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."

Finally

I'll be able to store my gigaquads in a compact space.

Ive seen this before

They were talkig about this a while back on simulatedlucidity.com

Re:Ive seen this before

[Neuroelectronic]

..and in other news: quantum holography can fit a infinate amount of data within a single quark. This technology is expected to be developed within 5-10 years. Reserve your quantum halographic quark today!

25 DVDs?

[chris-johnson]

Last time I checked, a DVD was (roughly) 4 GB, so 25 DVDs is only 100GB?

Re:25 DVDs?

[captain+igor]

Yes, a terabit = 125 Gigabytes, which is 31.25 DVDs

Re:25 DVDs?

[Sonic+McTails]

A double-sided DVD is 7.4GB, but your righ, that's still nowhere close to a terrabyte. I just wonder how long until we start to think a terrabyte is small.

Re:25 DVDs?

[chris-johnson]

And of course after I post, I see terabit instead of terabyte.

Re:25 DVDs?

Yes, 100GB would be about a Terabit, things like parity considered...

Re:25 DVDs?

A Terabit is 125GB. Single layer dvd discs store 4.7GB while dual layer discs store 8.5GB.

25 DVDs is a really bad comparison since the size of a dvd could vary.

Re:25 DVDs?

[djward]

This is all very confusing. Someone please tell me, how many Libraries of Congress is that?

Re:25 DVDs?

[Rosco+P.+Coltrane]

The LOC is about 20 TB worth of data. So the storage medium here is roughly 1/160th of an LOC :-)

Re:25 DVDs?

[XorNand]

DVD-R / DVD+R capacities are 4.7GB. However, actual pressed, dual-layer DVDs are 8.54GB (single-sided). So the analogy is a bit incomplete. A better analogy, of course, is how many hogshead of LoC does it hold?

Re:25 DVDs?

[darkpixel2k]

After doing a quick grep of the page for the word 'congress' and finding no results, I thought I'd karma whore:

"But what is that in Libraries of Congress?"

Re:25 DVDs?

[frinsore]

Since a DVD can hold 15.9 GB (that's dual layer and dual sided, the current maximum) the formula would look like:
15.9 GB * 25 = 397.5 GB and then to convert from Bytes to bits:
397.5 * 8 = 3180 which approximates 3.1 Tb

so comparing it to the DVD format is a poor frame of reference

Re:25 DVDs?

[kyouteki]

Except, of course, nobody said anything about terabytes, or even terrabytes.

Re:25 DVDs?

[nurb432]

Last time i checked, dvd movies from the store were 8ish.. ( dual layer )

But whos counting?

Re:25 DVDs?

Last time I checked, a postage stamp wasn't a square inch either!

Re:25 DVDs?

[chris+mazuc]

According to Wikipedia, one LoC is 20 terabytes, so the answer is 0.00625.

Re:25 DVDs?

[dbIII]

"But what is that in Libraries of Congress?"

Fourteen football feilds.

Re:25 DVDs?

Last I checked, the standard disk you can rent at the video store contains up to 8 gb, roughly.

Re:25 DVDs?

the average slashdot user's peen size (1") would be more appropriate

Re:25 DVDs?

Please learn the difference between bits and bytes.

Re:25 DVDs?

Thats 6.25 milliLOC in metric

Re:25 DVDs?

so 1.11 square feet (12.65 in x 12.65 in) of this stuff equals 1 Library of Congress

Re:25 DVDs?

I was gonna chime in with the 15.9GB comment but I see some got to it first, which btw the way is the most a Commercially made(pressed) DVD can hold in Dual layer config, but yes the average DVD is about half that, but we're refering to the max capacity it CAN hold 'vs' an ambiguous "average". And why does everyone automatically assume we're referring to burned DVD capacities when these comparisons come up?

Sorry about being an ANONYMOUS COWARD, but I was too LAZY to register, and will register here for future topics(or the continuation of this one).

Re:25 DVDs?

[Giggle+Stick]

American Football, or do you mean a pitch? And what is in the football field? Floppies stacked 100 high with 1 inch gaps around the stacks? Come on dude, let's be specific.

Magnetic memory = Doom

[Geogriffith]

Is it just me, or is persistent memory (i.e. magnetic) a really bad idea?

Now instead of rebooting to wipe viruses, spyware, crashed programs from memory, now we're going to have to wave a magnet inside our computers.

A step backwards, if you ask me.

Re:Magnetic memory = Doom

[k512-arch]

who says you can't reboot anymore? man, it'd be nice to be able to turn off your computer, and instantly go back to work when you turn it back on. if you have spyware problems, then go ahead and restart, there'll still be the option to.

Re:Magnetic memory = Doom

[Canadian_Daemon]

So, you are writing you 10 000 line program, get half way through it today, save to your non persistent memory, shutdown for the night, and what? You really ought to think about it for a while, how often do you use your harddrive? Never, well then you are correct in your idea that persistent memory is a bad idea. However, if you are like any person in the world that boots their OS from a hard drive, or saves their work to a hard drive, or plays games, then you probably want persistent memory

Re:Magnetic memory = Doom

Or have an electromagnet that zaps it. Or have the shutdown/boot up sequence (via BIOS hardware) automatically reset all the memory locations.

Ok .. now get me the patent on this cause although its obvious i had the idea of patenting it first.

Too bad I'm posting as an AC though. sucks.

Re:Magnetic memory = Doom

[GerbilSoft]

Warm reboots don't erase memory. Cold reboots usually don't erase memory, either. (There are still fragments of what was left before after doing a cold boot.)

And as almost all data recovery people know, reformatting a hard drive using the conventional disk formatting commands don't really erase anything; they merely create new directory structures. In order to really erase a disk, you have to use something like Eraser or `dd if=/dev/urandom of=/dev/hda`.

Re:Magnetic memory = Doom

[TERdON]

Well, he might be using Knoppix or another live-cd, and when finished for the day, burn his accomplishments to cd/dvd (ie persistent, but optical, not magnetic storage).

Re:Magnetic memory = Doom

Now instead of rebooting to wipe viruses, spyware, crashed programs from memory, now we're going to have to wave a magnet inside our computers.

I thought everybody did that?!

But I once tried to swing a cat in there and discovered that I have a much smaller case than I figured...

Re:Magnetic memory = Doom

[Aeiri]

So, you are writing you 10 000 line program, get half way through it today,

I don't know about you, but to me that sounds like a LOT of work for one day... 5,000 lines?

And how many bugs do you think will be in those 5,000 lines if you only worked on that in one day? 10,000? 20,000?

Re:Magnetic memory = Doom

[david.given]

Warm reboots don't erase memory. Cold reboots usually don't erase memory, either. (There are still fragments of what was left before after doing a cold boot.)

Standard DRAM will maintain its state --- mostly --- for a remarkably long time without refreshing. Unfortunately, it doesn't do so in a useful state.

I once was working on an embedded device that had VGA out. The development cycle was power on, boot from TFTP, run system, wait until it crashed, power off, repeat. When the system switched on, one of the first things the boot loader did was to initialise the video chipset, but without clearing the video memory.

If the board had been off for less than about five minutes, you could still see the last display that had been there when the board crashed.

Without refreshes, the data would gradually fade; the image was always corrupted with snow. The longer you left it switched off for, the worse the snow got. Different RAM chips lasted different lengths of time --- there was one band across the middle that would become completely unintelligable in about 30s, while another one could hold an image for about two minutes.

