KR101918602B1 - Infrared Light Emitting Diode And Infrared Gas Sensor - Google Patents

Abstract

An infrared light emitting diode device according to an embodiment of the present invention includes an n ⁺ -conductive GaSb substrate; An n ⁺ -conductive GaSb buffer layer disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer; An n-conductive InGaAsSb second quantum well layer having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer; The AlGaAsSb A p-conductive AlGaAsSb upper cladding layer disposed on the third barrier layer; And a p-conductive GaSb contact layer disposed on the AlGaAsSb upper cladding layer.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an infrared light emitting diode (LED)

The present invention relates to an infrared light emitting diode that emits a plurality of wavelengths, and more particularly to an infrared light emitting diode that oscillates at a plurality of wavelengths using a multilayered quantum well layer stacked on a GaSb substrate.

Gas sensors are classified into optical and contact type according to the detection method of gas. In general, the optical type is a method of measuring the light absorption rate with respect to the concentration of the gas molecules by using the characteristic that the gas molecules absorb light of a specific wavelength. The optical gas sensor has a disadvantage that it is very expensive, while maintaining high measurement reliability for a long period of time with very little change over time. The non-dispersive infrared (NDIR) method of the optical gas sensor is used to replace the medium-wavelength infrared LED with the medium-wavelength infrared laser diode A low-cost, high-performance gas sensor can be manufactured.

The existing commercialized NDIR sensor consists of one LED light source and one infrared detector (photodiode). The two-channel NDIR sensor consists of two LED light sources and one infrared detector. The 2-channel NDIR sensor has the advantage that it can measure more stable than 1 channel and the calibration period is longer than 1 channel.

Disclosure of Invention Technical Problem [8] The present invention provides a two-channel non-dispersion infrared (IR) type infrared gas sensor using one LED light source oscillating at a plurality of wavelengths.

An object of the present invention is to provide an infrared light emitting diode oscillating at a plurality of wavelengths by changing the thickness of a quantum well layer of a multi-layered structure stacked on a GaSb substrate.

An infrared light emitting diode device according to an embodiment of the present invention includes an n ⁺ -conductive GaSb substrate; An n ⁺ -conductive GaSb buffer layer disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer; An n-conductive InGaAsSb second quantum well layer having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer; The AlGaAsSb A p-conductive AlGaAsSb upper cladding layer disposed on the third barrier layer; And a p-conductive GaSb contact layer disposed on the AlGaAsSb upper cladding layer. And oscillates at a plurality of wavelengths.

In one embodiment of the present invention, the composition ratio of the AlGaAsSb lower cladding layer is Al _0.9 Ga _0.1 As _0.08 Sb _0.92 , The composition ratio of the barrier layer is Al _0.35 Ga _0.65 As _0.03 Sb _0.97, and the composition ratio of the AlGaAsSb second The composition ratio of the barrier layer is Al _0.35 Ga _0.65 As _0.03 Sb _0.97, and the composition ratio of the AlGaAsSb third The composition ratio of the barrier layer is Al _0.35 Ga _0.65 As _0.03 Sb _0.97 , the composition ratio of the InGaAsSb first quantum well layer is In _0.35 Ga _0.65 As _0.15 Sb _0.85 , and the composition ratio of the InGaAsSb second quantum well layer is In _0.35 Ga _0.65 As _0.15 Sb _0.85 , and the composition ratio of the AlGaAsSb upper cruding layer may be Al _0.9 Ga _0.1 As _0.08 Sb _0.92 .

In one embodiment of the present invention, the first thickness of the InGaAsSb first quantum well layer may be between 5 nm and 9 nm, and the second thickness of the InGaAsSb second quantum well layer may be between 10 nm and 15 nm.

In one embodiment of the present invention, the lower electrode pattern may further include a lower electrode pattern disposed under the GaSb substrate. Wherein the lower electrode pattern comprises: an Ni pattern in contact with the GaSb substrate; A Ge pattern disposed under the nickel pattern; And an Au pattern disposed under the Ge pattern.

In one embodiment of the present invention, an upper electrode pattern may be further disposed on the GaSb contact layer. The upper electrode pattern includes a Ti pattern in contact with the GaSb contact layer; A Pt pattern disposed on the Ti pattern; And an Au pattern disposed on the Pt pattern.

