石墨烯上生长GaN纳米线的研究

在常压条件下采用化学气相淀积(CVD)技术在有石墨烯插入层的衬底上生长GaN纳米线,研究了生长温度、石墨烯插入层、催化剂等因素对GaN纳米线的形貌、光学特性以及结构的影响.通过扫描电子显微镜(SEM)、光致发光(PL)谱、拉曼(Raman)谱和透射电子显微镜(TEM)等表征手段对GaN纳米线的形貌、光学特性以及结构进行表征.结果表明,在1 100℃条件下,同时有石墨烯插层和催化剂的衬底表面能够获得低应力单晶GaN纳米线.石墨烯、催化剂对于获得低应力单晶GaN纳米线有重要的作用.     

利用高频Plasma CVD在蓝宝石衬底上生长 立方GaN缓冲层及其光学性质

研究了采用高频PlasmaCVD技术在较低温度下(300—400℃)生长以GaN为基的Ⅲ-Ⅴ族氮化物的可行性,在蓝宝石衬底上生长了GaN缓冲层.热处理后的光致发光谱和X光衍射表明,生长的GaN缓冲层为立方相,带边峰位于3.15eV.在作者实验的范围内,最优化的TMGa流量为0.08sccm(TMAm=10sccm时),XPS分析结果表明此时的Ga/N比为1.03.这是第一次在高Ⅴ/Ⅲ比下得到立方GaN.相同条件下石英玻璃衬底上得到的立方GaN薄膜,黄光峰很弱,晶体质量较好.     

氮化对蓝宝石衬底上AlGaN/GaN异质结材料性能的影响

研究了不同氮化条件对蓝宝石衬底上生长的AlGaN/GaN异质结材料特性的影响。研究表明,随着氮化过程NH3流量的增大,GaN外延层的晶体质量得到了改善,GaN内应力释放,但是AlGaN/GaN异质结构中二维电子气的迁移率有所恶化。讨论了上述现象出现的原因。     

氮化工艺对GaN缓冲层生长的影响

以氮等离子体为氮源,以三乙基镓（TEG）为镓源,在蓝宝石（Al2O3）衬底上生长GaN缓冲层。主要考察了氮化温度和氮气流量对缓冲层生长的影响。实验中采用了氢氮混合等离子体清洗的方法,提高了清洗的质量。用X射线衍射来表征晶体的结构,用原子力显微镜来表征表面形貌。通过对高能电子衍射仪获得的缓冲层与氮化层的衍射图样进行比较,对GaN的氮化实验参数进行了优化。     

氧化物缓冲层制备Si(111)基GaN纳米线

采用氧化物缓冲层,通过射频磁控溅射系统依次在n型Si(111)衬底上沉积Ga2O3/ZnO(Ga2O3/MgO)薄膜,然后将薄膜于950℃氨化合成GaN纳米结构,氨化时间为15min。采用X射线衍射(XRD)、傅里叶红外吸收谱(FTIR)和高分辨透射电镜(HRTEM)对样品的结构进行了分析,结果显示两种缓冲层下制备的样品均为六方纤锌矿单晶GaN纳米结构,且缓冲层的取向对纳米线的生长方向有很大影响;采用扫描电镜(SEM)对样品的形貌进行了测试,发现纳米线表面光滑,长度可达几十微米,表明采用氧化物缓冲层制备了高质量的GaN线。同时对GaN纳米线的生长机理进行了简单讨论。     

缓冲层材料对纤锌矿结构GaN(0001)光电发射性能的影响研究

利用金属有机物化学气相沉积技术在蓝宝石衬底上异质外延生长了GaN光电发射层,为降低GaN发射层和蓝宝石衬底间的晶格失配与热失配,在蓝宝石衬底和GaN发射层间分别采用了AlN和AlxGa1-xN两种不同的缓冲层材料。对具有不同缓冲层材料的两种样品进行了表面清洗与激活,在激活结束后利用多信息量测试系统分别测试了样品的光谱响应,其最大量子效率分别为13%和20%,依据激活后光电阴极的光谱响应作为评估标准,可以得出,采用组份渐变AlxGa1-xN作为缓冲层激活出的阴极具有更高的光电发射性能,从而实现了GaN光电阴极结构的优化设计。     

蓝宝石上高电子迁移率AlGaN/GaN材料的研究

通过优化蓝宝石衬底上GaN材料缓冲层和Mg掺杂生长工艺,获得了高质量的半绝缘GaN缓冲层,同时通过优化AlGaN/GaN异质结材料中AlN插入层的厚度,获得了性能优良的AlGaN/GaN HEMT材料.室温下2DEG载流子面密度为1.21×10013/cm2,迁移率为1970 cm2/V·s,77 K下2DEG迁移率达到13000 cm2/V·s.     

