AgO_x界面插入层对GZO电极LED器件性能的影响

采用磁控溅射的方法在p-GaN上制备了GZO透明导电薄膜,通过在p-GaN和GZO界面之间插入AgOx薄层来改善LED器件的接触性能。研究结果表明:氮气退火后,采用界面插入层的AgOx/GZO薄膜电阻率为5.8×10-4Ω.cm,在可见光的透过率超过80%。AgOx界面插入层有效地降低了GZO与p-GaN之间的接触势垒,表现出良好的欧姆接触特性,同时使LED器件的光电性能获得了显著的提高。在50 mA的注入电流下,相比于常规的GZO电极LED器件,AgOx/GZO电极LED器件的正向电压由9.68 V降至6.92 V,而发光强度提高了13.5%。     

ITO界面调制层对GZO电极LED器件性能的影响

采用磁控溅射制备GZO和具有ITO界面调控层的GZO(ITO/GZO)透明导电薄膜作为大功率LED的电流扩散层,对比研究界面调控层对LED器件性能的影响。研究结果表明,ITO/GZO薄膜的透过率在可见光区达80%以上,退火后的ITO/GZO薄膜有较低的电阻率(1.15×10^-3 Ω·cm)。ITO调控层的介入能够调制GZO表面粗糙度,有利于改善LED外量子效率,降低GZO/p-GaN界面的接触势垒,提高LED器件的光电性 能。通过ITO界面调控后,LED器件20 mA驱动电流下的工作电压从9.5 V降低为6.8 V,发光强度从245 mcd 升到297 mcd,提高了20%;驱动电流为35 mA时,其发光强度从340.5 mcd 升到511 mcd,提高了50%。     

牺牲Ni退火对硅衬底GaN基发光二极管p型接触影响的研究

本文通过在硅衬底发光二极管(LED)薄膜p-GaN表面蒸发不同厚度的Ni覆盖层,将其在N₂ ∶O₂=4 ∶1的气氛中、400℃—750℃的温度范围内进行退火,在去掉薄膜表面Ni覆盖层之后制备Pt/p-GaN欧姆接触层.实验结果表明:退火温度和Ni覆盖层厚度均对硅衬底GaN基LED薄膜p型欧姆接触有重要影响,Ni覆盖退火能够显著降低p型层中Mg受主的激活温度.经牺牲Ni退火后,p型比接触电阻率随退火温度的升高呈先变小后变大的规律,随Ni覆盖层厚度的增加呈先变小后变 关键词： 氮化镓 发光二极管 牺牲Ni退火 p型接触     

Ni插入层对Ag/p-GaN界面接触性能的影响机理

采用"牺牲Ni处理"的方法研究了Ni对Ag/p-GaN界面接触性能的影响机理。利用传输线法(TLM)、紫外分光光度计、X射线光电子能谱(XPS)以及二次离子质谱仪(SIMS)等表征方式对Ag/p-GaN界面层光电性能进行了研究。结果表明,牺牲Ni处理后p-GaN表面仍会残留少量的Ni并以Ni_2O_3的形式存在;p-GaN表面Ga 2p3结合能峰位朝低能方向移动了0.3 eV,提高了Ag/p-GaN间的欧姆接触性能。我们认为,界面处的Ni会优先和p-GaN表面Ga_2O_3氧化物中的O结合形成Ni_2O_3,进而降低了p-GaN表面费米能级,提高了Ag/p-GaN之间的欧姆接触性能。     

牺牲Ni退火对硅衬底GaN基发光二极管P型接触影响的研究术

本文通过在硅衬底发光二极管（LED）薄膜p-GaN表面蒸发不同厚度的Ni覆盖层,将其在N2：O2=4：1的气氛中、400℃-750℃的温度范围内进行退火,在去掉薄膜表面Nj覆盖层之后制备Pt／p-GaN欧姆接触层．实验结果表明：退火温度和Ni覆盖层厚度均对硅衬底GaN基LED薄膜P型欧姆接触有重要影响,Ni覆盖退火能够显著降低P型层中Mg受主的激活温度．经牺牲Ni退火后,P型比接触电阻率随退火温度的升高呈先变小后变大的规律,随Ni覆盖层厚度的增加呈先变小后变大随后又变小的趋势;经过优化后,当Ni覆盖层厚度为1．5nm,退火温度为450℃,Pt与p-GaN比接触电阻率在不需要二次退火的情况下达到6．1×10^-5Ω·cm。．     