I suppose you could use this to store data for short periods during a power down, but you'd have to use so much redundancy to ensure that the data would survive the inevitable corruption that it probably wouldn't be worth it, but I'm sure someone, somewhere, could come up with a Nifty Trick(TM)... You couldn't do it at all on PCs, of course --- on boot, they wipe all their RAM, video or otherwise.

Re:Magnetic memory = Doom

[Dolda2000]

It's not like you actually have to clear the memory to get to a clean state. Just jumping back to the boot ROM or restarting the kernel ought to do the same thing for you.

Rather, non-volatile memory instead has the enormous advantage that you can shut down your computer (physically) without shutting down your software system.

Re:Magnetic memory = Doom

[CastrTroy]

This is offtopic but I actually fixed a broken hard drive with dd if=/dev/urandom of=/dev/hdb. It was reporting bad sectors all over the place, and SMART (which isn't really) said it had "Imminent Failure". So, I salvaged what I could, and after trying to format, along with many other things, I just tried overwriting the entire thing. It worked. 2 years later the drive is still in top condition reporting no bad sectors. I think that People could save a lot of hard drives with that small amount of information.

Re:Magnetic memory = Doom

[orangesquid]

That's because a 20Gig drive usually has something like 22-24Gigs of space; the extra space is used to relocate bad blocks.

If you completely overwrite a bad block, the drive's firmware is usually smart enough to move it to a new place. Reading from a bad block until you manage to get (most of) the data, and then re-writing it, will sometimes work (due to the same mechanism).

I'm told some drives are smart enough to try to "fix" bad blocks without being forced to like this, but I don't know of any (mostly likely because there would be no way to tell, since it would be user-transparent).

Occasionally, a drive will have some sort of mechanical shock which will damage a portion of the disk; often, the disk is not "failing," but has simply become partly damaged. A true "failing" disk would mean that the disk material was corroding, or that a poorly designed drive was losing its own low-level formatting from the motor's magnetic fields (I doubt that would ever happen, though), or something pretty ugly like that.

(I don't know if what I've said is completely true; please correct me if I'm talking out of my ass. It's been a long time since I've looked this up.)

Re:Magnetic memory = Doom

[Canadian_Daemon]

yes, because that was the point of my analogy, that the poster could write 5 000 lines of code a day.

Re:Magnetic memory = Doom

[Coolpup]

If you RTFA you will see they are talking about FLASH MEMORY. I've never seen anyone use their flash drives as their RAM. Do you know why this is? Because flash memory is far to slow to be used as RAM.

Re:Magnetic memory = Doom

[CastrTroy]

Well, this was a 30 gig drive, and was reporting around 25% bad sectors by the time I decided to overwrite everything with random data. Now, the drive works fine. No bad sectors reported. It all seems very mysterious to me. Conspiracy theory alert. Maybe the drive manufacturers recorded something on the drive that told it when to start reporting bad sectors and start dieing. Maybe overwriting the whole thing got rid of that data, and caused the drive to start working againg. But these are big maybes.

Re:Magnetic memory = Doom

and more importantly can only cope with thousands of writes before they fail

Re:Magnetic memory = Doom

[buford_tannen]

I don't know about you, but to me that sounds like a LOT of work for one day... 5,000 lines?

It's not all that much, provided each line begins with a

/*

and ends with a

*/

.

Re:Magnetic memory = Doom

[lachlan76]

And because it will fail after enough writes.

Re:Magnetic memory = Doom

[greenhide]

Hard drives are cheap. The information that was on them was priceless.

A decent 20G drive costs what, $30 now? When someone's drive fails, they're usually so devasted (unless they had a comprehensive backup in place) that a consolation like, "Well, I was able to save your hard drive that didn't do the job it was supposed to do in the first place" just doesn't make the person feel all that better.

If I was in that situation, I'd probably go ahead and buy a new hard drive unless it was on a machine I really didn't care about, and then why am I bothering to keep it switched on?

Otherwise, why keep a piece of hardware that I know failed in the past? It might not have been the hardware's fault, but why take any chances?

Besides, it's a perfect opportunity to get a newer, more stable drive with more capacity for the same or lower price than I paid for the old drive.

Re:Magnetic memory = Doom

[CastrTroy]

Living on a student budget is plenty of reason to use defective hardware. Mind you, I always keep my work on the drive that hasn't failed. And I keep back ups. But when you don't have to money to run out and get new hardware everytime something fails, it's nice to know how to fix it.

Hmm

[pHatidic]

These arrays can record up to one trillion bits of data -- known as a terabit -- in a single square inch.

Is that a hardware terabit or a software terabit?

Re:Hmm

[DrEldarion]

Or, if they're rounding, is it a tibibit?

Re:Hmm

[Jesus+2.0]

Probably neither. Are you familiar with the word "approximation"?

And even in the extremely unlikely case that exactly one terabit exactly fits in exactly one square inch, the answer to your question is contained in the sentence you quoted anyway: "one trillion bits of data".

Re:Hmm

Tebibit...

Re:Hmm

Is that a hardware terabit or a software terabit?

This is critical information. I had the soft tera once. I took a pill for it that I ordered off the internt, then got the hard tera when it wouldn't go away three hours later.

People worry about the soft tera. Trust me, the hard tera is much worse.

Re:Hmm

[Ironsides]

As a rule of thumb, bits are measured in base 10 (thousands) and bytes are measured in base 2 (1024's). Other than when marketers get a hold of numbers, this is usually true.

How long.

[lifejunkie]

How long before it's non-volatile?

Re:How long.

[lifejunkie]

Opps, looks like it is.

Re:How long.

[Spy+Hunter]

It is non-volatile by nature. But it is not likely to be fast enough to replace RAM. Instead it could replace Flash memory or even (depending on cost) hard drives. The real question is, how long until it's practical to manufacture and use in mass-produced products? The answer seems to be (according to the article) 2007-2010 timeframe.

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.

Re:What about speed?

[cthulhu11]

Since when are hard disks liquid or gaseous? Mine don't contain tubes - do yours? "Solid state" is an old term that came out to differentiate snazzy new radios from old clunky vacuum tube ones.

Re:What about speed?

don't you mean allso allternatives ?

Re:What about speed?

[GNUALMAFUERTE]

Yup, it refers to transistors, but since now everything uses them (besides some truly expensive audio systems), I meant to use it to diferenciate systems with mobile parts likes HDs from flashs, for example. I am not the first one to use it in this sense anyway ...

Go ahead

[killa62]

Mod me -1 redundant if you like, but for people out there, but 1 trillion b= 125,000,000,000 bytes = 116 GB, or if you're a harddrive manufacturer, its 125 GB.

Re:Go ahead

1 terabit = 125 GB (gigabyte)
1 terabit = 116 GiB (gibibyte)

Networking and storage use base-10, memory uses base-2.

http://mathworld.wolfram.com/Gibibyte.html

Re:Go ahead

[jdmuir]

• trillion b= 125,000,000,000 bytes = 116 GiB

Get your units right; the hard drive manufacturers have.

