CN101847828B

CN101847828B - Vertically emitting quantum cascade laser structure

Info

Publication number: CN101847828B
Application number: CN2010101715111A
Authority: CN
Inventors: 郭万红; 刘俊岐; 陆全勇; 张伟; 江宇超; 李路; 王利军; 刘峰奇; 王占国
Original assignee: Institute of Semiconductors of CAS
Current assignee: Institute of Semiconductors of CAS
Priority date: 2010-05-07
Filing date: 2010-05-07
Publication date: 2012-03-28
Anticipated expiration: 2030-05-07
Also published as: CN101847828A

Abstract

The invention provides a vertical launching quantum cascade laser structure comprising a substrate and a metal grating layer, wherein a waveguide layer, an active layer and a contact layer sequentially grow on the substrate; and the metal grating layer is positioned on the contact layer and has a secondary Bragg period.

Description

Vertical launching quantum cascade laser structure

Technical field

The present invention relates to the semiconductor photoelectric device technical field, relate in particular to a kind of vertical launching quantum cascade laser structure.The unique distinction of this structure is, surface plasma-wave is guided in the two-grade grating distributed feed-back vertical launching quantum cascade laser, can realize high vertical coupled efficient, has simplified material growth and grating preparation technology simultaneously.

Background technology

Wavelength is that the QCL of 8 ~ 12 μ m has very wide application prospect in fields such as atmosphere environment supervision and infrared counteraction.Different with the multimode operation that the Fabry-Perot-type cavity QCL of routine is had with the limit emission; Vertical launching quantum cascade laser possesses the advantage of single mode operation and Vertical Launch simultaneously; In the application of reality, can realize the integrated and online detection of two dimension, therefore paid close attention to widely and study.

Current vertical launching quantum cascade laser mainly contains 2 D photon crystal distributed feed-back vertical launching quantum cascade laser and two-grade grating distributed feed-back vertical launching quantum cascade laser.Wherein, 2 D photon crystal distributed feed-back vertical launching quantum cascade laser requires its photonic crystal pattern to possess very high aspect ratio; Require its fill factor, curve factor or the ABSORPTION EDGE can precise design and control simultaneously; But making the photonic crystal pattern that satisfies these requirements, for present photoetching process, but is a very big challenge.And by contrast; Preparation technology is simple relatively for its grating of two-grade grating distributed feed-back vertical launching quantum cascade laser; Therefore become a focus of vertical launching quantum cascade laser research in the world, and obtained deep research in the middle of in the past 10 years.

Although the further investigation to two-grade grating distributed feed-back vertical launching quantum cascade laser has obtained more achievement, comprise that the room temperature pulse swashs the far-field divergence angle of penetrating with 0.4 degree, these research major parts all are based on traditional dielectric waveguide structure.Though dielectric waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser has lower optical loss, its very thick ducting layer makes the material growth very difficult, and it is very dark that its grating requires etching simultaneously, and this makes etching technics very complicated again.Grow and preparing grating technology so design a kind of material of can simplifying, the two-grade grating distributed feed-back vertical launching quantum cascade laser structure that can improve vertical coupled efficient simultaneously again is a problem demanding prompt solution, and this patent is exactly to invent for this reason.

Summary of the invention

The objective of the invention is to, a kind of surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser structure is provided.This structure adopts very thin contact layer to replace very thick ducting layer in the traditional sucrose waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser, has therefore simplified the material growth; Simultaneously only adopt metal grating just to realize very strong coupling, do not need the etching semiconductor layer, this has simplified etching technics.In addition, the employing of surface plasma waveguide makes the overlapping of laser light field and grating increase, and through optimizing the duty ratio of metal in the grating, has finally obtained very strong vertical coupled efficient simultaneously.

The present invention provides a kind of vertical launching quantum cascade laser structure, comprising:

One substrate, growth has ducting layer, active layer and contact layer successively on this substrate;

Metal grating layer, this metal grating layer be positioned at contact layer above, and this metal grating layer has secondary Bragg period.