An infrared gas sensor according to an embodiment of the present invention includes: a light cavity having a passage through which gas can flow; An infrared light emitting diode element disposed at one end of the optical cavity and oscillating at a plurality of wavelengths; A plurality of light receiving elements disposed at the other end of the optical cavity to receive attenuated light; And a plurality of wavelength selective transmission filters disposed at the front ends of the light receiving elements, respectively, for transmitting light emitted from the infrared LED elements. The infrared light emitting diode device includes an n ⁺ -conductive GaSb substrate; An n ⁺ -conductive GaSb buffer layer disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer; An n-conductive InGaAsSb second quantum well layer having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer; The AlGaAsSb Claim the AlGa _A sSb of p- conductivity type disposed on the third barrier layer is greater an upper spreading layer; And the AlGa _A sSb GaSb contact layer of the p- conductivity type disposed on an upper large spreading layer; comprises a.

An infrared gas sensor according to an embodiment of the present invention includes: a light cavity having a passage through which gas can flow; An infrared light emitting diode element disposed at one end of the optical cavity and oscillating at a plurality of wavelengths; A light receiving element disposed at the other end of the optical cavity and receiving the attenuated light; And a plurality of wavelength selective transmission filters disposed at the front end of the light receiving element and transmitting the respective light emitting wavelengths of the infrared light emitting diode elements. The wavelength selective transmission filter is aligned with the light receiving element by rotation. The infrared light emitting diode device includes an n ⁺ -conductive GaSb substrate; An n ⁺ -conductive GaSb buffer layer disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer; An n-conductive InGaAsSb second quantum well layer having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer; The AlGaAsSb Claim the AlGa _A sSb of p- conductivity type disposed on the third barrier layer is greater an upper spreading layer; And the AlGa _A sSb GaSb contact layer of the p- conductivity type disposed on an upper large spreading layer; comprises a.

One embodiment of the infrared light emitting diode of the present invention can stack the multilayer structure by changing the thickness and composition of the quantum well layer and oscillate at a plurality of wavelengths.

1 is a cross-sectional view of an infrared light emitting diode according to an embodiment of the present invention.
2 is a result of measurement of the emission spectrum of the infrared light-emitting diode device of FIG.
3 and 4 are conceptual diagrams illustrating an infrared gas sensor according to another embodiment of the present invention.

 If two light emitting wavelengths are simultaneously emitted from one LED instead of two LEDs required for a two-channel NDIR sensor, the infrared gas sensor can be competitive in size or production cost. The infrared gas sensor is capable of providing real-time continuous monitoring of the gas concentration without time delay since it is simultaneously oscillated at a plurality of wavelengths.

 Infrared LEDs applied to conventional NDIR gas sensors are mainly based on antimony (Sb) based materials such as liquid phase epitaxy (LPE) or metalorganic vapor phase epitaxy (MOCVD) come. The LPE method has a disadvantage in that it is difficult to control a thin thickness such as a quantum well (QW) at a high growth rate, and in particular, the characteristics of the p-n junction interface are poor.

The epitaxial layer using the MOCVD method shows good characteristics in the 3 μm to 5 μm wavelength band using the InAs substrate. However, the epitaxial layer using the molecular beam epitaxy (MBE) method exhibits better bonding interface characteristics in the case of the 2 μm to 3 μm wavelength band using the GaSb substrate. As high quality GaSb and InAs substrate fabrication technologies and MBE and MOCVD thin film growth technologies have developed rapidly, high quality antimony (Sb) based compound semiconductor stacking structures have become possible.

According to one embodiment of the present invention, we fabricated an Sb-based quaternary compound infrared LED device using MBE growth method and confirmed the luminescence characteristics. We fabricated a device with two emission wavelengths in a device that could be used for a 2-channel NDIR gas sensor.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in different forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the concept of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

Like reference numerals refer to like elements throughout the specification. Accordingly, although the same reference numerals or similar reference numerals are not mentioned or described in the drawings, they may be described with reference to other drawings. Further, even if the reference numerals are not shown, they can be described with reference to other drawings.

1 is a cross-sectional view of an infrared light emitting diode according to an embodiment of the present invention.