AlGaN/GaN异质结Ni/Au肖特基表面处理及退火研究

采用O₂等离子体及HF溶液对AlGaN/GaN异质结材料进行表面处理后，Ni/Au肖特基接触特性比未处理有了明显改善，反向泄漏电流减小3个数量级.对制备的肖特基接触进行200—600℃ 5min的N₂气氛退火，发现退火冷却后肖特基反向泄漏电流随退火温度增大进一步减小.N₂气中600℃退火后肖特基二极管C-V特性曲线在不同频率下一致性变好，这表明退火中Ni向材料表面扩散减小了表面陷阱密度；C-V特性曲线随退火温度增大向右移动，从二维电子气耗尽电压绝对值减小反映了肖特基势垒的提高. 关键词： AlGaN/GaN 肖特基接触 表面处理 退火     

感应耦合等离子体刻蚀p-GaN的表面特性

研究了p-GaN材料经感应耦合等离子体(ICP)刻蚀后的表面特性,并用不同的方法对刻蚀表面进行处理.利用原子力显微镜(AFM)和X射线光电子能谱(XPS)对刻蚀样品进行分析,并在样品表面制作Ni/Au电极,进行欧姆接触特性的测试.实验结果表明了NaOH溶液处理表面对改善材料表面和欧姆接触特性是比较有效的. 关键词： GaN 感应耦合等离子刻蚀 表面处理 欧姆接触     

感应耦合等离子体刻蚀p-GaN的表面特性

研究了p-GaN材料经感应耦合等离子体(ICP)刻蚀后的表面特性，并用不同的方法对刻蚀表面进行处理.利用原子力显微镜(AFM)和X射线光电子能谱(XPS)对刻蚀样品进行分析，并在样品表面制作Ni/Au电极，进行欧姆接触特性的测试.实验结果表明了NaOH溶液处理表面对改善材料表面和欧姆接触特性是比较有效的.     

具有阻挡层的H等离子体处理增强型p-GaN栅AlGaN/GaN HEMT研究

采用H等离子体处理p-GaN盖帽层来制备p-GaN栅AlGaN/GaN高电子迁移率晶体管(HEMT).在p-Ga N层表面上先沉积2 nm的Al₂O₃薄膜,以减少H等离子体注入p-GaN时对表面造成的损伤.经研究表明沉积Al₂O₃阻挡层的器件栅极反向泄漏电流降低了一个数量级,开关比提高了约3倍.由于栅极泄露电流的减小,关态击穿电压从410 V提高到780 V.针对栅极反向泄漏减小的现象,进行了变温IG-VG测试,验证了栅极反向泄漏电流的主导机制是二维变程跳跃(Two-dimensional variable range hopping,2D-VRH)模型.分析了减小栅极反向电流的原因是由于Al₂O₃阻挡层改变了HR-Ga N的表面态,使陷阱能级的活化能升高.此外,器件动态特性也表现出更稳定的趋势,这是Al₂O₃薄膜阻挡过多的H等离子体的注入,使AlGaN势垒和沟道陷阱态数量减少,电流崩塌效应减弱.     

