利用W形空穴阻挡层降低AlGaN基深紫外激光二极管的空穴泄露

本文设计了V形和W形的空穴阻挡层(HBL)结构,改善空穴在AlGaN基深紫外激光二极管(DUV-LD)n型区的泄露问题.使用Crosslight软件,将参考型矩形、V形和W形三种空穴阻挡层结构进行仿真研究,分别比较了三种不同结构的DUV-LD能带、n区空穴浓度、辐射复合率、电光转换效率、有源区载流子浓度等特性,结果表明,具有W形空穴阻挡层的DUV-LD拥有更高的空穴有效势垒高度、更高的辐射复合率、更低的空穴泄露以及更好的斜率效率,可以有效降低深紫外激光二极管在n型区的空穴泄露,提升其光学和电学性能.     

电子阻挡层Al组分对GaN基蓝光激光二极管光电性能的影响

采用SiLENSe（Simulator of light emitters based on nitride semiconductors）软件仿真研究了Al_xIn_yGa_1-x-yN电子阻挡层（EBL）Al组分渐变方式对GaN基激光二极管（LD）光电性能的影响,实现了提高输出功率和电光转换效率的目的。文中提出的四种Al组分渐变方式分别是传统均匀组分、右阶梯渐变组分（0～0.07～0.16）、三角形渐变组分（0～0.16～0）、左阶梯渐变组分（0.16～0.07～0）。结果表明,与传统均匀组分EBL结构相比,Al组分阶梯渐变Al_xIn_yGa_1-x-yN EBL LD导带底的电子势垒显著提高,价带顶的空穴势垒降低。这主要是由于该结构能有效抑制电子泄漏和提高空穴注入效率,从而提高有源区载流子浓度,进而提高有源区辐射复合效率。当注入电流为0.48 A时,采用Al组分阶梯渐变Al_xIn_yGa_1-x-y...     

利用倒梯矩形电子阻挡层降低深紫外激光二极管的电子泄露

为了有效降低深紫外激光二极管(DUV-LD)在有源区的电子泄露,提出了一种新颖的具有倒梯矩形的电子阻挡层(EBL)结构。通过使用Crosslight软件将矩形,梯矩形和倒梯矩形三种不同的结构进行仿真研究,比较三种结构器件的能带图、辐射复合率、电子空穴浓度、P-I以及V-I特性等,得出倒梯矩形EBL更能有效地抑制电子的泄露,从而改善了器件的光学和电学性能。     

AlxGa1-xN/GaN双量子阱的结构和掺杂浓度对子带间跃迁波长和吸收系数的影响

用薛定谔方程和泊松方程自洽计算的方法研究了Al_0.75Ga_0.25N/GaN对称双量子阱(DQWs)中子带间跃迁(ISBT)的波长和吸收系数对中间耦合势垒高度、中间耦合势垒宽度、势阱宽度和势垒掺杂浓度的依赖关系.研究发现,第一奇序子带S_1ood与第二偶序子带S_2even ISBT波长随着中间耦合势垒高度的降低而变短.当中间耦合势垒高度高于0.62 eV时,S_{1odd< 关键词： 自洽 x}Ga_1-xN/GaN双量子阱')" href="#">Al_xGa_1-xN/GaN双量子阱 子带间跃迁     

表面钝化前后Al0.22Ga0.78N/GaN异质结势垒层应变的高温特性

用高分辨X射线衍射仪(HRXRD)研究了表面钝化前后Al_0.22Ga_0.78N/ GaN异质结势垒层应变的高温特性，温度变化范围从室温到813K.结果表明，对未钝化的异质 结，当测试温度高于523K时，Al_0.22Ga_0.78N势垒层开始出现应变 弛豫；钝化后，在Al_0.22Ga_0.78N势垒层中会产生一个附加的平面 拉伸应变，并随着温度的增加，势垒层中的平面拉伸应变会呈现出一个初始的增加，接着应 变将减小，对100nm厚的Al_0.22Ga_0.78N势垒层，应变只是轻微地减 小，但对于50nm厚的Al_0.22Ga_0.78N势垒层，则出现了严重的应变 弛豫现象. 关键词： 0.22Ga_0.78N/GaN异质结')" href="#">Al_0.22Ga_0.78N/GaN异质结 应变 3 N₄钝化')" href="#">Si₃ N₄钝化 高温XRD     