1, an infrared light emitting diode device 100 includes an n ⁺ -conductive GaSb substrate 110; An n ⁺ -conductive GaSb buffer layer 120 disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer 130 disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer 142; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer 144 disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer 146; An n-conductive InGaAsSb second quantum well layer (148) having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer 149; The AlGaAsSb A p-conductive AlGaAsSb upper cladding layer 150 disposed on the third barrier layer; And the AlGa sSb GaSb _A contact layer 160 of p- conductivity type disposed on the upper larger spreading layer; comprises a. The infrared light emitting diode device 100 oscillates at a plurality of wavelengths.

the n-type conductivity type impurity is Te, and the p-type conductivity type impurity is Be. n ⁺ At a high concentration Lt; 18 > / cm < ³ > or more. For high-quality LED epitaxial growth, each layer has a lattice match structure with the GaSb substrate having the same lattice constant. If the thicknesses of the quantum well layers 144 and 148 are 5 and 10 nm, respectively, the quantum well layers 144 and 148 may emit light of different wavelengths.

The GaSb substrate 110 has a high concentration n ⁺ , and is an n-type conductive type. The thickness of the GaSb substrate is 500 mu m.

The GaSb buffer layer 120 is disposed on the GaSb substrate 110 and has a high concentration of n ⁺ Doped and n-type conductivity. The thickness of the GaSb buffer layer 120 is 300 nm. The GaSb buffer layer 120 is grown through a molecular beam epitaxy growth method.

The AlGaAsSb lower cladding layer 130 is disposed on the GaSb buffer layer 120, and the high concentration n ⁺ Doped and n-type conductivity. The thickness of the AlGaAsSb lower cladding layer 130 is 2 탆. The composition ratio of the AlGaAsSb lower cladding layer 130 is Al _0.9 Ga _0.1 As _0.08 Sb _0.92 . The AlGaAsSb lower cladding layer 130 is grown through a molecular beam epitaxy growth method. The AlGaAsSb lower cladding layer 130 can confine the light generated in the quantum well layer with a refractive index difference. The AlGaAsSb lower cladding layer 130 is grown through a molecular beam epitaxy growth method.

The AlGaAsSb A first barrier layer 142 is disposed on the AlGaAsSb lower cladding layer 130, and an n-type impurity Doped and n-type conductivity. The AlGaAsSb The doping concentration of the first barrier layer 142 is about 10 17 / cm ³ . The AlGaAsSb first The composition ratio of the barrier layer 142 is Al _0.35 Ga _0.65 As _0.03 Sb _0.97 , and the composition ratio of the AlGaAsSb The thickness of the first barrier layer may be 200 nm. The AlGaAsSb The first barrier layer 142 is grown through molecular beam epitaxy growth. The AlGaAsSb The band gap of the first barrier layer 142 may be larger than the band gap of the quantum well layer.

The InGaAsSb first quantum well layer 144 is formed of AlGaAsSb Is disposed in the first barrier layer 142, and the n- Doped and n-type conductivity. The composition ratio of the InGaAsSb first quantum well layer 144 may be In _0.35 Ga _0.65 As _0.15 Sb _0.85 and the thickness of the InGaAsSb first quantum well layer 144 may be 5 nm. The InGaAsSb first quantum well layer 144 is grown through a molecular beam epitaxy growth method.

The AlGaAsSb A second barrier layer 146 is disposed on the InGaAsSb first quantum well layer 144, Doped and n-type conductivity. The AlGaAsSb second The composition ratio of the barrier layer 146 is Al _0.35 Ga _0.65 As _0.03 Sb _0.97 , and the composition ratio of the AlGaAsSb second The thickness of the barrier layer 146 is 200 nm. The AlGaAsSb The second barrier layer 146 is grown through molecular beam epitaxy growth.

The InGaAsSb second quantum well layer 148 is formed of AlGaAsSb Is disposed on the second barrier layer 146, and the n- Doped and n-type conductivity. The composition ratio of the InGaAsSb second quantum well layer 148 is In _0.35 Ga _0.65 As _0.15 Sb _0.85 and the thickness of the InGaAsSb second quantum well layer 148 is 10 nm. The InGaAsSb second quantum well layer 148 is grown through a molecular beam epitaxy growth method.

The AlGaAsSb A third barrier layer 149 is disposed on the InGaAsSb second quantum well layer 148, and an n-type impurity Doped and n-type conductivity. The AlGaAsSb third The composition ratio of the barrier layer 149 is Al _0.35 Ga _0.65 As _0.03 Sb _0.97 , and the AlGaAsSb third layer The thickness of the barrier layer 149 is 200 nm. The AlGaAsSb The third barrier layer 149 is grown through molecular beam epitaxy growth.