一种测量p-GaN载流子浓度的方法

提出了一种测量p-GaN载流子浓度的方法,其主要思想是利用p-n⁺结构GaN探测器长波和短波量子效率的差值随反向偏压的变化关系,找到p-GaN层刚好完全耗尽时的偏压,从而求出p-GaN层载流子浓度.模拟计算表明,该方法能够准确测量出p-GaN层的载流子浓度,而且受表面复合、欧姆接触影响很小.进一步研究了实际测量中如何选择p-GaN层厚度,计算结果表明,p-GaN层的优化厚度值随着p-GaN层的浓度增加而减小. 关键词： p-GaN 载流子浓度测量 紫外探测器     

氧气氛中p-GaN/Ni/Au电极在相同温度不同合金时间下的欧姆接触形成机制和扩散行为

用卢瑟福背散射/沟道技术研究了p-GaN上的Ni/Au电极在氧气氛下相同合金温度(500℃)不同合金时间后的微结构演化,以揭示欧姆接触的形成机制.利用背散射随机谱和RUMP模拟程序研究了电极金属之间的互扩散,用沟道谱探测了电极金属中的氧分布.结合不同合金时间下比接触电阻ρ_c的变化,发现随着合金时间的延长比接触电阻持续降低,在合金时间60 s后降低的速度减慢, Au扩散到GaN的表面,在p-GaN上形成外延结构,O向电极内部扩散反应生成NiO对降低ρ_{关键词： GaN 卢瑟福背散射/沟道 欧姆接触}     

Effects of hydrogen treatment on ohmic contacts to p-type GaN films

This study investigated the effects of hydrogen (H₂) treatment on metal contacts to Mg-doped p-GaN films by Hall-effect measurement, current-voltage (I-V) analyzer and X-ray photoemission spectra (XPS). The interfacial oxide layer on the p-GaN surface was found to be the main reason for causing the nonlinear I-V behavior of the untreated p-GaN films. The increased nitrogen vacancy (V_N) density due to increased GaN decomposition rate at high-temperature hydrogen treatment is believed to form high density surface states on the surface of p-GaN films. Compared to untreated p-GaN films, the surface Fermi level determined by the Ga 2p core-level peak on 1000 °C H₂-treated p-GaN films lies about ∼2.1 eV closer to the conduction band edge (i.e., the surface inverted to n-type behavior). The reduction in barrier height due to the high surface state density pinned the surface Fermi level close to the conduction band edge, and allowed the electrons to easily flow over the barrier from the metal into the p-GaN films. Thus, a good ohmic contact was achieved on the p-GaN films by the surface inversion method.     

Use of TiB2 diffusion barriers for Ni/Au ohmic contacts on p-GaN

The use of a TiB₂ diffusion barrier for Ni/Au contacts on p-GaN is reported. The annealing temperature (25-950 °C) dependence of ohmic contact characteristics using a Ni/Au/TiB₂/Ti/Au metallization scheme deposited by sputtering were investigated by contact resistance measurements and auger electron spectroscopy (AES). The as-deposited contacts are rectifying and transition to ohmic behavior for annealing at ≥500 °C . A minimum specific contact resistivity of ∼3 × 10⁻⁴ Ω cm⁻² was obtained after annealing over a broad range of temperatures (800-950 °C for 60 s). The contact morphology became considerably rougher at the higher end of this temperature range. AES profiling showed significant Ti and Ni outdiffusion through the TiB₂ at 800 °C. By 900 °C the Ti was almost completely removed to the surface, where it became oxidized. Use of the TiB₂ diffusion barrier produces superior thermal stability compared to the more common Ni/Au, whose morphology degrades significantly above 500 °C.     

Auger electron spectroscopy of Au/NiOx contacts on p-GaN annealed in N2 and O2 + N2 ambients