氮化物抛物量子阱中类氢杂质态能量

采用变分方法研究氮化物抛物量子阱(GaN/Al_xGa_1-xN)材料中类氢杂质态的能级,给出基态能量、第一激发态能量、结合能和跃迁能量等物理量随抛物量子阱宽度变化的函数关系.研究结果表明,基态能量、第一激发态能量、基态结合能和1s→2p±跃迁能量随着阱宽L的增大而减小,最后接近于GaN中3D值.GaN/Al_0.3Ga_0.7N抛物量子阱对杂质态的束缚程度比GaAs/Al_0.3Ga_0.7As抛物量子阱强,因此,在GaN/Al_0.3-Ga_0.7N抛物量子阱中束缚于杂质中心处的电子比在GaAs/Al_0.3Ga_0.7As抛物量子阱中束缚于杂质中心处的电子稳定.     

利用倒双阶渐变阶梯形电子阻挡层减少深紫外激光二极管的电子泄露

本文提出了用双阶渐变阶梯和倒双阶渐变阶梯形电子阻挡层(EBL)以减少AlGaN基深紫外激光二极管(DUV-LDs)在p型区的电子泄露,并用Crosslight软件模拟仿真了双阶渐变阶梯和倒双阶渐变阶梯形EBL结构的光电特性,结果发现：具有倒双阶渐变阶梯形EBL的激光器拥有比双阶渐变阶梯形EBL激光器更高的斜率效率(SE),更高的输出功率,更低的阈值电流和阈值电压,更高的有效势垒高度和更低的电子泄露.这意味着前者拥有更强的抑制电子泄露的能力.在与矩形EBL结构对比中发现,所提出的结构还提高了有源区载流子浓度和辐射复合速率,进一步提高了DUV-LDs的光电性能.     

不规则H形量子势垒增强AlGaN基深紫外发光二极管性能

针对AlGaN基多量子阱中有效的平衡载流子注入问题,研究了有源区势垒层中Al组分调制形成的非规则H形量子势垒对AlGaN基深紫外发光二极管(LED)器件性能的影响及载流子的输运行为。研究发现,与多量子阱中常用的单Al组分势垒相比,加入Al组分较高的双尖峰势垒可以有效地提高内量子效率和光输出功率。进一步研究表明,电子在有源区因凸起的尖峰势垒而得到了有效的阻挡,减少了电子的泄露,而空穴获得更多的动能从而穿过较高的势垒进入有源区。因此,采用非对称H形量子势垒的深紫外LED器件中载流子输运实现了较好的平衡,量子阱中的载流子复合速率远高于普通的深紫外发光二极管。     

高效InGaN/AlInGaN发光二极管的结构设计及其理论研究

利用Advanced Physical Models of Semiconductor Devices (APSYS)理论对比研究了InGaN/AlInGaN 和 InGaN/GaN多量子阱作为有源层的InGaN基发光二极管的结构和电学特性。与InGaN/GaN 基LED 中GaN作为垒层材料相比,在AlInGaN材料体系中,通过调节AlInGaN中Al和In的组分可以优化器件的性能。当InGaN阱层材料中In组分为8%时,可以实现无应力的In_0.08Ga_0.92N/AlInGaN基 LED。在这种无应力结构中可以进一步降低大功率LED的"效率下降"(Effciency droop)问题。理论模拟结果显示,四元系AlInGaN作为垒层可以进一步减少载流子泄露,增加空穴注入效率,减少极化场对器件性能的影响。在In_0.08Ga_0.92N /AlInGaN量子阱中的载流子浓度、有源层的辐射复合率、电流特性曲线和内量子效率等方面都优于InGaN/GaN基LED。无应变AlInGaN垒层代替传统的GaN垒层后,能够得到高效的发光二极管,并且大电流注入下的"效率滚降"问题得到改善。     