Wherein said substrate is the InP substrate.

The material of wherein said ducting layer is InGaAs, and this ducting layer mixes for the n type, and doping content is 6 * 10 ¹⁶Cm ^-3, bed thickness is 0.55 μ m.

Wherein said active layer is made up of the InGaAs/InAlAs in 40 cycles, and the wavelength that this active layer is corresponding is 8-12 μ m.

The material of wherein said contact layer is InGaAs, and doping content is 1 * 10 ¹⁹Cm ^-3, bed thickness is 0.05 μ m.

The material of wherein said metal grating layer is a silver, and the thickness of this metal grating layer 14 is 0.25 μ m, and the duty ratio of metal is 0.55.

Wherein said metal grating layer is divided into 4 segment structures on contact layer.

Description of drawings

In order to further specify characteristic of the present invention and effect, below in conjunction with accompanying drawing and specific embodiment the present invention is done further explanation, wherein:

Fig. 1 is embodiments of the invention, and it is the waveguide of plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser and the schematic cross-section of two-grade grating structure.

Fig. 2 is for to press among the described embodiment of Fig. 1, and the coupling coefficient of plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser is along with the variation relation figure of metal grating duty ratio.

Fig. 3 is for to press among the described embodiment of Fig. 1, and the vertical coupled efficient of the plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser that different cavity is long is along with the variation relation figure of metal grating duty ratio.

Fig. 4 is for to press among the described embodiment of Fig. 1, and the gain for threshold value of the plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser that different cavity is long is along with the variation relation figure of metal grating duty ratio.

Embodiment

See also shown in the figure, the present invention provides a kind of vertical launching quantum cascade laser structure, comprising:

One substrate 10, growth has ducting layer 11, active layer 12 and contact layer 13 successively on this substrate 10; Described substrate 10 is the InP substrate; The material of described ducting layer 11 is InGaAs, and this ducting layer 11 mixes for the n type, and doping content is 6 * 10 ¹⁶Cm ^-3, bed thickness is 0.55 μ m; Described active layer 12 is made up of the InGaAs/InAlAs in 40 cycles, and the wavelength that this active layer is corresponding is 8-12 μ m; The material of described contact layer 13 is InGaAs, and doping content is 1 * 10 ¹⁹Cm ^-3, bed thickness is 0.05 μ m;

Metal grating layer 14, this metal grating layer 14 be positioned at contact layer 13 above, and this metal grating layer 14 has secondary Bragg period; The material of described metal grating layer 14 is a silver, and the thickness of this metal grating layer 14 is 0.25 μ m, and the duty ratio of metal is 0.55; Described metal grating layer 14 is divided into 4 segment structures on contact layer 13.

The advantage of this structure is: InGaAs contact layer 13 very thin thickness above (1) active layer 12; And in traditional dielectric waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser; Ducting layer above the active layer is very thick; Generally be approximately 3 μ m, by contrast, the present invention has simplified the material growth.(2) employing of plasma waveguide only makes that the etching two-grade grating just can be realized very strong coupling on metal level; And in traditional dielectric waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser; Etching is finished after the two-grade grating on metal level; Still need etching depth on the semiconductor layer below to be approximately the grating of 1 μ m, by contrast, the present invention has also simplified etching technics.(3) surface plasma-wave is guided into after the two-grade grating distributed feed-back vertical launching quantum cascade laser; Duty ratio through optimizing metal in the metal grating layer 14 is 0.55; The present invention has obtained 43% vertical coupled efficient; This with traditional dielectric waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser in about 20% vertical coupled efficient compare, be again a bigger improvement.

Below specify waveguiding structure and the two-grade grating structure Design foundation and the method for designing of the above-mentioned plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser that provides.

