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Scientists perfect technique to boost capacity of computer storage a thousand-fold

New technique leads to world’s densest solid-state memory that can store 45 million songs on the surface of a quarter

Date:
July 23, 2018
Source:
University of Alberta
Summary:
Scientists have created the most dense, solid-state memory in history that could soon exceed the capabilities of current hard drives by 1,000 times. New technique leads to the densest solid-state memory ever created.
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The most dense solid-state memory ever created could soon exceed the capabilities of current computer storage devices by 1,000 times, thanks to a new technique scientists at the University of Alberta have perfected.

"Essentially, you can take all 45 million songs on iTunes and store them on the surface of one quarter," said Roshan Achal, PhD student in Department of Physics and lead author on the new research. "Five years ago, this wasn't even something we thought possible."

The scientists used the same technology they developed to manufacture atomic-scale circuits, which allows for quickly removing or replacing single hydrogen atoms. The technology enables the memory to be rewritable, meaning it could lead to far more efficient types of solid-state drives for computers.

Ready for real-world use

Previous discoveries of atomic-scale computer storage were stable only at extremely low temperatures, but the new memory works at real-world temperatures and can withstand normal use.

"What is often overlooked in the nanofabrication business is actual transportation to an end-user, which simply was not possible until now given temperature restrictions," noted Achal. "Our memory is stable well above room temperature and precise down to the atom."

Achal explained the technology has immediate applications for archiving data. Next steps will include increasing read and write speeds for even more flexible applications.

More memory, less space

Achal works with U of A physics professor Robert Wolkow, a pioneer in the field of atomic-scale physics. Wolkow perfected the nanotip technology that allows scientists to manipulate single atoms on a silicon chip -- a technology he said has now reached a tipping point.

"With this last piece of the puzzle now in hand, atom-scale fabrication will become a commercial reality in the very near future," said Wolkow. His spinoff company, Quantum Silicon Inc., is working on commercializing atom-scale fabrication for use in all areas of the technology sector.

To demonstrate the new memory, Achal, Wolkow and their fellow scientists encoded the entire alphabet at a density of 138 terabytes per square inch, roughly equivalent to writing 350,000 letters across a grain of rice. For a playful twist, Achal also encoded music reminiscent of video game soundtracks from the '80s and '90s.

The research, "Lithography for Robust and Editable Atomic-Scale Silicon Devices and Memories," appears in the current issue of Nature Communications.


Story Source:

Materials provided by University of Alberta. Original written by Jennifer-Anne Pascoe. Note: Content may be edited for style and length.


Journal Reference:

  1. Roshan Achal, Mohammad Rashidi, Jeremiah Croshaw, David Churchill, Marco Taucer, Taleana Huff, Martin Cloutier, Jason Pitters, Robert A. Wolkow. Lithography for robust and editable atomic-scale silicon devices and memories. Nature Communications, 2018; 9 (1) DOI: 10.1038/s41467-018-05171-y

Cite This Page:

University of Alberta. "Scientists perfect technique to boost capacity of computer storage a thousand-fold." ScienceDaily. ScienceDaily, 23 July 2018. <www.sciencedaily.com/releases/2018/07/180723132055.htm>.
University of Alberta. (2018, July 23). Scientists perfect technique to boost capacity of computer storage a thousand-fold. ScienceDaily. Retrieved December 3, 2024 from www.sciencedaily.com/releases/2018/07/180723132055.htm
University of Alberta. "Scientists perfect technique to boost capacity of computer storage a thousand-fold." ScienceDaily. www.sciencedaily.com/releases/2018/07/180723132055.htm (accessed December 3, 2024).

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