Re:Go ahead

[bohnsack]

1 trillion bits is 125 GB, whether you're a hard drive manufacturer or not, as "G" is exactly defined as 10^9. If you're interested in representing this quantity in terms of multiples of 2^(30), as in your 116, 1 trillion bits is more correctly stated as 116.5 GiB, 116.5 gigabinary bytes, or 116.5 gibibytes. See the SI spec on prefixes for binary multiples for more information.

Re:Go ahead

[DNX+Blandy]

There are 1,099,511,627,776 bytes in a Terabyte...

http://www.webopedia.com/quick_ref/FileSizeConvers ionTable.asp

Going on that basis:

1,099,511,627,776 / 8 = 137438953472 Bytes = 128 GB
(Divide by 8 as they specified bits)

Re:Go ahead

[ic3p1ck]

Whoever came up with those suffixes (gibi etc) should be forced to say them out loud, in public! They sound ridiculous!

Re:Go ahead

[CrackerJack9]

whether you're a hard drive manufacturer or not

And when was the last time your hard drive manufacturer-labeled "80GB" hard drive actually proved to be able to hold 80GB of data?

It's not a question of the giga part, everyone knows the metric system by now (I hope)

Here's the important part you were ignoring:
---
Hard drive manufacturer: One GigaByte = 1000 bytes
Software/everyone else: One GigaByte = 1024 bytes
---
I'm pretty sure this is what the parent was referring to.

Re:Go ahead

[bohnsack]

It's not a question of the giga part, everyone knows the metric system by now (I hope)

Really, do you? Last time I looked, G or giga is defined as exactly 10^9 (1,000,000,000).

Here's the important part you were ignoring:
---
Hard drive manufacturer: One GigaByte = 1000 bytes

Wrong. Hard drive manufacturers and everyone else who knows how to use SI prefixes correctly knows that one gigabyte is 1,000,000,000 bytes.

Software/everyone else: One GigaByte = 1024 bytes

Wrong again. If in this case you mean 2^30 bytes, 1 GiB = 1,073,741,824 bytes. What about network people? To them, 1 GB is certainly 1,000,000,000 bytes. Does a 100 Mb/s Ethernet operate at 1,000,000 bits per second (10^6) or is is 1,048,576 (2^20)? More and more people are becoming aware of this issue and moving from the old ambiguous use of prefixes representing powers of ten to represent powers of two to the new more percise and seperate binary SI prefixes. Case in point. Bittorent. Download the client, use it, and you'll notice that bytes, in binary multiples are correctly refered to as KiB, MiB, etc.

If you had actually read the link I posted on SI prefixes for binary multiples, you might know the following historical context:

Once upon a time, computer professionals noticed that 2^10 was very nearly equal to 1000 and started using the SI prefix "kilo" to mean 1024. That worked well enough for a decade or two because everybody who talked kilobytes knew that the term implied 1024 bytes. But, almost overnight a much more numerous "everybody" bought computers, and the trade computer professionals needed to talk to physicists and engineers and even to ordinary people, most of whom know that a kilometer is 1000 meters and a kilogram is 1000 grams.

Then data storage for gigabytes, and even terabytes, became practical, and the storage devices were not constructed on binary trees, which meant that, for many practical purposes, binary arithmetic was less convenient than decimal arithmetic. The result is that today "everybody" does not "know" what a megabyte is. When discussing computer memory, most manufacturers use megabyte to mean 2^20 = 1 048 576 bytes, but the manufacturers of computer storage devices usually use the term to mean 1 000 000 bytes. Some designers of local area networks have used megabit per second to mean 1 048 576 bit/s, but all telecommunications engineers use it to mean 10^6 bit/s. And if two definitions of the megabyte are not enough, a third megabyte of 1 024 000 bytes is the megabyte used to format the familiar 90 mm (3 1/2 inch), "1.44 MB" diskette. The confusion is real, as is the potential for incompatibility in standards and in implemented systems.

Faced with this reality, the IEEE Standards Board decided that IEEE standards will use the conventional, internationally adopted, definitions of the SI prefixes. Mega will mean 1 000 000, except that the base-two definition may be used (if such usage is explicitly pointed out on a case-by-case basis) until such time that prefixes for binary multiples are adopted by an appropriate standards body.

In December 1998 the International Electrotechnical Commission (IEC), the leading international organization for worldwide standardization in electrotechnology, approved as an IEC International Standard names and symbols for prefixes for binary multiples for use in the fields of data processing and data transmission.

Re:Go ahead

[sahonen]

Fuck SI. Talk about actual practical use. A GB has been 1,073,741,824 bytes ever since somebody decided they needed a unit bigger than the megabyte, which was 1,048,576 bytes. Everybody knows what a Gigabyte is. Only annoying pedants like you who say "Well, actually what you're talking about is a Gibibyte," even though it sound fucking ridiculous to say actually take this whole SI thing seriously.

Re:Go ahead

I think it's time for you know who to get his you know what out of his you know where...

Re:Go ahead

The old Latins and Greeks?

Re:Go ahead

[ceeam]

Thank you, but no thanks. You know - we've been using "normal" greek prefixes with meaning of 2^n long before you toddlers :) came up with this silly mixing of greek and latin prefixes. If you can't stand that 1GByte = 1024MBytes, but 1GWatt = 1000MWatts, it's kinda your own problem, but don't try and force others to be silly too. Otherwise someone will come up and will claim that it is inconsistent that the basic unit of mass is _kilo_gram and hence we should rename it to "boo". Will anyone be happy then or will it lead to less messing-up? (Remember, if you accept KiB heresy you are obliged to accept that 1KByte = 1000bytes!)

Re:Go ahead

[BlueHands]

What I would like to do is mod you +1 flamebait. What I would like to do is mod EVERYONE who starts thier post with "mod me -1 blah blah blah" as -10 what I would like to do is break down and cry when people have no clue what they are talking about. What i am going to go do now is walk a kilometer (thats 1024 meters dont you know) in your shows and see exactly what it feels like.

Re:Go ahead

[sr180]

Basically, the computer scientists designing computers settled on 1024 bytes in a kilobyte.

Around the same time, the telecommunications engineers settled on 1000 bytes in a kilobyte.

At the time, the two industries were reasonably orthogonal, and hence there was no problem. Now there is.

The hard drive manufacturers just did it to make the hard drives sound bigger. SI units and international agreements not withstanding, theyd market their drives using the largest numbers possible.

Re:Go ahead

[bohnsack]

> Talk about actual practical use

How about this? As capacities increase, you're becoming more and more impercise:

The difference between 1 kB and 1 KiB is only 24 bytes or 2.400%, but the difference between 1 MB and 1 MiB is 48,574 kB or 4.858%. The difference between 1 GB and 1 GiB is 73.742 MB or 7.374%. The difference between 1 TB and 1 TiB is 99,512 GB or 9.995%. The difference between 1 PB and 1 PiB is 125.899 TB (12.900%).

Do you really want to be dealing with a minimum of 125.9 TB of ambuguity, when discussing petabytes?

> Only annoying pedants like you who say

Without "annoying pendants" like me, there wouldn't be an Internet for trolls like you to play on.

The world you live in:

Q: What's the propagation delay of signals over Ethernet?
A: Hmnn... hard to calculate, because we don't really know the speed of light? - Guess we won't be able to build networks.

Q: Could we land a man on the moon?
A: I don't think so. We've only been able to measure the distance from the Earth to the moon with +/- 15% precision. We won't be able to do it.

