Nano-Scale Memory Fits A Terabit On A Square Inch

prostoalex writes "San Jose Business Journal talks about Nanochip, a company that's developing molecular-scale memory: "Nanochip has developed prototype arrays of atomic-force probes, tiny instruments used to read and write information at the molecular level. These arrays can record up to one trillion bits of data -- known as a terabit -- in a single square inch. That's the storage density that magnetic hard disk drive makers hope to achieve by 2010. It's roughly equivalent to putting the contents of 25 DVDs on a chip the size of a postage stamp." The story also mentions Millipede project from IBM, where scientists are trying to build nano-scale memory that relies on micromechanical components."

What about speed?

[GNUALMAFUERTE]

This kind of devices would be incredible for backup purposes, but also, the recording method seems to be also fast, would they accept allmost-unlimited rewrites?, in that case, this technology could finally replace magnetic devices. Solid state is allways better, but so far, the existing alternatives don't offer the durability and flexibility of hard disks.

Issues untold yet

[karvind]

(a) Reliability: No words about how reliable the system and elements are. It is one thing to make a 1M by 1M array and another to make bigger. Silicon semiconductor industry is lot more mature in transferring electronic processes. MEMS process still have low yield and haven't found commercial success yet (except the accelerometers used in air bags etc).

(b) Testing: How are they going to test this trillion element chip ? Testing complexity grows exponential with number of elements and it will require serious consideration. It may be worthwhile to make smaller components which can be tested easily (modern chips has one-third cost devoted to testing)

(c) Redundancy: Is this process going to give more yield than conventional electronic processes ? If no, common technique of redundancy has to be utilized. This brings in the cost in terms of power, speed and delay. For example if the yield is only 90%, that means you will need ~110% resources. Not only you have to make up for the defective components, you will have to provide lot more redundancy for testing. At some point it becomes worthless as the performance will drop to floor.

But still it is a good work and perhaps will generate some new ideas.

Such products are a godsend

[danila]

It's amazing how lucky these chip manufacturers are. Imagine to what lengths people need to go in other industries in order to convince customers to upgrade. If all you are selling is a damn chocolate bar, there is only so much that you can do to improve it. They had perfectly edible chocolate bars 100 years ago and there isn't much besides slapping "10% free" on the package that you can do. Ditto for things like headphones, ballpoint pens and pretty much everything else.

But the manufacturers of memory chips, hard disks, even CPUs, have it really easy. All they need to do is solve the technological problem of doubling the capacity/performance and the customer is eager to shell out some $$$ to get the new version. No focus groups are needed, no expensive marketing surveys. The only thing you need to do to please the customer is basically improve the obvious performance metric by 100%. You don't need to lie and twist the facts as those guys in cosmetics do with "73% more volume" for your eyelashes or "54% healthier hair" bullshit. You just make your CPU twice as fast and that flash chip twice as large, and you are done.

And if you really want to, you can say it will make Internet faster, or something...

data transfer rate

[kebes]

Most posters seem unimpressed with the storage density they are reporting, but I'd like to point out a couple of things. (Note that I use atomic force microscopes in my "job" -- I do academic research.)

Firstly, the storage density they are reporting is for a prototype setup, and it's already as good as curent HD technology. The exciting thing is not the value they currently have, but rather the fact that this technology can be pushed very very far. Thus, comparing this new technology to a mature technology (magnetic disks) is not really fair. I do believe that if this new technology is investigated for 10 years, it could outperform magnetic drivers in terms of storage density.

Secondly, the data transfer rate can be much higher with this new technology. The millipede project uses an array of thousands of AFM-like tips, which means that in principle 1000 bits of data are read at a time (compared to, for example, 4 bits read at one time in a magnetic disk drive with 4 platters). We all know that HD access is a major bottleneck in modern computers. This new concept could immediately speed that up by 2 orders of magnitude. I think that's worthy of consideration!

That having been said: don't hold your breath. MEMS is a rapidly evolving field, but it will be awhile before it can really beat out the mature magnetic technology. The article also doesn't give any details on how this new technology works. The potential is great, but alot of work has to be done.