5D optical data storage is a nanostructured glass for permanently recording digital data using femtosecond laser writing process. The memory crystal is capable of storing up to worth of data for billions of years. The concept was experimentally demonstrated in 2013. Since 2018 the technology is in production use by the Arch Mission Foundation. Its first and second discs were given to Elon Musk: one disc is in his personal library, and the other was placed aboard the Tesla Roadster in space. Hitachi and Microsoft have researched and developed 5D optical storage techniques.
Technical design
The concept is the bulk storing of data optically in non-photosensitive transparent materials such as fused quartz, which is renowned for its high chemical stability and resistance. Writing into it using a femtosecond-laser was first proposed and demonstrated in 1996. The storage media consists of fused quartz where the spatial dimensions, intensity, polarization, and wavelength is used to modulate data. By introducing gold or silver nanoparticles embedded in the material, their plasmonic properties can be exploited. Up to 18 layers have been tested using optimized parameters with a light pulse energy of, a duration of 600 fs, and a repetition rate of 500 kHz. Assuming a 100% efficient laser, that is of energy consumption for a maximum 0.5 Mbits of data storage. For 1000 Mbits of storage that adds up to. Testing the durability using accelerated aging measurements shows that the decay time of the nanogratings is 3×1020±1 years at room temperature—. At an elevated temperature of, the extrapolated decay time is comparable to the age of the Universe. By recording data with a numerical apertureobjective of 1.4 NA and a wavelength of, a capacity of 360 terabytes can be achieved. The format has a novel method of storing data called "5-dimensional". This is more for marketing purposes since the device has 3 physical dimensions and no exotic higher dimensional properties. The fractal/holographic nature of its data storage is also purely 3-dimensional. According to the University of Southampton: It can be read with a combination of an optical microscope and a polarizer. The technique was first demonstrated in 2010 by Kazuyuki Hirao's laboratory at the Kyoto University. Further, the technology was developed by Peter Kazansky's research group at the Optoelectronics Research Centre, University of Southampton.