Re:Go ahead

[Jazu]

Gibby?

Re:Go ahead

[ski_fun17]

Hard drive manufactueres suck. they should be on track with the rest of us. using 1024 instead of 1000

Postage Stamp Storage

[cybercobra]

Cool, the next time I need to send something over sneakernet to someone far away, I'll just send a postcard with 2 stamps on it. 1 postal and 1 storage stamp.

More information

[ploss]

More information about the company can be found at their website, http://www.nanochip.com.nyud.net:8090[Coral Cache Link].

Re:More information

Someone mod this karma whore down. There's nothing informative about posting a link to a company mentioned in the blurb...

impressive

[Hellasboy]

i'm impressed... 25 dvds for 1 terabit. but i think were all holding out until we hit 150 zip disks on a square centimeter or 172 ls-120's on the size of a heineken bottle cap.

Re:impressive

[Rosco+P.+Coltrane]

172 ls-120's on the size of a heineken bottle cap.

You're right, I'd rather drink a single cold one than eat 172 LS-120 disks...

Re:impressive

Hah, I love that .sig; I've got a dog, and I know EXACTLY what you're talking about.

Re:impressive

[jonbryce]

I have an SD card which is about 1/2" sq and stores 1GB. 2GB cards are available but fairly expensive at the moment. Or, you could look at Compact Flash cards which are about 1" sq, and you see 8GB cards available to those who can afford them.

The jump from there to 128GB which is what this article is promising isn't really too radical.

Re:impressive

[Punboy]

Free Terabit of Heinie with your Heineken! ...Thats Free Porn.

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.

Re:Issues untold yet

[Rosco+P.+Coltrane]

(a) Reliability: No words about how reliable the system and elements are ...
(b) Testing: How are they going to test this trillion element chip ? ...
(c) Redundancy: Is this process going to give more yield than conventional electronic processes ?

Do you understand the definition of a prototype?

I'm sure all your questions will be answered in due time, in 5 or 10 years when the device hits the street.

Re:Issues untold yet

[karvind]

I don't want to flame you, but I would take a scientific/engineering approach rather than accepting opinion from a wall-street magazine. It would be worthwhile to follow the bubble burst of the MEMS technology in the recent 4-5 years. Even after 10 years of work, MEMS elements have serious issues in packaging. Intel withdrew their MEMS program as it doesn't have enough yield. So just making prototype is not the end of the story.

As an engineer you have to take things with a pinch of salt. Every scientific idea may not be technologically feasible. In the end economics determine if the product will even hit the market or not. Nanotechnology is not cheap, so it is worthwhile consideration to see if it is even possible to tackle the important issues rather than hoping someone else will do it.

Re:Issues untold yet

I don't want to flame you either, but I think it's a little harsh to call MEMS a bust. TI seems to be pretty happy by marketing the MEMS chips behind DLP projectors, many hdtvs, etc; the inkjet printhead folks seem to be pretty happy with MEMS as well; you did point out airbag sensors, but Analog Devices is making accelerometers for video games as well; Motorola (now Freescale) is making lots of automotive MEMS pressure sensors; Cepheid has anthrax sensors in post offices; the list is actually pretty long...

Just because Intel couldn't make it work doesn't mean it's no good.

P.S. As an engineer myself, it's hard to admit this, but the Wall Street boys usually have the last say. Most of the 'bubble burst' in optical MEMS was actually not failure of the technology, but collateral damage of the telecom collapse.

Re:Issues untold yet

[duncanbojangles]

(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)

My guess is that they'll only do random/spot checking of one chip in each batch of the chips they manufacture. There would likely be a maximum of bad cells that are allowed and part of the read/write specification would be to mark bad cells at runtime so that checking the device is left mainly as an exercise to the buyer.

Dense but slow?

[M0RBO]

So do you read the bits with an Atomic Force Microscope? Sure it holds a terabit, but not useful if it takes a multi-million dollar machine and a decade to read/write that much. /didn't RTFA

1terabit != 1 terabyte

[soundproofing.noise]

1 tera a bit is roughly 25DVD's?

Re:1terabit != 1 terabyte

Let me introduce you to the word "redundant"...

Re:1terabit != 1 terabyte

[Mr2cents]

Indeed, or 1 terranibble per 100 DVD's.

ATM or AFM?

[fermion]

From the article it is hard to tell what they are taking about. IBM used an atomic tunnelling microscope, a reltively complicated piece of equipment that relies on the fact that quantum particles can tunnel through a potential, to move that atoms. The ATM can either be used to create a atomic scale picture of a surface, or move atoms. An atomic force microscope is simply a physical hammer that gently taps a surface and through the change in deflection creates an image. The tip on an ATM is currently so fragile I don't think it could be used to move atoms. The lifetime of a tip is pretty short just becuase of wear, and their is not way to reliable create good tips.

So we must assume they are talking about an ATM, which a largish and complicated peice of equipment. It requires a piezoelctric device to move the tip to the proper placed on the substrate. For years, such devics kept cell phones large. The ATM requires a highly senstive feeback loop to keep the current constant. And is still requires a very delicae tip that can be easily damaged. Durable tips are probably years away and involve carbon nanotubes. Tips that have a lifetime more than a few months are probably even longer away.

It is a neat idea and probably works well in the laboratory on a vibration cancelation table. How would it work on a portable in the train or in the car? Does anyone have any real details on the technology?

Re:ATM or AFM?

[notmuchtosay]

As someone already mentioned i think the ATM you refer to is usually called a STM (scanning tunnelling microscope). However an AFM does not need to operate in contact (hammering) mode. There are other techniques called non-contact/lift mode. In these mode you don't sense the repulsion from the surface. You actually drive the tip near resonance and then sense the change in frequency as the tip is pulled toward the surface.

It's the question of data intensity ;-)

But the average 125 Gigabyte drive is much bigger than 1 inch x 1 inch x 1 millimeter, no?

Checksums

[LaCosaNostradamus]

25 DVDs on a chip the size of a postage stamp

Well, not with the software overhead in various checksums that will be had in 2010:

• MPAA/RIAA field (the "copy checksum")
• Dept. of Homeland Security header (the "red checksum")
• UN Standards bit (the "blue checksum")
• .SUM (the "Microsoft checksum")

Those are apt to take up quite a bit of space. So maybe you'll get 15 DVDs (maybe 20 by paying Microsoft an expansion fee) on that postage stamp.

Re:Checksums

[mrgsd]

With each checksum containing an "Evil Bit" (or are they all evil?)

Re:Checksums

[LaCosaNostradamus]

That'll be covered by Microsoft's 2008 patent on its data infrastructure enterprise solution ".BIT". All the bits will be evil then.

Multiple Read/Write ?

Is this a mutiple write drive? I could not find that in the article. I have been told that a single write device at molecular level is easier to construct than a mutiple write device.

By the way, here is a link to an EE Times article on 200GByte disk Hitachi develops 200GB holographic disk. Linear dimension = 5inches. {Remember: 1 terabit ~ 125GB}

I have also read some articles on Quantum Dots being used to store data. Typically, they are about 20nm in size and will store 1-bit (yeah, the evil one!) each. That would get translated to 10^14 bits per sq in! Let's see where this thing goes in a few years.

ionbheem!
--

And thats just 2-dimensional

[mnmn]

Some earlier stories were mentioning stacking layers of memory to increase it. So considering structural, voltage, data and addressing layers as well, how much data can we store in a 1 inch cube?

