Hard drives currently have a one terabyte limit

 

A single hard drive with four terabytes of storage (4TB) could be a reality by 2011, thanks to a nanotechnology breakthrough by Japanese firm Hitachi.

The company has successfully managed to shrink the read-write head of a hard drive to two thousand times smaller than the width of a human hair.

 

The smaller head can read greater densities of data stored on the disk.

 

Hitachi said the advance would fuel the "terabyte era", with a 4TB drive able to hold more than a million songs.

 

Hard drives store data by magnetising the surface of the disk in a pattern which represents the data in digital form.

 

The data is stored digitally as tiny magnetized regions, called bits, on the disk. A magnetic orientation in one direction on the disk could represent a "1", while an orientation in the opposite direction could represent a "0".

 

To store an ever increasing amount of data, the magnetised regions on the disk are packed ever closer together, requiring smaller and smaller read-write heads.

 

Current hard disks can store about 200 gigabits of information per square inch (6.4sqcms) while Hitachi believes its new technology means it can store up to 1 terabit of data per square inch.

 

However, as the heads get smaller the amount of electrical resistance grows, generating noise output and adversely affecting the head's ability to read data off the disk.

 

Big differences

 

Hitachi's solution is to return to a technology which spurred an explosion in hard disk storage 10 years ago and led to the Nobel prize for physics last week for French scientist Albert Fert and Peter Grunberg of Germany.

 

They discovered the phenomenon of "giant magnetoresistance" (GMR), in which weak magnetic changes give rise to big differences in electrical resistance.

 

The knowledge allowed industry to develop sensitive read tools, called GMR heads, to pull data off hard drives in computers, iPods and other digital devices.

 

In recent years GMR heads have given way to so-called tunneling magneto-resistance (TMR) heads, which have been able to read more densely-packed disks.

 

However, Hitachi has discovered a method of reducing noise and boosting signal output when using GMR heads and so further increasing the density of data on a disk than can be read.

 

"We changed the direction of the current and adjusted the materials to get good properties," said John Best, chief technologist for Hitachi's data-storage unit, in an interview with AP.

 

"Hitachi continues to invest in deep research for the advancement of hard disk drives as we believe there is no other technology capable of providing the hard drive's high-capacity, low-cost value for the foreseeable future," said Hiroaki Odawara, Hitachi's research director, at its Storage Technology Research Centre.

 

Hitachi predicts it could release a hard disk for desktops with 4TB of storage and a laptop with a 1TB drive by 2011.

 

The company said this would mean hard drive storage would continue doubling every two years.

 

http://news.bbc.co.uk/1/hi/technology/7044606.stm

Hmm! From scanning tunneling electron microscopes to tunneling magneto-resistance heads - sounds like a logical leap to make. I used to like the images we first saw of various enzymes using the scanning tunneling electron microscope - really amazing to actually "look" at enzymes on the atomic scale!

I wonder somewhat about the robustness of these newer technologies though.. It takes less and and less to damage the media as well; still backups could save the day, as they have always done..

Just how do they read the resistance? Hmm.. I had better check it out.:)

Thanks Ian!

no problem!

I can remember when top-of-the-range computers had 1GB hard-drives.

 

It's less to do with music more video.

I still hear the screeches of a 48k rubber-key spectrum trying to load my favourite games, seconds before it crashed abruptly :(