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5-D ‘Superman’ Memory Crystal Created

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SOUTHAMPTON, England, July 10, 2013 — Nanostructured glass has been demonstrated as a medium for recording digital text in 5-D using a femtosecond laser. The portable memory technology could store vast quantities of information — 360 TB on a disc — for more than a million years.

The technology, developed at the University of Southampton and Eindhoven University of Technology, was dubbed the “Superman” memory crystal as a nod to the “memory crystals” featured in Superman films. The method records data via self-assembled nanostructures created in fused quartz. The five dimensions include size and orientation in addition to the 3-D coordinates of these nanostructures. The storage allows unprecedented parameters, including 360-TB/disc data capacity, thermal stability up to 1000 °C, and an unlimited lifetime.

Scientists at the University of Southampton have experimentally demonstrated the recording and retrieval processes of five-dimensional digital data by femtosecond laser writing.
Scientists at the University of Southampton have experimentally demonstrated the recording and retrieval processes of five-dimensional digital data by femtosecond laser writing. The storage allows unprecedented parameters, including 360-TB/disc data capacity, thermal stability up to 1000 ºC, and practically unlimited lifetime. Pictured here, digital data recorded into 5-D optical data storage. Images courtesy of the University of Southampton.


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“We are developing a very stable and safe form of portable memory using glass, which could be highly useful for organizations with big archives. At the moment companies have to back up their archives every five to 10 years because hard-drive memory has a relatively short life span,” said lead researcher Jingyu Zhang of the University of Southampton’s Optoelectronics Research Centre (ORC). “Museums who want to preserve information or places like the national archives where they have huge numbers of documents, would really benefit.”

The self-assembled nanostructures change the way light travels through glass and modify its polarization, which can be read using the combination of an optical microscope and a polarizer similar to that found in sunglasses.

Jingyu Zhang
Jingyu Zhang

The investigators successfully recorded a 300-kb digital copy of a text file in 5-D using an ultrafast laser. The file was written in three layers of nanostructured dots separated by 5 µm.

“It is thrilling to think that we have created the first document which will likely survive the human race,” said ORC group supervisor professor Peter Kazansky. “This technology can secure the last evidence of civilization: all we've learnt will not be forgotten.”

The researchers are now searching for industry partners to commercialize the technology.

The work, conducted under the European Union framework project Femtoprint, was presented in June at CLEO 2013 in San Jose.

For more information, visit: www.southampton.ac.uk

Published: July 2013
Glossary
fused quartz
Crystal quartz that is melted at a white heat and cooled to form an amorphous glass. It is not birefringent and the refractive index is much lower than that of crystal quartz. Fused quartz of optical quality can be prepared by suitable techniques.
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
nanostructured glass
A unique glass made up of nano-structured materials to create millimeter sized monolithic glass space-variant polarization converters which ultimately alter the way light propagates through and is ultimately stored in glass. This store and read technique allows for more precise laser material processing, ultra-high resolution imaging, as well as optical manipulation of atom-sized objects.
360 TB data capacity5-D digital dataAmericasCaliforniaCLEO 2013Eindhoven University of TechnologyEuropeFemtoprintfused quartzJingyu Zhanglaser writingLasersMicroscopynanonanostructured glassOpticsOptoelectronics Research CentreORCPeter KazanskyResearch & Technologyultrafast lasersUniversity of Southampton

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