Whatever that number, we'll still be running out of space since Windows 2050 will take 1/3rd of that space and games+movies the remaining 2/3rd.

Re:And thats just 2-dimensional

[gnuman99]

1 in cube would be 1e12^(3/2)bits or 1e18 bits. That is 1 exabit or 1Eb.

Re:And thats just 2-dimensional

[captain+igor]

Good luck removing heat from a 3D structure easily. That's the principle reason we don't have processing cubes instead of chips in our computers.

Fastest Transfer Rate

[ryanmfw]

So, if we attached a couple square inches of this stuff to a pigeon, or filled a 747 with some of these chips, and flew it around the world, how fast would the transfer rate be?

Re:Fastest Transfer Rate

[Rosco+P.+Coltrane]

So, if we attached a couple square inches of this stuff to a pigeon, or filled a 747 with some of these chips, and flew it around the world, how fast would the transfer rate be?

I know you're trying to be funny but...

What most people really look for in electronic communication networks is not transfer rate but good latency: if I can "download" the entire library of Congress by having it Fedexed to be in a big box full of disks, but I have to wait 3 weeks for the snail mail request to reach the LoC, the guys to package everything up and the box to reach me eventually, I may be better off downloading the LoC on a slower link that answers immediately.

Re:Fastest Transfer Rate

[Ziviyr]

So how fast is 0.000000551 LoC/sec? :-)

Re:Fastest Transfer Rate

[ryanmfw]

Of course that would be better, but, I would rather have a 747 filled with this stuff, because afterwards I'd have a personal jet that I could fly around the world. :P

Re:Fastest Transfer Rate

[Singletoned]

"So, if we attached a couple square inches of this stuff to a pigeon, or filled a 747 with some of these chips, and flew it around the world, how fast would the transfer rate be?"

There'd be an amazing transfer rate, but the lag would make CounterStrike quite difficult to play.

Re:Fastest Transfer Rate

[Dark+Lord+Seth]

African or European pigeon?

Impressive...

[Matilda+the+Hun]

...So how long before we start seeing those Brainboxes from 3001?

Re:Impressive...

[f()rK()_Bomb]

I believe what you are talking about is the Braincap or Brainman after the walkman.

Check out here for arthur c clarkes view on possiblity of this device and we well know how prophetic his vision is.

Don't hold out for them

[iammaxus]

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.

I'd be really surprised if we see this technology on the shelf in anything close to 5 years from now.

Re:Don't hold out for them

[spankey51]

Agreed...
It is in my oppinion that industry is very self regulating. We will have to ease slowely toward memory like this. I imagine one could buy something congruent to this technology today, but it would be prohibitively expensive. We hear "breaking news" about technologies like this so often... It barely phases me anymore.

The governing factor in the success of these cutting edge devices is consumer driven supply and demand. No doubt, there will be use for this level of storage density; the form factor is provocative, just like MiniDisk was. It seems that more often than not, these sort of inventions just disappear over time... overshadowed by properly marketed technologies, like CDs.

In any case, I imagine it will take quite a while before something like this becomes a mainstream medium. Not to lean too far left, but we do have to consider the MPAAs timeframe in figuring out what to put on a disk that can hold the genome of 1-200 species. They'll need to up with something like Ultra High Definition digital video to combine with their already outrageous levels of "deleted scenes" and "special features."
And what's the RIAA going to do? They sure won't throw half the world's available music on a postage stamp and sell it for $16.95! Nono... time for a new format: audio recording frequencies 2 Ghz above that which is discernable to the human ear in .WAV, with a two Gigabyte security tag.

Google

[blcknight]

http://www.google.com/search?q=1+terabit+in+gigaby tes 1 terabit is 128 gigabytes. That is the definitive answer from google. It's not 116, not 125.

Re:Google

[Unnngh!]

Yep...the poster you are correcting probably made the mistake of thinking that 1 terabit = 1 trillion bits; still have to count those in powers of 2, as well. 1 kilobit = 1024 bits, etc.

Re:Google

1 terrabit is 1 trillion bits. On my computer, bytes are 8 bits in a format called ASCII. 1,000,000,000,000 / 8 = 125000000000 bytes. A kilobyte is 1024 bytes. A megabyte is 1024*1024 bytes (except for silly hard drive manufactures who try to sell megabytes as 1024*1000 bytes, although it's wrong and there have been lawsuits over it). A gigabyte is 1024*1024*1024 bytes, and a terabyte is 1024*1024*1024*1024 bytes. Now 125000000000 / (1024*1024*1024)=116.41532182693481445312 gigabytes (unless again it's sold by a hard disk manufacturer in which case it's 119.20928955078125000000 gigabytes (so there)

What happened to Millipede?

[DaleBob]

There was an article written (I believe by researchers from IBM) in Scientific American about two years ago regarding Millipede that said they expected technology to come to market in 3 years. Now the article from the post suggests the project is all but dead. What happened? I'm too lazy to actually look at the patents, but it isn't clear at all how this new technology actually differs from Millipede. I'd guess the write and erase mechanisms are different.

Re:What happened to Millipede?

[noidentity]

Millipede? I played that game almost twenty years ago! That's old tech!

Re:What happened to Millipede?

[stefanb]

IBM will show a Millipede prototype at CeBIT in Hannover, Germany this month.

Re:What happened to Millipede?

IBM sold their HDD division to Hitachi. Presumably this has lessened their interest in pursuing these gadgets, except for the sake of intellectual property.

(too lazy to log in)

A square inch!

[NaruVonWilkins]

My god, it's two dimensional! Our memory limitations are over!

Re:A square inch!

[assassinator42]

It would get broken very easily. And you'd have a hard time picking it up. And my brain doesn't like thinking about 2D objects in a 3D world.

Re:A square inch!

[darkitecture]

But it's not in metric! We're doomed!

Re:A square inch!

[stinerman]

Hopefully this will increase the performance of two dimensional arrays! A boon for the graphics industry! Matrix multiplication carried out in O(1)!!!

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...

Re:Such products are a godsend

[Ziviyr]

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.

Theres alot of room to improve ona chocolate bar after you've been using it for a couple years.

I'd personally advise only consuming them then once, then buying a new one when I wanted to use it again.

Re:Such products are a godsend

[Woy]

"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."

Actually, its much easier to sell more chocolate bars, since they are consumed on use, than chips, that can last a few years.

Re:Such products are a godsend

Damn, I wish someone told me this earlier! Buying a new CPU each day is getting expensive.

Re:Such products are a godsend

They are lucky because it is such a minor feat to double performance after all.

Seriously, do you have any clue the amount of money it's taking nowadays to double the performance? Enough to make companies question how much money actually needs to go into R&D.

Re:Such products are a godsend

[appleLaserWriter]

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.

All the chocolate bar maker needs to do is wait until the customer gets hungry and needs a new bar. No R&D needed!

This is redundant

[SlashThat]

As the writer says, it's 1 terabit, or 125GB. Which is about 25 DVDs, given that a DVD is about 5GB. And yes, it's denser than hard disks, but not by far.

Punching holes in polymer?

