KR100264775B1 - Semiconductor laser - Google Patents

Abstract

PURPOSE: A semiconductor laser is provided to be capable of reducing a light loss owing to reflection by using a ring-type grating different from a conventional grating. CONSTITUTION: A semiconductor laser emits a laser beam through grating that is formed on an active layer region(11). The grating(14) has a ring shape so that the laser beam(15) is emitted only in one direction. The laser beam is generated in a ring-shaped cavity and a grating period is designed so that only laser beams for satisfying an incident angle(theta) of 60° to 90° obtains a gain. The laser beam(15) penetrated toward the exterior of the cavity hardly passes the ring-type grating(14).

Description

Semiconductor laser

1 is a schematic diagram of a conventional semiconductor laser,

2 is a schematic diagram of a semiconductor laser of the present invention.

* Explanation of symbols for main parts of the drawings

1,11: active layer region 2,12: internal transmission beam

3,13: internal reflection beam 4: first grating

14 ring grating 5,15 laser beam

6: 2nd grating 16: Flat tip part of grating

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor laser, and more particularly, by introducing a ring mechanism into a distributed bragg reflector (DBR) type semiconductor laser so that the beam reflected from its grating comes out in only one direction. The present invention relates to a semiconductor laser capable of improving light output.

Currently, semiconductor lasers using DBR-type ring oscillators have emerged in an effort to obtain a light output of 1W or more while maintaining a single transverse mode and a single longitudinal mode.

FIG. 1 is a schematic view of a conventional semiconductor laser. In the conventional gain-guided laser structure, FIG. 1 shows two pairs of perpendicular grating regions 4 and 6 in the active layer region 1. By forming a special oscillator cavity, so that the beam 3 reflected therein is subjected to Bragg reflection so that the laser only has a wavelength that matches the gain peak of the active layer region 1. It was prepared to release the.

However, in the structure having two pairs of grating regions perpendicular to each other as described above, since the internal transmission beam 2 to be the laser beam 5 passes through the second grating 6 region, loss due to reflection occurs. In addition, since it is radiated to both mirror surfaces in a direction substantially parallel to the first grating portion 4, there is a problem that the actual effective light output is reduced to less than half of the total output.

It is therefore an object of the present invention to provide a semiconductor laser which not only solves the above problems but also considerably improves the performance compared to the conventional one.

In order to achieve the above object, the semiconductor laser of the present invention consists of forming a grating in a ring shape so that the laser beam is emitted only in one direction in the semiconductor laser emitting the laser beam by the grating formed on the active layer region.

Hereinafter, the configuration and effects of the present invention will be described in more detail with reference to the accompanying drawings.

According to the above, a semiconductor laser using a DBR-type ring oscillator was developed to obtain a light output of 1 W or more while maintaining a single transverse mode and a single longitudinal mode.

FIG. 1 shows a conventional semiconductor laser. As described above, the semiconductor laser has a reflection beam that satisfies two pairs of gratings 4 and 6 and Bragg reflection conditions in an oscillator cavity (inner region of the grating). Internally transmitted beams 2 running substantially parallel to the laser beam 5 by ring oscillation complementary to two pairs of gratings 4 and 6 where (2, 3) are perpendicular to each other And the remaining internal reflection beam 3, wherein the internal transmission beam 2 becomes the laser beam 5, but the internal reflection beam 3 is continuously reflected on the inner boundary surface and remains in the cavity.

In addition, since the internal transmission beam 2, which becomes the laser beam 5, passes through the second grating 6 region, there is a loss due to reflection and is radiated to both mirror surfaces, so that the effective light output is less than half of the actual total output. It will be nothing.

The present inventors have developed a ring-shaped grating different from the existing grating in view of this point.

2 shows a semiconductor laser of the present invention, and has a structure in which a grating 14 having a ring shape is formed on the active layer region 1. Here, the flat tip 16 of the ring grating 14 forms an acute angle of about 40 ° or less with an axis perpendicular to the mirror surface.

On the other hand, the ring grating 14 is configured in such a form that the cycle satisfies the following equation.

mλ = 2n _eff d cosθ

Where n _eff is the effective refractive index of the region containing the grating,

d is the grating period,

θ is the angle of incidence of the beam,

λ is the wavelength of the beam,

m is an integer

In the above equation, the incident angle λ of the beam is in the range of 60 ° to 30 °, and has a grating period d that satisfies this.

As shown in FIG. 2, in the semiconductor laser of the present invention, the beam generated in the ring-shaped cavity reflects with the grating 14 to be reflected as shown in the figure, wherein the grating period is determined by the incident angle θ of the beam at 60 °. Since only the beams satisfying 90 to 90 ° are designed to gain, the laser beam 15 that is actually transmitted out of the cavity is emitted almost immediately after the ring-shaped grating 14 and is emitted out of the mirror surface, so that light loss due to reflection is almost disappeared. It can be seen that the effective light output is much increased because the laser beam is emitted only in one direction.

Therefore, the semiconductor laser of the present invention can reduce the optical loss due to reflection by using a ring-type grating different from the conventional grating, and has an advantage of increasing the effective light output even more.

Claims (3)

A semiconductor laser which emits a laser beam by grating formed on the active layer region (11), characterized in that the grating (14) is formed in a ring shape so that the laser beam (15) is emitted only in one direction. The semiconductor laser according to claim 1, wherein the period of the ring grating (14) satisfies the following equation. mλ = 2n _eff d cosθ Where n _eff: effective refractive index of the region including grating d: grating period θ: beam incident angle λ: beam wavelength m: integer The semiconductor laser according to claim 1, wherein the tip portion (16) of the grating (14) forms an angle in the range of about 0 to 40 degrees with an axis perpendicular to the mirror surface.