p型GaN/Al0.35Ga0.65N/GaN应变量子阱中二维空穴气的研究

对Ga面p型GaN/Al_0.35Ga_0.65N/GaN应变异质结构中形成的二维空穴气(2DHG)进行了研究.首先基于半导体-绝缘体-半导体异质结构模型确定了应变异质中的临界厚度，然后自洽求解薛定谔方程和泊松方程，计算了当中间势垒层AlGaN处于完全应变状态和半应变状态两种条件下，顶层GaN及中间层AlGaN厚度的变化对2DHG分布的影响.计算结果表明，势垒层AlGaN和顶层GaN的应变状态和厚度对极化引起的2DHG面密度及分布有重要影响.在此基础上制备了p型GaN/Al_0.35Ga_0.65N/GaN应变量子阱结构肖特基器件，并通过器件的C-V测试证实了异质结处2DHG的存在.器件响应光谱的测试结果表明，由于p型GaN/Al_0.35Ga_0.65N/GaN量子阱中强烈的极化作用和Stark效应使得器件零偏压和反向偏压时的响应光谱都向短波方向移动了10 nm，在零偏压下器件在280 nm处的峰值响应为0.022 A/W，在反向偏压为1 V时，峰值响应达到0.19 A/W，已经接近理论值. 关键词： AlGaN 二维空穴气 极化效应     

Performance improvement of blue InGaN light-emitting diodes with a specially designed n-AlGaN hole blocking layer

Blue InGaN light-emitting diodes (LEDs) with a conventional electron blocking layer (EBL), a common n-AlGaN hole blocking layer (HBL), and an n-AlGaN HBL with gradual Al composition are investigated numerically, which involves analyses of the carrier concentration in the active region, energy band diagram, electrostatic field, and internal quantum efficiency (IQE). The results indicate that LEDs with an n-AlGaN HBL with gradual Al composition exhibit better hole injection efficiency, lower electron leakage, and a smaller electrostatic field in the active region than LEDs with a conventional p-AlGaN EBL or a common n-AlGaN HBL. Meanwhile, the efficiency droop is alleviated when an n-AlGaN HBL with gradual Al composition is used.     

Improvement of radiative recombination rate in deep ultraviolet laser diodes with step-like quantum barrier and aluminum-content graded electron blocking layer

The design of the active region structures, including the modifications of structures of the quantum barrier(QB) and electron blocking layer(EBL), in the deep ultraviolet(DUV) Al Ga N laser diode(LD) is investigated numerically with the Crosslight software. The analyses focus on electron and hole injection efficiency, electron leakage, hole diffusion,and radiative recombination rate. Compared with the reference QB structure, the step-like QB structure provides high radiative recombination and maximum output power. Subsequently, a comparative study is conducted on the performance characteristics with four different EBLs. For the EBL with different Al mole fraction layers, the higher Al-content Al Ga N EBL layer is located closely to the active region, leading the electron current leakage to lower, the carrier injection efficiency to increase, and the radiative recombination rate to improve.     

Suppression of electron and hole overflow in GaN-based near-ultraviolet laser diodes

In order to suppress the electron leakage to p-type region of near-ultraviolet GaN/In_xGa_(1-x )N/GaN multiple-quantumwell(MQW) laser diode(LD), the Al composition of inserted p-type AlxGa_(1-x)N electron blocking layer(EBL) is optimized in an effective way, but which could only partially enhance the performance of LD. Here, due to the relatively shallow GaN/In_(0.04)Ga_(0.96)N/GaN quantum well, the hole leakage to n-type region is considered in the ultraviolet LD. To reduce the hole leakage, a 10-nm n-type Al_xGa_(1-x)N hole blocking layer(HBL) is inserted between n-type waveguide and the first quantum barrier, and the effect of Al composition of Al_xGa_(1-x)N HBL on LD performance is studied. Numerical simulations by the LASTIP reveal that when an appropriate Al composition of Al_xGa_(1-x)N HBL is chosen, both electron leakage and hole leakage can be reduced dramatically, leading to a lower threshold current and higher output power of LD.     

Effectiveness of inserting an In Ga N interlayer to improve the performances of In Ga N-based blue-violet laser diodes

Electron leakage still needs to be solved for In Ga N-based blue-violet laser diodes(LDs), despite the presence of the electron blocking layer(EBL). To reduce further electron leakage, a new structure of In Ga N-based LDs with an In Ga N interlayer between the EBL and p-type waveguide layer is designed. The optical and electrical characteristics of these LDs are simulated, and it is found that the adjusted energy band profile in the new structure can improve carrier injection and enhance the effective energy barrier against electron leakage when the In composition of the In Ga N interlayer is properly chosen. As a result, the device performances of the LDs are improved.     