How could this ever replace magnetic hard drives if the chip "punches holes" into something to represent 1 or 0? Sounds like there would be "moving parts", and how do the holes "heal" in order to change the state?

Re:Punching holes in polymer?

[DaleBob]

It's not clear how this new technology is different from the IBM Millipede project, but Millipede took a heated atomic froce microscope (AFM) tip and stuck it into a polymer substrate to form the hole. The holes are erased by heating the surface surrounding the hole until melting happens and the hole just fills in as surface tension makes it flat again. This hole punching and erasing using heating happens really fast since the size scales are so small. Although I'd imagine the write speed is slower than a hard drive or flash memory.

comparison to core memory

1 terabit of core memory == 1 square mile
1 terabit this stuff == 1 square inch

vaporware

This is, by my count, the 1,0131st story in slashdot that has enthusiastically described a radical new storage technology, not one of which as ever gone into production.

impressive-Trilevel storage.

Radical would be dumping the binary numbering system. Both for computing, and storage.

On ebay yet?

How come it isn't on ebay yet? Geeez, how long will I have to wait? Oh, the humanity!

Re:how big is a postage stamp?

[ScrewMaster]

Well, on the plus side since all you'll have to send is the stamp there won't be anything to lick.

Re:terabit != one trillion bits.

[bohnsack]

Where do these people learn their math?

Where did you learn your math? One trillion X is, by definition, a terra X.

See here and here

AFM

[DaleBob]

The IBM Millipede project doesn't use tunneling microscope technology (ATM, or usually STM). It uses a modified AFM tip that can be resistively heated. The hot tip pushes into a polymer surface and creates a hole. The hole can be "erased" by heating close to the surface and the region around the hole melts and fills it in. The reading is done with cold tips using regular AFM technology.

OK! ENOUGH BULLSHIT NUMBERS!!!

[__aailob1448]

We don't measure HDs in Terabits . 1 Tbit = 128 GBytes or 128 gigs3

Second, converting this from inches to Centimeters, we get slightly less than 20GB/cm^2

Yes ladies and gentlemen, 20 Gigs per Squared centimeters.

That's a nice increase but it sure as hell isn't overwhelming.

Assuming a radius of 5 cm for a 3.5" HD, we get a surface of 80 cm^2 per platter. That comes to 800 Gb per platter. around 8 times the current density.

These new-gen HDs will be at most 8 times bigger than those we have right now.

That's it. 8 times. Not even a single order of magnitude.

Now mod this up or be destroyed!

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[Ziviyr]

And I don't assume they had error correction overhead raining on their parade either...

It does tick me off when someone measures really big sizes in bits. Especially on devices that manipulate data in blocks that are 16384 times the size of the chosen metric.

Measuring network speeds in bits is also rather irritating.

And I'll try not to get started on when people insist on using decimal reasoning with binary data size calculations. (anyone want my old 134.217728 megabyte stick of ram?)

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[dbIII]

We don't measure HDs in Terabits

It's a business journal - and you can tell. We don't measure size in molecules either - it's a long way from H2 to a really big polymer chain - or since molecules don't make sense where crystals are involved, a single crystal of silicon they cut the wafers from, a jet turbine blade or a cubic galena crystal the size of a house.

They should stick to their standard business journal units - football feilds - if the ewant to be vague.

8 times. Not even a single order of magnitude.

Think of the readership. A response from some would be "IBM can only increase it by two orders of magnitude by these guys can increase it 8 times! Buy! Buy! Buy!

We need better teaching of basic mathematics in high schools so the guy whose dad owns the company still picks up a clue along the way. Either my country has become a dumping ground for the worst of US management or the USA is really in trouble.

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[NaruVonWilkins]

This is a chip, not a platter. There's almost no correlation. This is memory, not hard disk.

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[__aailob1448]

Doesn't matter whether it's a chip, a platter or a magic banana. This is about density. Now, if you told me that transfer speeds and latency are superior to those find in RAM nowadays, it would change everything but it doesn't appear to be the case.

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[NaruVonWilkins]

Actually, it matters a lot whether it's a chip or a platter. A platter requires, in today's hard disk drives, a set of support mechanisms equal to much more than 100% of the platter. A chip of equal storage density per square inch as a platter will take up less space, require less overhead, and generate less heat. The comparison I'd like to see is to today's solid state storage devices - USB drives, CompactFlash, etc. I'm pointing out that this is being compared to a technology it will not significantly affect the development of (except, perhaps, in cache).

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

That's a nice increase but it sure as hell isn't overwhelming.

You make a good point, but there are some issues that could make this a big deal compared to hard drives, specifically heat, resistance to shock damage, production cost, power usage, lower latency and/or higher tranfer rates. A non-volatile memory with the performance characteristics of even PC133 would have a lot of very useful applications.

Sadly their website doesn't seem to have much on any this (at least what I can grab out of Google's cache, their DNS seems to be fux0red ATM).

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[ajs]

"We don't measure HDs in Terabits . 1 Tbit = 128 GBytes or 128 gigs3"

YOU may not, but I assure you that those doing research into hard-drive platter manufacture do. What's more, this isn't a hard-drive platter, it's a random-access device, which are ALWAYS measured in bits, not bytes (except when labeling a product for the masses).

This is not a product, ready to ship, it's a prototype, and as such you're being exposed to the technical terminology of the industry that produces these devices, NOT the technical terminology of the industry that consumes them.

Please carry on.

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

Either my country has become a dumping ground for the worst of US management or the USA is really in trouble.

You live in Iraq?

Re:OK! ENOUGH BULLSHIT NUMBERS!!!

[iolaus]

That's it. 8 times. Not even a single order of magnitude.

It's a single order of magnitude in base 8!

What size is the prototype?

[spworley]

The article says they have working prototypes. Of what? The implication is that it's a device that's a square inch in size, and it holds a terabit of data. But from the usage of "square inch" I think the reality may mean a density of 1 terabit per square inch, not that they have a terabit device. (I hope I'm wrong!). For example, they may have a prototype that stores 1000 bits in an area of a billionth of a square inch. That's a lot different than an actual terabit device! I wish articles had more details...

Re:What size is the prototype?

[corngrower]

It's one thing to store a small amount of data (a few thousand bits) very densly. It's another to be able to write and access large amounts data stored at that density reliably at high data rates. Just achieving a high density of data storage is not a big deal. The article doesn't indicate that they've actually solved the problems necessary for a successful commercial product.

At the end of my nose...

[exp(pi*sqrt(163))]

...there is a single atom. Orbiting it is an electron. When it's in a spin up state I consider it to contain a 1. When spin down it's a zero. There: a prototype of a multi exaterapetabit/mm^3 storage device at the end of my nose. Oh wait - I might be able to hype this up more. Oh yes...it's an electron, so it's in a superposition state. It's a multi exapetaterabyte/mm^3 quantum computer at the end of my nose. Surely /. have got to publish this story now.

Re:At the end of my nose...

[roman_mir]

There is no God - I concur.

God.

Re:At the end of my nose...

[iggymanz]

i used to have one of those but then I sneezed

What's with Nantero??

