HOMESite MapContact Us
Global NetworkProductsCorporateInvestor RelationsR & DCSR

Press Release 2008

Home > Press Release > 2009 > July 16

Sumitomo Electric Develops The World’s First Pure Green Semiconductor Laser

- A Newly Developed Gallium Nitride Crystal Leads To The Achievement -

July 16, 2009
Sumitomo Electric Industries, Ltd.

Sumitomo Electric Industries, Ltd. has successfully developed the world’s first green laser diode lasing at 531 nm.

Light sources using lasers for display applications, such as laser TV’s and pocket laser projectors, are expected to have superior properties in terms of size, weight and power consumption. For this reason, R&D activities aimed at commercialization of these devices have expanded rapidly over the past several years. Up to now, only red and blue laser diodes were commercially available, while green lasers (*1) were obtained by frequency conversion of infrared lasers. Gallium nitride (GaN) semiconductors, commercially available for blue LEDs, are also expected to be the key material for light-emitting devices in the green region. However, the material has been plagued with a phenomenon where the luminance efficiency shows a rapid decline with increasing wavelength.


At Sumitomo Electric, we have overcome this problem by developing a GaN crystal which inhibits the efficiency drop, resulting in room temperature pulse operation of a laser diode emitting in the pure-green region at 531nm. It is the first green laser diode in the world.


Some of the features of our green laser diode are as follows.


High quality crystal emitting in the green region

The luminous efficiency of GaN light-emitting devices is known to show a sharp decline with increasing wavelength (*2). This is a combined result of the internal field effects as well as the deterioration of the crystal quality of the active layer. Several organizations are studying to alleviate this problem by changing the crystal orientation.
At Sumitomo Electric, we have developed a crystal which weakens the internal field effects and also improves the quality of the active layer. This has lead to the successful development of the world’s first green laser diode.


Tunability of the wavelength in the green region

With a proper design of the active layer, we have succeeded in covering the entire range of the lasing spectrum in the green region. While the lasing wavelengths of the conventional frequency-converted lasers are locked at a specific wavelength, our device can be tuned to any wavelength in the green region. Furthermore, the lasing spectrum remains virtually unshifted even in the high current range, and therefore, we believe our device has advantages in high power applications.
Another advantage of our green laser diode is that the dependence of wavelength at ambient temperature is minimal.

We have applied for over 60 patents related to this technology. Details of the device will be presented in the July 17th edition of the Applied Physics Express.
The successful development of the green laser diode leads to the red-green-blue (RGB) laser light sources and should lead to new applications. We will continue to seek new business opportunities utilizing our nitride semiconductor technology.

[Support documentation]
Photo 1. Green laser emitting from an oscillator below right

Photo 1. Green laser emitting from an oscillator below right


※1 Green laser
A laser operates in the green region of the optical spectrum. Until now, green lasers based on semiconductors materials, such as blue or red lasers, did not exist. Commercial green lasers, such as those used in laser pointers, emit green light at the wavelength of 532nm by down converting a 1064nm infrared laser light. The needs for large number of mechanical parts resulting in high costs, along with their inherent low efficiencies, have prevented widespread commercialization of these devices.


※2 Sharp efficiency decline with increasing wavelength
The main reason for the low luminous efficiency of green light-emitting devices based on GaN materials is an electric field, commonly known as “the piezoelectric field.” Piezoelectric polarization caused by a large distortion in the crystal structure is the origin of this field. The piezoelectric field, while it has less effect on blue lasers, has a serious influence upon green lasers.



(C) 2014 Sumitomo Electric Industries, Ltd.
Using This SitePrivacy Policy