Surface-emission laser diode operable in the wavelength band of 1.1-1.7 um and optical telecommunication system using such a laser diode

Abstract

A surface-emission laser diode includes a distributed Bragg reflector tuned to a wavelength of 1.1 μm or longer, wherein the distributed Bragg reflector includes an alternate repetition of a low-refractive index layer and a high-refractive index layer, with a heterospike buffer layer having an intermediate refractive index interposed therebetween with a thickness in the range of 5-50 nm

Description

BACKGROUND OF THE INVENTION [0001] This invention generally relates to laser diodes and further to the art of optical telecommunication that uses a laser diode. Especially this invention is related to a so-called surface-emission laser diode that emits a laser beam in a generally vertical direction to a substrate surface. Also, the present invention is related to an optical transmission / reception system and optical-fiber telecommunication system that uses such a surface-emission laser diode. [0002] A surface-emission laser diode is a laser diode that emits a laser beam in a generally vertical direction from a surface of a substrate. By using surface-emission laser diodes, two-dimensional array integration of laser diode is achieved easily. Further, the laser diode has an advantageous feature of relatively narrow divergent angle of the output optical beam (about 10 degrees), which is particularly suitable for coupling with optical fibers. Furthermore, inspection of the laser diode de...

AI Technical Summary

Benefits of technology

[0029] Another and more specific object of the present invention is to provide a surface-emission laser diode or laser diode array having a distributed Bragg reflector tuned to a wavelength of 1.1 μm or longer wherein the electric resistance of the distributed Bragg reflector is minimized while maintaining high reflectance.

[0046] In constructing such a point-to-point optical transmission / reception system, the present invention avoids localized bending of the transmission path. As a result, the optical transmission / reception system connects two points easily and with low cost, without damaging the optical fiber.

Problems solved by technology

Thereby, there arises a problem in that the semiconductor multilayer part increases the resistance of the laser diode.

Because of this, conventional surface-emission laser diodes constructed on a GaAs substrate have suffered from the problem of comparatively high operating voltage of about 2.5 volts or more.

Because of this, it has been difficult to use the surface-emission laser diode with a CMOS driver integrated circuit, which produces a laser driving voltage of 2 volts at best.

In order to reduce the operational voltage below 2 V, it is necessary to reduce the device resistance by one-half, while it is extremely difficult to meet for this requirement at the present stage of technology.

Unfortunately, the desired low voltage operation is not materialized in such a long wavelength laser diode.

In such a system, the lattice constant of InP constituting the substrate is large, and it is difficult to achieve a large refractive-index difference in the reflector when a material that achieves lattice matching with the InP substrate is used for the reflector.

In such a construction, however, the resistance of the reflector increases again as a result of increased stacking number of the reflector.

Thus, it has been difficult to drive the laser diode driver by a CMOS integrated circuit.

In a surface-emission laser diode formed on an InP substrate, there is another problem of change of laser characteristic caused by the temperature.

However, the use of such a temperature regulator is difficult in the apparatus for home use, which is subjected to a severe demand of cost reduction.

Because of these problems of increased number of stacking in the reflector and the poor temperature characteristics, practical long-wavelength surface-emission laser diode has not yet commercialized.

However, the laser diode structure thus formed does not provide optical emission at all, or operates but only with low power, indicating that the efficiency of optical emission is extremely small.

In this case, too, the luminous efficacy of the laser diode is far from the level of practical use.

More specifically, it is thought that the use of a material containing Al easily invites formation of crystal defects originating from Al.

Thus, the stacking number in the reflector has to be increased, and the object of reducing the resistance of the surface-emission laser diode is not attained.

Thus, at present, the surface-emission laser diode operable at the long-wavelength of 1.1-1.7 μm does not exist, and because of this, it is not possible to construct a computer network or optical-fiber telecommunication system that uses such a laser diode.

As explained before, in a conventional surface-emission laser diode, it was also not possible to use a CMOS circuit for the laser diode driver, and it has been necessary to use an expensive special driver circuit.

Unfortunately, the surface-emission laser diode that can be used for this purpose and can be used with a low-cost CMOS driver integrated circuit, and oscillates at the long-wavelength band of 1.1-1.7 μm does not exist.

Meanwhile, in the abovementioned semiconductor Bragg reflector, in which semiconductor layers of different bandgaps are grown alternately, there arises the problem of spike formation in the band structure thereof at the hetero interface as a result of the band discontinuity.

Thus, there arises a problem in that the electric resistance becomes very high in the semiconductor multilayer part of the surface-emission laser diode.

As noted previously, it has been difficult to drive a laser diode having such a large driving voltage by the driver integrated circuit formed of a CMOS circuit (driving voltage is below 2 volts).

However, this is a very difficult subject.

However, the surface-emission laser diode that can be used for this purpose and can be used with a low-cost CMOS driver integrated circuit, and oscillates at the long-wavelength band of 1.1-1.7 μm does not exist yet.

However, the photodetection device that has sensitivity to the desired wavelength band of 1.1-1.7 μm is expensive as compared with the low cost Si photodetection device.

Thus, simple replacement of a conventional Si photodetection device with the photodetection device having the sensitivity to the wavelength of 1.1-1.7 μm causes an increase of cost of the whole optical-fiber telecommunication system.

In such a laser diode, deterioration of device characteristic may be caused as a result of the thermal stress caused by the difference of linear thermal expansion coefficient with regard to the mounting substrate.

This issue is related to the yield of the laser diode production process in the production of the module product that uses an array arrangement of the laser diode elements, there is an acute demand of establishing the production process in which the modules that function normally are utilized efficiently and the yield of production of the module is improved.

Summarizing above, there is no available long-wavelength surface-emission laser diode operable at the wavelength band of 1.1-1.7 μm and that there is no available optical transmission / reception system that uses such a laser diode.

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