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MQW (multiple quantum well)-growth applied GaN (gallium nitride)-based green-light LED (light emitting diode) epitaxial structure

An epitaxial structure and green light technology, which is applied in the field of GaN-based green LED growth technology, can solve the problems of reduced radiation recombination efficiency, poor lattice quality, low growth temperature, etc., and achieve effective radiation recombination improvement, increased performance, and separation Phenomena mitigation effect

Inactive Publication Date: 2013-06-26
YANGZHOU ZHONGKE SEMICON LIGHTING
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

This means that a lower growth temperature is required during the growth of the green well, which will lead to poorer lattice quality and degrade its performance; during the growth of the green well, the well and the barrier have a larger The lattice difference, which will lead to more serious lattice mismatch, more serious polarization effect, more serious space separation phenomenon of electron-hole wave function
Therefore, compared with blue LEDs, the radiation recombination efficiency of green LEDs will decrease.

Method used

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  • MQW (multiple quantum well)-growth applied GaN (gallium nitride)-based green-light LED (light emitting diode) epitaxial structure
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Embodiment Construction

[0013] figure 1 Among them, 1 is the sapphire substrate, 2 is the GaN nucleation layer, 3 is the non-doped GaN layer, 4 is the n-type GaN layer, 5a is the GaN barrier layer, 5b is the buffer layer shallow well, 5c is the InGaN quantum well layer, 5d is a temperature-varying GaN transition layer, and 6 is a p-type GaN layer.

[0014] From figure 1 It can be seen that a GaN nucleation layer 2, an undoped GaN layer 3, an n-type GaN layer 4, a GaN barrier layer 5a, a buffer layer shallow well 5b with a low In composition, and an InGaN quantum well layer 5c are grown sequentially on the substrate 1 , a temperature-swapping GaN transition layer 5d and a p-type GaN layer 6 .

[0015] Among them, the low In composition refers to: in the InGaN material, the mass of In contained is 1%~10%.

[0016] From figure 2 Among them, the curve of the LED (SQW LED) with a buffer layer shallow well with a low In composition is the simulated electric field distribution in the LED quantum well w...

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Abstract

The invention discloses an MQW (multiple quantum well)-growth applied GaN (gallium nitride)-based green-light LED (light emitting diode) epitaxial structure, and relates to the technical field of LED epitaxial production, in particular to growth technology of GaN-based green-light LEDs. The MQW-growth applied GaN-based green-light LED epitaxial structure comprises a GaN nucleating layer, a non-mixed GaN layer, a n-type GaN layer, an InGaN (indium gallium nitride) / GaN MQW active layer and a p-type GaN layer which are sequentially grown on a substrate. The InGaN / GaN MQW active layer comprises a GaN barrier layer, an InGaN quantum well layer and a temperature-changing GaN transition layer. A buffering layer shallow well with low In components is grown between the GaN barrier layer and the InGaN quantum well layer of the InGaN / GaN MQW active layer. Stress between a quantum well and a barrier is greatly reduced, and stress difference between the quantum well and the barrier is relieved, so that a polarization electric field in the quantum well is greatly reduced. By the buffering layer shallow well between the barrier and the quantum well, the polarization electric field is reduced, spatial segregation of an electron-hole wave function is relieved, and effective radiative recombination can be improved.

Description

technical field [0001] The invention relates to the technical field of LED epitaxial production, in particular to the growth technology of GaN-based green LEDs. Background technique [0002] Green LEDs have quietly emerged in the market, with a wide range of applications, including large indoor and outdoor billboards, traffic lights, backlight (computer, mobile phone display), portable lighting systems, fixed color lighting systems, optical access systems, etc. . The market share of products related to green light is also expanding year by year, and the market has higher and higher requirements for the performance of green light LEDs. How to obtain green LEDs with high brightness and high antistatic ability has become a hot research topic now. One of the most important criteria to measure its overall performance is the external quantum efficiency (EQE) of LEDs. External quantum efficiency is the ratio of the number of photons emitted to the outside per unit time to the nu...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01L33/12H01L33/06
Inventor 李盼盼李鸿渐李志聪孙一军王国宏
Owner YANGZHOU ZHONGKE SEMICON LIGHTING
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