Anenome
07-01-2011, 08:20 PM
http://i.imgur.com/1iteU.jpg?1035
Phase-Change Memory (PCM) is the new hotness, and will likely succeed flash-memory because it's both much faster and much more reliable. Instead of storing electrons as in flash, PCM-memory takes advantage of nano-scale melting of a metal at different temperatures which results in different electrical resistances. Thus, you can write a bit in and leave it there, melted into the material, for virtually eternity, I mean hundreds of years, with no chance of electrical interference or loss as in Flash.
So, you see those flash-based solid-state harddrives that just now have become practical enough to be in widespread use? PCM is going to make those look slow and expensive.
We might soon look at today's flash memory in the same way that we looked at 3 1/4 discs back when the CD came out :P Shocked at both how slow the old tech was by comparison, and how little memory it contained.
For that matter, when PCM really gets rolling, say goodbye to your platter-based harddrives. We will be PCM all the way.
IBM is claiming (http://www.gizmag.com/ibm-multi-bit-phase-change-memory/19082/) the first practical on-chip design:
Scientists from IBM Research - Zurich are claiming a world-first, for their recent demonstration of "reliable multi-bit phase-change memory [PCM] technology." PCM involves the use of materials that change between crystalline and amorphous states, the two states having different levels of electrical resistance - data is stored in a binary fashion, using one level to represent a 0, and the other to represent a 1. By applying new techniques to existing PCM technology, the researchers were reportedly able to write and retrieve data 100 times faster than is possible with Flash.
The IBM team used a 200,000-cell PCM test chip, fabricated in 90-nanometer CMOS technology. The phase-change material, an alloy consisting of various elements, was deposited between electrodes in the chip. By applying voltage to those electrodes, the alloy was heated, causing it to change back and forth between its low-resistance crystalline state, and its high-resistance amorphous state. What's more, by varying that voltage, the amount of material between electrodes that changed state could also be controlled - this allowed the scientists to store multiple bits of data on each cell.
One of the problems meeting previous PCM efforts has been one of resistance drift, or the tendency of the amorphous material's resistance to gradually increase after the initial phase-change. This has resulted in read errors. In order to get around this problem, the Swiss researchers utilized an "advanced modulation coding technique," that compensated for resistance drift. As a result, the chip has been able to reliably retain data for up to five months, and counting. Previously, only single bit-per-cell PCM chips had proven to be as reliable.
Another challenge involved creating read and write processes that allowed for deviations in resistance, caused by variations within the cells and the alloy itself. Even performing at its slowest, however, the chip still had a write latency of about 10 microseconds - reportedly 100 times faster than the most advanced Flash memory systems currently available.
PCM chips in general are also said to be much more durable than traditional technology - while an enterprise-class Flash chip is able to last approximately 30,000 write cycles, a PCM can reportedly go for at least 10 million.
The IBM Research team believe that the technology could be ready for use by 2016.
TL;DR version in bold :D
Phase-Change Memory (PCM) is the new hotness, and will likely succeed flash-memory because it's both much faster and much more reliable. Instead of storing electrons as in flash, PCM-memory takes advantage of nano-scale melting of a metal at different temperatures which results in different electrical resistances. Thus, you can write a bit in and leave it there, melted into the material, for virtually eternity, I mean hundreds of years, with no chance of electrical interference or loss as in Flash.
So, you see those flash-based solid-state harddrives that just now have become practical enough to be in widespread use? PCM is going to make those look slow and expensive.
We might soon look at today's flash memory in the same way that we looked at 3 1/4 discs back when the CD came out :P Shocked at both how slow the old tech was by comparison, and how little memory it contained.
For that matter, when PCM really gets rolling, say goodbye to your platter-based harddrives. We will be PCM all the way.
IBM is claiming (http://www.gizmag.com/ibm-multi-bit-phase-change-memory/19082/) the first practical on-chip design:
Scientists from IBM Research - Zurich are claiming a world-first, for their recent demonstration of "reliable multi-bit phase-change memory [PCM] technology." PCM involves the use of materials that change between crystalline and amorphous states, the two states having different levels of electrical resistance - data is stored in a binary fashion, using one level to represent a 0, and the other to represent a 1. By applying new techniques to existing PCM technology, the researchers were reportedly able to write and retrieve data 100 times faster than is possible with Flash.
The IBM team used a 200,000-cell PCM test chip, fabricated in 90-nanometer CMOS technology. The phase-change material, an alloy consisting of various elements, was deposited between electrodes in the chip. By applying voltage to those electrodes, the alloy was heated, causing it to change back and forth between its low-resistance crystalline state, and its high-resistance amorphous state. What's more, by varying that voltage, the amount of material between electrodes that changed state could also be controlled - this allowed the scientists to store multiple bits of data on each cell.
One of the problems meeting previous PCM efforts has been one of resistance drift, or the tendency of the amorphous material's resistance to gradually increase after the initial phase-change. This has resulted in read errors. In order to get around this problem, the Swiss researchers utilized an "advanced modulation coding technique," that compensated for resistance drift. As a result, the chip has been able to reliably retain data for up to five months, and counting. Previously, only single bit-per-cell PCM chips had proven to be as reliable.
Another challenge involved creating read and write processes that allowed for deviations in resistance, caused by variations within the cells and the alloy itself. Even performing at its slowest, however, the chip still had a write latency of about 10 microseconds - reportedly 100 times faster than the most advanced Flash memory systems currently available.
PCM chips in general are also said to be much more durable than traditional technology - while an enterprise-class Flash chip is able to last approximately 30,000 write cycles, a PCM can reportedly go for at least 10 million.
The IBM Research team believe that the technology could be ready for use by 2016.
TL;DR version in bold :D