Data Storage Breakthrough Could Store the Library of Congress on a Dust Mite
The densest data storage device ever invented.
Using this new data storage technique, you
could fit the entire Library of Congress on a cube smaller than a dust mite—or
the size of George Washington's pupil on a one dollar bill.
A team of nanoscientists led by Sander Otte
at Delft University of Technology in the Netherlands has just unveiled the
densest method ever developed to store re-writable digital data. By scooting
around individual chlorine atoms on a flat sheet of copper, the scientists
could write a 1 kilobyte message at 500 terabits per square inch. That's around
100 times more info per square inch than the most efficient hard drive ever
created. Otte says the method could theoretically fit every book ever written
onto a flat copper sheet the size of a postage stamp. The new storage device is
outlined today in the
journal
Nature Nanotechnology.
"This density is two to three orders of
magnitude beyond current hard disk or flash technology. An advance of this size
is remarkable, to say the least"—so writes Steven Erwin, a theoretical
physicist with the U.S. Naval Research Laboratory who was not involved in
developing the new technique, in an essay accompanying the scientific paper.
Way back in 1959, renowned physicist Richard
Feynman gave a famous speech at at CalTech called "There's Plenty of Room at the Bottom."
He spoke about the promise of writing with individual atoms, musing on how
exactly you could store a fantastically large amount of data in an
inconceivably small space. Today, Otte and his team took a page out of
Feynman's book, and quite literally too.
Otte's team used individual atoms to encode a
short section of Feynman's speech on a copper tablet about 100 nanometers wide
and tall. That's so small it could fit on a Flu virus with room to spare. Otte
and his colleagues then cleared the spaced and typed out a segment of On the
Origin of Species by Charles Darwin using the same atoms.
Here's how it's done: Otte's team found that
they could put chlorine atoms onto a cold grid of copper metal and get them to
form into perfect squares. Think of it like a checkerboard. Any empty spot that
was missing a chlorine atom would like a dark square on Otte's checkerboard.
Next, the researchers found they could scoot around the chlorine atoms on this
grid, sort of like a sliding block puzzle, and thus
rearrange where the dark spots on the grid are. It's done with a tool called a
scanning tunnelling microscope, which is a bit like an ultra-thin needle that
can nudge atoms up and down, left and right.
To create the data storage device, Otte
starts with a copper plate that's been randomly peppered with chlorine atoms,
leaving plenty of blank spaces. He then scoots around the atoms until he's
formed a larger 12-by-12 grid with chunks of ordered atoms and darker blank
spaces. If any of these 144 chunks has some fatal error—say the copper
underneath has some elemental impurity—Otte can mark off that box as defective
with a tiny 4-atom symbol in its upper left-hand corner.
The arrangement of atoms and blank spaces
translates to individual bits of data. A blank space followed by a chlorine
atom is a 0, while the reverse (a chlorine atom and then a blank space) is a
1. Using this method, Otte can store any digital information, be it lines from
a speech or small segments of computer code.
The scientists keep their copper tablets from
being jumbled by storing them at hyper-cold temperatures and isolated in a
vacuum. That's technology you won't soon see on a thumb drive, "so the
[practical] storage of data on an atomic scale is still some way off. But
through this achievement we have certainly come a big step closer," says
Otte. At -320 Fahrenheit, the research team was able to store one of their 1 kilobyte
records for about two days with no errors. And rewriting one of the copper
slates is as simple as just moving around the chlorine atoms to form new
combinations of ones and zeroes.
There's one other downside to Otte's method.
It may be a dense way to store data, but it's also heartbreakingly slow.
Reading a few short sentences on one of the copper blocks takes around 1 to 2
minutes, and writing them takes 10. But Otte's team is investigating new
methods they believe could speed up their writing and readout speeds by an
incredible amount, up to about 1 megabit per second, about a tenth as fast as
the average U.S. computer downloads data online.
Source | http://www.popularmechanics.com/
Regards
Pralhad
Jadhav
Senior
Manager @ Library
Khaitan
& Co
Best
Paper Award | Received the Best Paper Award at TIFR-BOSLA National Conference on
Future Librarianship: Innovation for Excellence (NCFL 2016) on April 23,
2016. The title of the paper is “Removing
Barriers to Literacy: Marrakesh VIP Treaty”
Note | If anybody use these post for forwarding in any social media coverage
or covering in the Newsletter please give due credit to those who are taking
efforts for the same.
No comments:
Post a Comment