCMs: A New Direction”
This is Part 3 of a short Memory Guy series in which contributor Ron Neale continues to explore the possible future impact on PCM memory performance, especially write/erase endurance, building on the results of the IBM/Yale University analysis outlined in Part 1 and Part 2.
Part 3 of this series of articles triggered by the recently published PCM device analysis by a team from IBM/Yale University, moves to a look at its possible implications for the arsenic doped GST threshold switch. Although the threshold switch was not part of the IBM/Yale work, the implementation of the call for bipolar operation of PCMs means there will be a requirement for a threshold switch whose durability matches that of the memory with which it will be associated in a memory array.
If the study’s finding for PCM can be applied to the arsenic-doped GST threshold switch which is used in today’s commercially-available PCM arrays then the threshold switch might just be the weak link that accounts for the poor endurance of commercial PCM memory arrays.
One little conundrum we must address is: Which Continue reading “Extending the Write/Erase Lifetime of Phase Change Memory: Part 3 – Failure Modes for the Threshold Switch”