We have designed a promising contact scheme to p-GaN. Au/NiO_x layers with a low concentration of O in NiO_x are deposited on p-GaN by reactive dc magnetron sputtering and annealed in N₂ and in a mixture of O₂ + N₂ to produce low resistivity ohmic contacts. Annealing has been studied of NiO_x layers with various contents of oxygen upon the electrical properties of Au/NiO_x/p-GaN. It has been found that the Au/NiO_x/p-GaN structure with a low content of oxygen in NiO_x layer provides a low resistivity ohmic contact even after subsequent annealing in N₂ or O₂ + N₂ ambient at 500 °C for 2 min.Auger depth profiles and transmission electron microscopy (TEM) micrographs reveal that while annealing in O₂ + N₂ ambient results in reconstruction of the initial deposited Au/NiO_x/p-GaN contact structure into a Au/p-NiO/p-GaN structure, annealing in N₂ brings about reconstruction into Au/p-NiO/p-GaN and Ni/p-NiO/p-GaN structures. Hence, in both cases, after annealing in N₂ as well as in O₂ + N₂ ambient, the ohmic properties of the contacts are determined by creation of a thin oxide layer (p-NiO) on the metal/p-GaN interface. Higher contact resistivities in the samples annealed in O₂ + N₂ ambient are most likely caused by a smaller effective area of the contact due to creation of voids.     

ZnMgO/n-ZnO/ZnMgO/p-GaN异质结LED的紫外电致发光

利用等离子体辅助分子束外延( P-MBE)技术制备了ZnMgO/n-ZnO/ZnMgO/p-GaN异质结LED.Ni/Au电极与p-GaN、In电极与ZnMgO之间都形成了良好的欧姆接触.在ZnMgO/n-ZnO/ZnMgO/p-GaN异质结器件中观察到了明显的整流特性.异质结的电致发光强度随着注入电流的增大而逐渐增强...     

Contact mechanisms and design principles for alloyed Ohmic contacts to p-type GaN

Contact mechanisms and design principles of alloyed Ohmic contacts to p-type GaN (p-GaN) are studied. Illustrative studies include bilayer, trilayer and quadrilayer Ohmic contacts. Almost all contacts appear to follow the proposed design principles. The removal of the surface insulating layer, preferably by plasma etching, leads to metal/semiconductor barrier lowering. This, together with thermionic emission, plays a crucial role for yielding low-resistance metal/p-GaN contacts. Band-gap narrowing and/or image force lowering due to heavy doping also contribute to the low contact resistivity. A judicious choice of the layer thicknesses of appropriate metal combination, rapid thermal annealing (RTA) time, RTA temperature and RTA ambient can produce large-work-function alloy(s) in contact with the p-GaN epitaxial layer, creating a robust low-resistivity thermionic-emission-induced Ohmic contact. The fundamental physics of contact mechanisms and design principles proposed in the study is useful for making other contacts. These are general enough to be extended to other III–V nitride materials, at the least.     

Effect of graphene/ZnO hybrid transparent electrode on characteristics of GaN light-emitting diodes

In order to reduce the Schottky barrier height and sheet resistance between graphene(Gr) and the p-GaN layers in GaN-based light-emitting diodes(LEDs), conductive transparent thin films with large work function are required to be inserted between Gr and p-GaN layers. In the present work, three kinds of transparent conductive oxide(TCO) zinc oxide(ZnO) films, Al-, Ga-, and In-doped ZnO(AZO, GZO, and IZO), are introduced as a bridge layer between Gr and p-GaN,respectively. The influence of different combinations of Gr/ZnO hybrid transparent conducting layers(TCLs) on the optical and thermal characteristics of the GaN-LED was investigated by the finite element method through COMSOL software. It is found that both the TCL transmittance and the surface temperature of the LED chip reduce with the increase in Gr and ZnO thickness. In order to get the transmittance of the Gr/ZnO hybrid TCL higher than 80%, the appropriate combination of Gr/ZnO compound electrode should be a single layer of Gr with ZnO no thicker than 400 nm(1 L Gr/400-nm ZnO),2 L Gr/300-nm ZnO, 3 L Gr/200-nm ZnO, or 4 L Gr/100-nm ZnO. The LEDs with hybrid TCLs consisting of 1 L Gr/300-nm AZO, 2 L Gr/300-nm GZO, and 2 L Gr/300-nm IZO have good performance, among which the one with 1 L Gr/300-nm GZO has the best thermal property. Typically, the temperature of LEDs with 1 L Gr/300-nm GZO hybrid TCLs will drop by about 7 K compared with that of the LEDs with a TCL without ZnO film.