In recent years, due to technology such as the Internet and 8K broadcasting, more and more information has been distributed across the world. Along this trend, there is a demand for an innovative storage method for storing large volumes of data at ultra-high recording density and at ultra-high speed. Magnetic-holographic memory meets this demand. This new technology enables more than 1 TB worth of data (equivalent to the total capacity of 40 Blu-ray discs, each with a typical capacity of 25 GB) to be recorded in a disc the size of a DVD or Blu-ray disc.
In magnetic hologram recording, a medium is magnetized in one direction; then the medium is irradiated with an information-bearing beam (signal beam) and a reference beam; and the resulting interference pattern is recorded in the form of the difference in magnetization directions. When this recording proceeds with an external magnetic field applied to it, the recording of the difference in magnetization directions becomes clearer. The latter process is called magnetic assist recording.
The research group led by Yuichi Nakamura, Associate professor at Toyohashi University of Technology, has applied this magnetic assist recording technology to magnetic-holographic memory and, for the first time in the world, succeeded in reducing recording energy consumption and achieving non-error data reconstruction.
Through simulation, the group investigated the size of the stray magnetic field required for magnetization reversal in magnetic hologram recording. As a result, they found that the thinner the medium, the smaller the necessary stray magnetic field and the less clear the hologram recording. They also proved through experiments that magnetic assist recording yields a clear magnetic hologram even with a thin medium, and the magnetic hologram yields a bright reconstruction beam upon irradiation with a reference beam. Through further experiments, they found that magnetic assist recording and reconstruction of two-dimensional data yields clear reconstruction images. As a result of this research, the group have enabled for the first time in the world a significant reduction in errors in data recording and reconstruction with a small amount of energy as well as non-error recording and reconstruction with magnetic-holographic memory.
"Until now it has been difficult to obtain a clear reconstruction image with a magnetic hologram, due to strict requirements for material characteristics, optical conditions, and so on. Using magnetic assist recording, we have relaxed these requirements and also improved the reconstruction performance of recording media. This technology is promising for the future application of magnetic-holographic memory," says first author Shirakashi.
They intend to proceed with their work to improve recording density, and their goal is to apply this technology to make a portable, ultra-high-density, high-speed optical information storage medium (outperforming Blu-ray discs) capable of storing high-volume contents from various sources including 8K Super Hi-Vision broadcasting and 3D films; and to enable wide application of this technology in various types of storage systems, including archive and cold storage for storing information such as medical image data, SNS data on the Internet, and high-volume data in data centers.
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Funding agency: This work was supported in part by Grants-in-Aid for Scientific Research (S) 26220902 and (A) 15H02240.
Reference:
Zen Shirakashi, Taichi Goto, Hiroyuki Takagi, Yuichi Nakamura, Pang Boey Lim, Hironaga Uchida & Mitsuteru Inoue, "Reconstruction of non-error magnetic hologram data by magnetic assist recording" Scientific Reports,7, Article number: 12835 (2017) doi:10.1038/s41598-017-12442-z
Further information:
Toyohashi University of Technology
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Toyohashi University of Technology, which was founded in 1976 as a National University of Japan, is a leading research institute in the fields of mechanical engineering, advanced electronics, information sciences, life sciences, and architecture. Website: http://www.tut.ac.jp/english/
Journal
Scientific Reports