[luwain]

Prototype Arrays of Atomic Force Probes?? Is this real technology? I wonder is the talk of a real product by 2007 is credible, or just marketing to attract venture capital. I'm still waiting for products based on NRAM (made up of arrays of carbon nantubes) from Nantero (nantero.com). I wonder if "atomic force probes" are easier to manufacture than "arrays of carbon nanotubes"? Will Nanochip beat Nantero to the marketplace, or will they just burn through venture capital and next year we'll hear about another "Nano-'something'" company with some other "revolutionary technology" that's going to produce a marketable product "real soon now".

Re:What's with Nantero??

[kebes]

I don't expect this technology to be on the shelf anytime soon (maybe in 8 years though).

However, in response to your question:
I wonder if "atomic force probes" are easier to manufacture than "arrays of carbon nanotubes"?
The answer is: "yes." Trying to line up carbon nanotubes is difficult, and most importantly, is starting from scratch. No one knows how to do it, and so it is all very experimental and tricky. Manufacturing a huge array of atomic force probes, however, is a natural extension of the lithography industry that currently exists to make microchips of all sorts. In fact, the alignment tolerance for making these probes are easy compared to making a CPU chip. Where I work, we buy wafers with hundreds of these probes on them for ~30$. They are only that expensive because we (academic research) are such a limited market. If they were mass produced for use in an end-consumer product, they would be dirt cheap.

Re:What's with Nantero??

[Mister+Attack]

um... AFM tips cost quite a bit more than 30 bucks for a wafer. Try $50/tip, in bulk. Not cheap. The cantilevers are hard to make.

Re:What's with Nantero??

[bloggins02]

Prototype Arrays of Atomic Force Probes?? Is this real technology?

Maybe. Maybe not. Who knows? But one thing's for sure: with an acronym like PAAFP I'm pretty sure the marketing department hasn't found out about it yet.

Re:What's with Nantero??

[kebes]

I don't mean to nit-pick, but for fun I just contacted Veeco/DI for a quote. They will sell me a wafer with 500 probes for 3672.55 US$. Since each probe has 4 tips on it, that's a lithography cost of 1.83 US$ per tip. That's for generic SiN tips (specialty and ultra-sharp ones cost more, of course).

So I under-estimated, and you over-estimated. I still think my point holds: the current costs would drop dramatically if the technology was scaled up to make a commodity (like hard drives). The tolerances on making SPM tips are much lower than making transistors. I can see this technology becoming very affordable.

Re:What's with Nantero??

[Mister+Attack]

Well, OK, you can get the generic contact mode tips for cheap, but contact mode AFM tends to wreck your surface pretty thoroughly after a few passes. At a minimum, you need to be looking at tips in the TESP series -- and those are $30-40 each, in wafer quantities.

Just thought you'd like to know, since I can't message you directly (at least I don't think so)

when will we see consumer devices?

[kobaz]

About 5 years ago there was a story just like this on slashdot that was making all the commotion. The claim was three dimensional non-volatile memory and the capacity was 660gigs per cubic cm. So far I haven't heard anything since the slashdot story 5 years ago.

It would be nice to actually be able to buy this technology that always seems to be "about to come out". It would also be nice to be at a price comparable to current consumor storage devices.

For now we will still be stuck with the bottleneck of bottlenecks, the spinning harddrive based on technology that was thought up somewhere around the 1960s (or was it even the 50s?).

Re:when will we see consumer devices?

[MajorDick]

Its called bubble memory,

Its been here and gone, unfortunatley due to cost for the most part, it was a wonderful concept, albeit a bit slow, (slow meaning still much much faster than mechanical means I.E Hard drive)

There was a company called Elephant (I belive based on the company that sold floppy disks in the 70's and early 80's) That sold a Bubble Memory based Hard Drive that had na IDE Interface, last I saw some 5 years ago it was like 1.2 gig, it was meant for Mil Spec applications and had a shock resitance of something insane.....

My DG1 Laptop Circa 1983-84 had a Plasma Screen and Bubble Memory, I wish I still had it it was way cool, but at 10 grand it should have been :)

Why go tera, when you can go peta?

If you really want high memory density, and you don't mind using some form of scanning probe microscope for readout, there's a nutty proposal to use silicon surface dimers (http://jdj.mit.edu/atoms/dimer-stm.html). The silicon (001) surface reconstructs so the top layer atoms pair up to form two-atom dimers, and each dimer has two possible configurations -- either tilted one way or the other. The state of each dimer can be read, and more importantly written, with the tip of a scanning tunneling microscope (rather than an atomic force microscope like the article talks about).

Storage capacity? Well, each dimer is about 4 by 8 angstroms, so we're talking 3.2e18 bits per square metre, or approximately 2 petabits per square inch.

There's just a few technical difficulties, I guess. Firstly, you need to keep the whole system pretty close to absolute zero or the silicon dimers start thermally flipping, erasing your data. Secondly, you need to keep it under ultra-high-vacuum conditions, which means your system will probably be the size of a room and need a UHV expert to operate it. Thirdly, it'll be insanely slow, capable of writing a few bits per second if you're lucky. And finally, an ultra-low temperature ultra-high vacuum scanning tunneling microscope with atomic resolution will probably set you back quite a few million bucks.

Still, it's interesting in that it gives you an estimate of what the ultimate physical limits of two-dimensional data storage density are likely to be. Realistically you'll always need quite a few atoms per bit for any system you want to operate at room temperature.

Yeah, but ...

[elronxenu]

They didn't explain how many volkswagons per metric second.

Re:terabit != one trillion bits.

Ask the hard drive manufacturers!

Re:how big is a postage stamp?

[x2A]

in other news: lollipop share prices go up!

*grunt* must... lick... something...

This is a true magnetic method

[jkocurek]

Other wise it is similar to Millipede. To increase density, they can move the R/W heads and the media. I've been following this for a while, I have exchanged e-mails with Tom Rust starting back in 1998. Like with fusion, it seems that this has been just a year or two from commercialization ever since...

They have had working prototypes for a long while. I suspect that the problems have more to do with reliably getting it into production.

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.

Re:data transfer rate

[TodPunk]

You're assuming that all 1000 bits of data are relevant to the request made by the accessing system. In a HD situation, that's not always true, even if it's 4 heads. In this situation, I can't imagine getting more than 50% average return per seek.

Potential is fine, but realistically, you're right, a lot of work has to be done, and this doesn't look like the solution to end all solutions, especially if HDs can match this "potential" performance within the next 3-5 years or whenever this matures enough for productions

In reality, the solution to better storage will probably come out of some creative whiz's mind and won't be publicized well until just before it's ready for production, and even then only because the VCs in charge of funding the production will push it through due diligence. We should be looking in garages and cubicles for pet projects of quiet geniuses, not half-baked publicity stunts from articles that can't produce any details.

Wooohooooo, more pr0n for me!!!!

[0x000000]

Hey sorry guys, i'll be right back, filling up my new terabit HD.

Ah, now i won't ever feel like i don't have enough.

Re:Wooohooooo, more pr0n for me!!!!

Uh, 1 terabit is 128GB. Whoa, you 1337!

Overheard at IBM...

[isny]

Boss: What are you two working on? You've been sitting and staring at the screen for hours.
Engineer 1: Uh....the millipede project.
Engineer 2: Yeah. Lots of data stored in two dimensional space.
Boss: Great! Keep up the good work. (Leaves)
Engineer 1: Whew that was close.
Engineer 2: In more ways than one. Look out! Here comes the spider again...
Engineer 1: I love MAME.