Two-grade grating distributed feed-back vertical launching quantum cascade laser utilize two-grade grating to the vertical diffraction of light and obtain Vertical Launch, the coupling coefficient of its grating has directly determined the performance of device.And the size of coupling coefficient depends primarily on two factors, i.e. the difference of the pattern effective refractive index at grating bottom and grating top and the overlapping degree of light field and grating.In the surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser, the waveguiding structure at place, grating bottom is owing to adopt air as cover layer, and its light field pattern belongs to the dielectric waveguide mould; Yet the waveguiding structure at place, grating top is owing to adopt argent as cover layer, and its light field pattern belongs to the surface plasma mould, and the difference of the mode refractive index between these two kinds of guided wave modes is very large.In addition, the introducing of surface plasma waveguide makes light field more near grating one side, thereby has caused bigger light field and the overlapping between grating.To sum up; In the surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser, pattern effective refractive index bigger between the waveguiding structure at grating bottom and place, top is poor, and bigger overlapping between grating and the light field; Caused very big coupling coefficient, as shown in Figure 2.

According to the coupled mode theory of the long structure in the theoretical and limited chamber of the Floquet-Bloch of unlimited chamber long periodicity structure, the duty ratio of metal influences the vertical coupled efficient and the gain for threshold value of surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser strongly in the metal grating layer 14.As shown in Figure 3, when duty ratio less (duty ratio is less than 0.3),, cause the overlapping between light field and grating less, so vertical coupled efficient is very little because metal ratio is less in the grating layer.When duty ratio big (duty ratio is greater than 0.7); Though bigger metal ratio has guaranteed bigger light field and the overlapping between grating in the grating layer; But the pattern effective refractive index difference of place, grating top and grating bottom this moment waveguiding structure is along with the formed perturbation intensity of grating cyclic variation is very little, and both cancel out each other and cause less vertical coupled efficient.Gain for threshold value for surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser; As shown in Figure 4, when duty ratio hour, gain for threshold value is bigger; It is less that this comes from the grating layer metal ratio, makes light field well not be limited in active area.In addition, when duty ratio is near 0.6 the change once more of gain for threshold value big, this is because the bigger cause of face coupling loss herein.To sum up, in order to obtain big vertical coupled efficient, keep relatively low gain for threshold value simultaneously, the duty ratio of metal is optimised for 0.55 in the metal grating layer.Under this duty ratio, the vertical coupled efficient of surface plasma waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser and gain for threshold value are respectively 43% and 12cm ^-1, and in traditional dielectric waveguide two-grade grating distributed feed-back vertical launching quantum cascade laser, corresponding value is respectively 17.5% and 20cm ^-1, this shows that the present invention has good effect.

Above-described specific embodiment; The object of the invention, technical scheme and beneficial effect have been carried out further explain, and institute it should be understood that the above is merely specific embodiment of the present invention; Be not limited to the present invention; All within spirit of the present invention and principle, any modification of being made, be equal to replacement, improvement etc., all should be included within protection scope of the present invention.

Claims

1. A vertical emission quantum cascade laser structure, comprising:

A substrate on which a waveguide layer, an active layer and a contact layer are grown sequentially;

a metal grating layer, the metal grating layer is located above the contact layer, and the metal grating layer has a second-order Bragg period;

The material of the contact layer is InGaAs, the doping concentration is 1×10 ¹⁹ cm ^-3 , and the layer thickness is 0.05 μm;

The material of the metal grating layer is silver, the thickness of the metal grating layer is 0.25 μm, and the duty ratio of the metal is 0.55.

2. The vertical emitting quantum cascade laser structure according to claim 1, wherein said substrate is an InP substrate.

3. The vertical emitting quantum cascade laser structure according to claim 1, wherein the material of the waveguide layer is InGaAs, the waveguide layer is n-type doped, the doping concentration is 6×10 ¹⁶ cm ^-3 , and the layer The thickness is 0.55 μm.

4. The vertical emitting quantum cascade laser structure according to claim 1, wherein said active layer is composed of 40 periods of InGaAs/InAlAs, and the corresponding wavelength of the active layer is 8-12 μm.

5. The vertical emission quantum cascade laser structure according to claim 1, wherein said metal grating layer is divided into four segments above the contact layer.