The AlGaAsSb upper cladding layer 150 is formed of AlGaAsSb Is disposed on the third barrier layer (149), and is highly doped with p-type impurity Doped and p-type conductivity. The composition ratio of the AlGaAsSb upper cladding layer 150 is Al _0.9 Ga _0.1 As _0.08 Sb _0.92 , and the thickness of the AlGaAsSb upper cladding layer 150 is 2 μm. The AlGaAsSb upper cladding layer 150 is grown through molecular beam epitaxy.

The GaSb contact layer 160 is disposed on the AlGaAsSb upper cladding layer 150 and has a high concentration of p-type impurity Doped and p-type conductivity. The thickness of the GaSb contact layer 160 is 500 nm. And the GaSb contact layer is grown through a molecular beam epitaxial growth method.

According to one embodiment of the present invention, the Sb-based quaternary compound layer can design the lattice matching structure with the GaSb substrate 110 through the compositional change of each material, and the thickness and composition change of the InGaAsSb quantum well layers 144 and 148 The emission wavelength can be adjusted in the range of 1 μm to 3 μm. Further, by increasing the number of periods of the quantum well layer, the light output can also be improved.

The lower electrode pattern 180 may be disposed under the GaSb substrate 110. The lower electrode pattern 180 includes an Ni pattern 186 of 5 nm in contact with the GaSb substrate; A 17 nm Ge pattern 184 disposed under the nickel pattern; And a 500 nm Au pattern 182 disposed under the Ge pattern. After the patterning is completed, the lower electrode pattern may be formed by ohmic contact through a heat treatment of 300 degrees Celsius.

The upper electrode pattern 170 may be disposed on the GaSb contact layer 160. The upper electrode pattern 170 includes a Ti pattern 172 of 30 nm in contact with the GaSb contact layer; A 40 nm Pt pattern 174 disposed on the Ti pattern; And a 300 nm Au pattern 176 disposed on the Pt pattern. After patterning is completed, the upper electrode pattern 170 may be formed by ohmic contact through a heat treatment of 300 degrees Celsius.

2 is a result of measurement of the emission spectrum of the infrared light-emitting diode device of FIG.

Referring to FIG. 2, two emission spectra are shown in a device of 1.97 and 2.1 .mu.m emitted from each quantum well layer by the measured emission spectrum. A 10 nm InGaAsSb second quantum well layer generates a wavelength of 2.1 μm and a 5 nm InGaAsSb first quantum well layer generates a wavelength of 1.97 μm. The full width at half maximum of the wavelength of 1.97 mu m is 69 nm and the half width of the wavelength of 2.1 mu m is 66 nm.

 Sb-based quaternary compounds can be designed with a GaSb substrate and lattice matching structure by changing the composition of each material, and the emission wavelength can be controlled in the range of 1 μm to 3 μm by changing the thickness and composition of the InGaAsSb quantum well layer. Further, by increasing the number of periods of the quantum well layer, the light output can also be improved.

3 is a conceptual diagram illustrating an infrared gas sensor according to another embodiment of the present invention.

Referring to FIG. 3, the infrared gas sensor 10 includes a light cavity 20 having a passage 21 through which gas can flow; An infrared light emitting diode device (100) disposed at one end of the optical cavity and oscillating at a plurality of wavelengths; A light receiving element (22) disposed at the other end of the optical cavity (20) and receiving the attenuated light; And a plurality of wavelength selective transmission filters (24a, 24b) disposed at the front end of the light receiving element (22) and transmitting the respective light emitting wavelengths of the infrared light emitting diode elements. The wavelength selective transmission filters 24a and 24 align with the light receiving element 22 by rotation.

The infrared light emitting diode device 100 includes an n ⁺ -conductive GaSb substrate 110; An n ⁺ -conductive GaSb buffer layer 120 disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer 130 disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer 142; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer 144 disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer 146; An n-conductive InGaAsSb second quantum well layer (148) having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer 149; The AlGaAsSb A p-conductive AlGaAsSb upper cladding layer 150 disposed on the third barrier layer; And a p-conductive GaSb contact layer 160 disposed on the AlGaAsSb upper cladding layer.

In the infrared gas detection sensor, when the gas to be detected is methane, a strong absorption spectrum is observed at 2.3 μm. The first and second quantum well layers of the light emitting diode simultaneously emit 1.9 and 2.3 μm. At this time, 1.9 μm emission is used as a reference LED and 2.3 μm emission is used as a measurement LED.

4 is a conceptual diagram illustrating an infrared gas sensor according to another embodiment of the present invention.