Production vs. Prototype

[wcdw]

A lot of people have complained about how many technologies get reported, and are never heard of again.

This is pretty ironic, given that most companies (FUD aside) will only talk about products to a) attract venture capital, or b) sell an actual product.

And any company which has burned all the v.c. without bringing anything to market is hardly to going to trumpet about it.

Whether this technology will be the next best thing or not is open to question (that's what makes the stock market work ;). What I found most interesting was the reference to an agreement with Ovonics.

The stock market may hate Stan and company, but their list of accomplishments is pretty impressive, including having the word 'ovonics' added to the english language.

Either way, the news is a useful harbringer of things to come. Even if *this* technology doesn't make it, something else will. Somone will ALWAYS have a better idea. This is just a watermark for where the so-called state-of-the-art currently floats.

This would be great...

[Upaut]

For the development of E-books that contain vast libraries. I believe that all the books in the library of congress can be stored on one or two terabytes. Imagine, having all historical books and documents in a single book... From Aristotle to Zinill... All we need is a good powersource and more flexible e-paper and were all set. I believe Philips is working on a good e-paper, and that "new lithium battery we read about last week"might fit the bill for the time being...

Anyone else think this is a good use of the technology?

Re:This would be great...

[Vo0k]

Naive... This would never get through publisher agencies. Just like "all movies" or "all songs"...

Re:terabit != one trillion bits.

[Dominatus]

ignorance. Bits are measured normally, 1000 unit intervals. 1000 bits in a kilobit, 1000 kilobits in a megabit. It's BYTES that use the 1024 convention for kilo, mega, giga, etc, and even then that's not technically correct, as there is another standard for that.

bytes, bits, nibbles blah!!!

[falser]

Why can't people just standardize on a common unit of measurement such the number of Encyclopedia Brittanica's or the number of Library of Congress's?

Re:bytes, bits, nibbles blah!!!

[bill_mcgonigle]

Suffice it to say, it's the minimum system requirement for Office 2012.

cocaine

[realitybath1]

makes chocolate bars (more) addictive, and the internet (morer) faster.

Not so

[A+nonymous+Coward]

First usage was 1000 == grand, as in that sap lost 25Gs on a horse, or the kidnap ransom was 100Gs, etc. G for 1000, M for 1,000,000, and B for 1,000,000,000 were in common use for budgets and gross national products long before some smartass computer guys decided that 2^10 was so close (1024) to 1000 that it was good enough to coopt the idea, which might have been ok until they compounded the error by re-using M, then went on to G.

I applaud the Gi etc standard. It behooves the computer people, who came second, to use their own abbreviations, or as you would say, their own fucking abbreviations. Since they didn't have the fucking common sense to steer clear of the already-used fucking M, I say fuck 'em and make 'em use somebody else's abbreviations, since they have proven themselves incapable of responsibly picking their own.

Re:Not so

[xip.dk]

I believe the first use was K = kilo = 1,000, M = mega = 1,000,000, G = giga = 1,000,000,000 and so on, since G for grand is, as far as I know, a purely american expression. I think that physicists were using those units long before your G, M and B were in "common use for budgets and gross national products".

Gay

The new term is queer, so you should be asking him to get his unit bent. fag.

Snore... Again... Snore...

Well, for the past 20 years I can actually clearly remember the computer industry, claims like this have been coming constantly.

I mean, IBM back in the early 80s were talking about holographic memory, claimed it even worked, maybe they even shipped it, but noone I've ever met has ever seen it.

Bubble-memory was a hot topic at some time. I heard that for a while it even was shipped. Well, the problem was that it was too expensive to produce, their manufacturing yield was terrible. Well long story short, the technology never made it into the house.

I can't remember the names of all the companies, but the technologies ranged from non-moving CD technology that used beam splitters to shoot the laser around the surface instead of moving the disc. I've heard of multiheaded disc changers. I've heard of plasma based storage methods. They never made it either. Either they would produce the techology and it would never break into the market due to costs, or they needed to raise a billion dollars first just to test to see if it works, or worse, they never managed to make it at all.

Recently a company which really messed up the Norwegian stock exchange called Opticom was claiming to have used multilayered thinfilm polymer in order to provide a method of extremely high density, low cost, reliable datastorage. It would be able to fit massive amounts (not sure if terabit was mentioned) of data on a single layer of plastic and the plastic could be layered. I was going to completely devistate the flash and hard drive market since it gave RAID capacities in semiconductor size with zero power usage when not reading or writing. Well, they never produced anything except hot air. In fact I have located prior art on every patent they have filed and was hoping they'd make it happen so I could sell my search results.

The fact is, until I see a storage product, not just at a trade show, but in real life, in the store where I can buy it, I won't believe any outrageous claims that "Out product holds 50X the data as magnetic and is 10x faster than silicon". I've come to believe that claims like this are made simply so people can get the typical $10 million payment from Intel, AMD, Seagate, etc... to make sure that if it ever does happen, then patents won't be a problem. Until it's in your hand, it's vapor

And if you can do better still, streaming.

[Kjella]

but I have to wait 3 weeks for the snail mail request to reach the LoC, the guys to package everything up and the box to reach me eventually, I may be better off downloading the LoC on a slower link that answers immediately.

And nevermind that if the source is persistant and fast, the content is changing or it is impossible to predict which part you'd want later, it might be superior to simply download on demand. The missing factor here though is persistant. URLs move. Torrents die. There is no "repository" to get from. Yet.

Kjella

40 bits on the address bus...

[carlmenezes]

Kinda gives you an idea of how huge a 64 bit address space is. I mean, 116GB is still 24 bits smaller - by about 16 million times (10 bits = 1K, 24=10+10+4) - than the amount of data 64 bits can address.

Could this be an indication of the data volumes we will be dealing with in the future when 32 bit computing on the deskop is obsolete?

Re:terabit != one trillion bits.

[smallguy78]

but 125gb of storage surely, 8 bits per byte unless I've been living a lie

In Related News

[Foolomon]

LinuxWorld announced today that 4 of these postage stamp-sized storage devices have been preordered to hold all of the spewage coming from Dvorak about its demise.

So Long Virtual Memory OS

Because today's machines are getting closer -- if not already there -- to supporting the entire addressable space of a 32-bit processor in RAM (0 -- 2^32) the need for operating systems to support virtual memory management is becoming less important.

I'm one of those dinosaurs who remembers authorizing the purchase of 64MB of internal memory for untold thousands and wishing the whole damn thing would run in internal memory. If only for the performance gain.

With nanoscale memory like this the whole industry becomes embedded and the year 2050 robotics predictions don't seem so far-fetched.

Thank you Richard Feynman. There is indeed "Plenty of Room at the Bottom."

OT -- Sig

FYI -- Zapata wasn't the first to say that ... Mikhail Bakunin was.

However...

[Mythrix]

...this also means that they *have* to improve. If they don't, or do some bad choices or design, they'd quickly lose marketshare to better competitors.

While for something like chocolate bars, if you've managed to make your brand popular, you can just make more of the same and still get good sales.

Holographic Data Storage Systems (HDSS)

[Nitescan]

What do you think about holographic storage devices and their future?

yeah right

considering a bit is only 1/8 a kb it is a bit deceptive. It'll be the day when you can fit 5 terrabytes into the tiny size of an american stamp.