Improvement of the carrier distribution with GaN/InGa N/AlGaN/InGaN/GaN composition-graded barrier for InGaN-based blue light-emitting diode

In Ga N light-emitting diodes(LEDs) with Ga N/In Ga N/Al Ga N/In Ga N/Ga N composition-graded barriers are proposed to replace the sixth and the middle five Ga N barriers under the condition of removing the electron blocking layer(EBL)and studied numerically in this paper. Simulation results show that the specially designed barrier in the sixth barrier is able to modulate the distributions of the holes and electrons in quantum well which is adjacent to the specially designed barrier. Concretely speaking, the new barrier could enhance both the electron and hole concentration remarkably in the previous well and reduce the hole concentration for the latter one to some extent along the growth direction. What is more,a phenomenon, i.e., a better carrier distribution in all the wells, just appears with the adoption of the new barriers in the middle five barriers, resulting in a much higher light output power and a lower efficiency droop than those in a conventional LED structure.     

Enhanced performance of AlGaN-based ultraviolet light-emitting diodes with linearly graded AlGaN inserting layer in electron blocking layer

The conventional stationary Al content Al GaN electron blocking layer(EBL) in ultraviolet light-emitting diode(UV LED) is optimized by employing a linearly graded Al Ga N inserting layer which is 2.0 nm Al_(0.3) Ga_(0.7) N/5.0 nm Alx Ga_(1-x) N/8.0 nm Al_(0.3) Ga_(0.7) N with decreasing value of x. The results indicate that the internal quantum efficiency is significantly improved and the efficiency droop is mitigated by using the proposed structure. These improvements are attributed to the increase of the effective barrier height for electrons and the reduction of the effective barrier height for holes,which result in an increased hole injection efficiency and a decreased electron leakage into the p-type region. In addition,the linearly graded AlGaN inserting layer can generate more holes in EBL due to the polarization-induced hole doping and a tunneling effect probably occurs to enhance the hole transportation to the active regions, which will be beneficial to the radiative recombination.     

Numerical study of performance characteristics of deep violet InGaN DQW laser diodes with AlInGaN quaternary multi quantum barrier electron blocking layer

The performance characteristics of deep violet In_0.082Ga_0.918N/GaN double quantum well (DQW) laser diodes (LDs) with different electron blocking layer (EBL) including a ternary AlGaN bulk EBL, a quaternary AlInGaN bulk EBL and ternary AlGaN multi quantum barrier (MQB) EBL has been numerically investigated. Inspired by the abovementioned structures, a new LD structure with a quaternary AlInGaN MQB EBL has been proposed to improve the performance characteristics of the deep violet InGaN DQW LDs. Simulation results indicated that the LD structure with the quaternary AlInGaN MQB EBL present the highest output power, slope efficiency and differential quantum efficiency (DQE) and lowest threshold current compared with the above mentioned structures. They also indicated that choosing an appropriate aluminum (Al) and indium (In) composition in the quaternary AlInGaN MQB layers could control both piezoelectric and spontaneous polarizations. It will decrease the electron overflow from the active region to p-side and increased the contribution of electron and hole carriers to the radiative recombination effectively. Enhancing radiative recombination in the well using the quaternary AlInGaN MQB EBL also increased the optical output power and optical intensity.     

Improved performance of near UV light-emitting diodes with a composition-graded p-AlGaN irregular sawtooth electron-blocking layer

We investigate the performances of the near-ultraviolet(about 350 nm-360 nm) light-emitting diodes(LEDs) each with specifically designed irregular sawtooth electron blocking layer(EBL) by using the APSYS simulation program.The internal quantum efficiencies(IQEs),light output powers,carrier concentrations in the quantum wells,energy-band diagrams,and electrostatic fields are analyzed carefully.The results indicate that the LEDs with composition-graded pAl_xGa_(1-x)N irregular sawtooth EBLs have better performances than their counterparts with stationary component p-AlGaN EBLs.The improvements can be attributed to the improved polarization field in EBL and active region as well as the alleviation of band bending in the EBL/p-AlGaN interface,which results in less electron leakage and better hole injection efficiency,thus reducing efficiency droop and enhancing the radiative recombination rate.