Referring to Fig. 4, the infrared gas sensor 10a includes a light cavity 20 having a passage 21 through which gas can flow; An infrared light emitting diode device (100) disposed at one end of the optical cavity and oscillating at a plurality of wavelengths; A plurality of light receiving elements (22a, 22b) arranged at the other end of the optical cavity for receiving attenuated light; And a plurality of wavelength selective transmission filters (24a, 24b) disposed at the front ends of the light receiving elements (22a, 22b) and transmitting the respective light emitting wavelengths of the infrared light emitting diode elements. The infrared light emitting diode device 100 includes an n ⁺ -conductive GaSb substrate 110; An n ⁺ -conductive GaSb buffer layer 120 disposed on the GaSb substrate; An n-conductive AlGaAsSb lower cladding layer 130 disposed on the GaSb buffer layer; An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer 142; And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer 144 disposed on the first barrier layer; An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer 146; An n-conductive InGaAsSb second quantum well layer (148) having a second thickness and disposed on the second barrier layer; An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer 149; The AlGaAsSb A p-conductive AlGaAsSb upper cladding layer 150 disposed on the third barrier layer; And a p-conductive GaSb contact layer 160 disposed on the AlGaAsSb upper cladding layer.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative and non-restrictive in every respect.

110: GaSb substrate
120: GaSb buffer layer
130: AlGaAsSb lower cladding layer
142: AlGaAsSb The first barrier layer
144: InGaAsSb first quantum well layer
146: AlGaAsSb The second barrier layer
148: InGaAsSb second quantum well layer
149: AlGaAsSb The third barrier layer
150: AlGaAsSb upper cladding layer
160: GaSb contact layer

Claims (7)

delete delete delete delete delete A light cavity having a passage through which gas can flow;
An infrared light emitting diode element disposed at one end of the optical cavity and oscillating at a plurality of wavelengths simultaneously;
A plurality of light receiving elements disposed at the other end of the optical cavity to receive attenuated light; And
And a plurality of wavelength selective transmission filters arranged at the front ends of the light receiving elements and each transmitting the light emission wavelength of the infrared light emitting diode elements,
Wherein the infrared light emitting diode element comprises:
an n ⁺ -conductive GaSb substrate;
An n ⁺ -conductive GaSb buffer layer disposed on the GaSb substrate;
An n-conductive AlGaAsSb lower cladding layer disposed on the GaSb buffer layer;
An n-conductive AlGaAsSb disposed on the AlGaAsSb lower cladding layer A first barrier layer;
And a second thickness of the AlGaAsSb An n-conductive InGaAsSb first quantum well layer disposed on the first barrier layer;
An n-conductive AlGaAsSb disposed on the first quantum well layer A second barrier layer;
An n-conductive InGaAsSb second quantum well layer having a second thickness and disposed on the second barrier layer;
An n-conductive AlGaAsSb disposed on the InGaAsSb second quantum well layer A third barrier layer;
The AlGaAsSb Claim the AlGa _A sSb of p- conductivity type disposed on the third barrier layer is greater an upper spreading layer; And
Includes,; the AlGa _A sSb upper size of the p- conductivity type contact layer disposed on the GaSb layer Redding
Wherein the n-conductive InGaAsSb first quantum well layer and the n-conductive InGaAsSb second quantum well layer have different thicknesses and the same composition,
Wherein the infrared light-emitting diode element emits light at a plurality of wavelengths simultaneously,
Wherein the infrared light emitting diode element oscillates at two wavelengths, the wavelength interval between the two wavelengths is at least twice the full width half maximum of each wavelength,
The first thickness of the InGaAsSb first quantum well layer is 5 nm to 9 nm,
The second thickness of the InGaAsSb second quantum well layer is 10 nm to 15 nm,
And an upper electrode pattern disposed on the GaSb contact layer,
Wherein the upper electrode pattern comprises:
A Ti pattern in contact with the GaSb contact layer;
A Pt pattern disposed on the Ti pattern; And
And an Au pattern disposed on the Pt pattern,
And a lower electrode pattern disposed under the GaSb substrate,
Wherein the lower electrode pattern comprises:
An Ni pattern in contact with the GaSb substrate;
A Ge pattern disposed under the Ni pattern; And
And an Au pattern disposed under the Ge pattern,
Wherein the upper electrode pattern is ohmic-bonded to the GaSb contact layer,
Wherein the lower electrode pattern is ohmic-bonded to the GaSb substrate. delete

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