Sony Works With University To Create New Blu-ray Laser

Right from the start, Sony has been one of Blu-ray's largest fans, and also one of the company's pouring the most money into marketing the format. Many people assumed that Blu-ray was a format created by Sony at first, but it's actually not. Nevertheless, Sony is now helping to advance Blu-ray into the next level, teaming with Tohoku University in order to develop a blue-violet laser with a 100W output. This may not sound too important on the surface, but it holds a lot of promise. What kind of promise? According to reports, this invention could lead to 1TB optical discs.


That's a fair bit larger than the 50GB Blu-ray Discs that we have today, and while there have already been plans made for a 128GB optical disc, being able to archive a full terabyte onto a single disc would be revolutionary. The team has jointly developed a laser which has a peak output that's 100x that of the world's highest current levels, and while it's rather difficult for the layperson to understand, this new one is capable of using a nonlinear optical process known as two-photon absorption, which occurs only as a result of high intensity optical pulses.

There's been no public announcement made about when this laser will actually lead to new products, but we're guessing they wouldn't be working on this if it weren't in the pipeline.

Tohoku University and Sony Corporation jointly develop the world’s first blue-violet ultrafast pulsed semiconductor laser with 100 watt output

The path to practical light-source in next-generation large-capacity optical disc storage & for nano-fabrication...

Professor Hiroyuki Yokoyama of the New Industry Creation Hatchery Center (NICHe), Tohoku University (hereafter, 'Tohoku University'), and Advanced Materials Laboratories, Sony Corporation (hereafter, 'Sony'), have succeeded in jointly developing a blue-violet ultrafast pulsed semiconductor laser*2 with dramatically improved peak laser beam output levels that are 100 times that of the world's current highest levels.


    * Beam emitted by the blue-violet ultrafast pulsed semiconductor laser.
      (Image above: arrow indicates the semiconductor optical amplifier)
    * The newly-developed blue-violet semiconductor laser (right)
      The newly-developed semiconductor optical amplifier (left)

This latest successful development is an all-semiconductor laser picosecond pulse source with a laser wavelength of 405 nanometers (1 nm = one-billionth of a meter) in the blue-violet region. It is capable of generating optical pulses in the ultrafast duration of 3 picoseconds (1 picosecond = one-trillionth of a second), with ultrahigh output peak power of 100 watts and repetition frequency of 1 gigahertz. Advanced control of the newly-developed and proprietarily-constructed GaN-based mode-locked semiconductor laser*3 and semiconductor optical amplifier*4 have enabled peak output power in excess of 100 watts to be achieved, which is more than a hundred times the world’s highest output value for conventional blue-violet pulse semiconductor lasers.


Although there have been ultra high-output laser devices combining solid-state lasers*5 and a second harmonic generation unit for high functionality and high-value leading-edge chemical research applications in the past, the light source box itself was bulky and a specialist technician was required to ensure the stable operation of the laser. There are high expectations that this newly-developed semiconductor laser system, which incorporates semiconductor diodes, can have a much wider range of future applications. For instance, this technology enables the size of components such as the light source box to be drastically reduced.

This newly-developed ultra high-output, ultrafast pulsed semiconductor laser light source is capable of using a nonlinear optical process known as two-photon absorption*6, which occurs only as a result of high intensity optical pulses. When light from the laser beam is concentrated on the lens, it creates chemical and thermal changes in the vicinity of the lens focus spot which is narrower than even the diameter of the focus spot of the lens itself. It is anticipated that application of these properties will be possible in a wide range of fields such as three-dimensional (3D) nano-fabrication of inorganic/organic materials in the order of nanometers, and next-generation large-capacity optical disc storage.

Sony tested the principles for applying this technology in next-generation large-capacity optical disc-storage by creating void marks with a diameter of approximately 300 nanometers at intervals of 3 micrometers on the interior of plastic material, and successfully read these marks with the laser beam.

These experimental results have been achieved through integration of Tohoku University’s fundamental technology on ultrashort pulse lasers (Tohoku University is promoting joint research program for industry-academic collaboration based on materials and devices), and Sony’s fundamental technology on semiconductor laser diodes. Hereafter, Tohoku University and Sony will work to further develop its fundamental technology for creating even higher output and multi-functionality, while developing the practical applications of this technology to make these systems even more compact and stable.

These research findings were also published in the latest edition of the US academic journal, 'Applied Physics Letters'. (Appl. Phys. Lett. volume 97, issue 2, page 021101 (2010); doi:10.1063/1.3462942 (3 pages), Online Publication Date: 12 July 2010 )

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