AlN缓冲层厚度对脉冲激光沉积技术生长的GaN薄膜性能的影响

在蓝宝石(Al2O3)衬底上应用脉冲激光沉积技术(PLD)生长不同厚度的AlN缓冲层后进行GaN薄膜外延生长。采用高分辨X射线衍射仪(HRXRD)和扫描电子显微镜(SEM)对外延生长所得GaN薄膜的晶体质量和表面形貌进行了表征。测试结果表明:相比直接在Al2O3衬底上生长的GaN薄膜,通过生长AlN缓冲层的GaN薄膜虽然晶体质量较差,但表面较平整;而且随着AlN缓冲层厚度的增加,GaN薄膜的晶体质量和表面平整度均逐渐提高。可见,AlN缓冲层厚度对在Al2O3衬底上外延生长GaN薄膜的晶体质量和表面形貌有着重要的影响。     

AlN缓冲层厚度对脉冲激光沉积技术生长的GaN薄膜性能的影响

在蓝宝石(Al2O3)衬底上应用脉冲激光沉积技术(PLD)生长不同厚度的AlN缓冲层后进行GaN薄膜外延生长。采用高分辨X射线衍射仪(HRXRD)和扫描电子显微镜(SEM)对外延生长所得GaN薄膜的晶体质量和表面形貌进行了表征。测试结果表明: 相比直接在Al2O3衬底上生长的GaN薄膜, 通过生长AlN缓冲层的GaN薄膜虽然晶体质量较差, 但表面较平整; 而且随着AlN缓冲层厚度的增加, GaN薄膜的晶体质量和表面平整度均逐渐提高。可见, AlN缓冲层厚度对在Al2O3衬底上外延生长GaN薄膜的晶体质量和表面形貌有着重要的影响。     

插入δAl/AlN缓冲层在Si(111)上生长GaN

采用MOCVD(metal organic chemical vapor deposition)生长方法,对比在AlN层上加入δAl/AlN缓冲层和不加入δAl/AlN缓冲层两种生长结构,在Si(111)衬底上生长GaN.实验结果表明,在加入δAl/AlN缓冲层后,GaN外延层的裂纹密度得到了有效的降低,晶体质量也得到了明显的提高.通过MOCVD生长方法,利用光学显微镜、XRD和Raman等分析测试手段,研究了δAl/AlN缓冲层对GaN外延层的影响,获得了裂纹密度小、晶体质量高的GaN材料.     

The effect of GaN and ain buffer layers on GaN film properties grown on both C-plane and A-plane sapphire

This paper presents a comparative study of the properties of GaN grown by organometallic vapor phase epitaxy, using both a GaN and A1N buffer layer, as a function of sapphire orientation (c-plane vs a-plane). Results are presented for varying the thickness of the buffer layer, varying the growth temperature of the GaN film, and also varying the ammonia/trimethylgallium mass flow ratio. The electron Hall mobilities of GaN films grown on an A1N buffer layer were, in general, higher compared to films grown using a GaN buffer layer. In addition, growth on a-plane sapphire resulted in higher quality films (over a wider range of buffer thicknesses) than growth on c-plane sapphire. The room temperature electron mobilities were also found to be dependent on, not only the growth temperature, but also the ammonia/trimethylgallium mass flow ratio.     

Investigations of GaN growth on the sapphire substrate by MOCVD method with different AlN buffer deposition temperatures

The effects of different AlN buffer deposition temperatures on the GaN material properties grown on sapphire substrate was investigated. At relatively higher AlN buffer growth temperature, the surface morphology of subsequent grown GaN layer was decorated with island-like structure and revealed the mixed-polarity characteristics. In addition, the density of screw TD and leakage current in the GaN film was also increased. The occurrence of mixed-polarity GaN material result could be from unintentional nitridation of the sapphire substrate by ammonia (NH₃) precursor at the beginning of the AlN buffer layer growth. By using two-step temperature growth process for the buffer layer, the unintentional nitridation could be effectively suppressed. The GaN film grown on this buffer layer exhibited a smooth surface, single polarity, high crystalline quality and high resistivity. AlGaN/GaN high electron-mobility transistor (HEMT) devices were also successfully fabricated by using the two-step AlN buffer layer.     

MOCVD生长中利用Al双原子层控制和转变 GaN的极性

讨论了采用MOCVD在Al2O3衬底上生长GaN过程中的极性问题,在氮化衬底上生长低温缓冲层前沉积一Al层来改变外延层的极性,并用CICISS来测量这一级性,最后给出了一种模型来解释这一极性的转变。     

Characterization of AlGaN/GaN structures on various substrates grown by radio frequency-plasma assisted molecular beam epitaxy

The structural properties and surface morphology of AlGaN/GaN structures grown on LiGaO₂ (LGO), sapphire, and hydride vapor phase epitaxy (HVPE)-grown GaN templates are compared. AlGaN grown on LGO substrates shows the narrowest x-ray full width at half maximum (FWHM) for both symmetric 〈00.4〉 and asymmetric 〈10.5〉 reflections. Atomic force microscopy (AFM) analysis on AlGaN surfaces on LGO substrates also show the smoothest morphology as determined by grain size and rms roughness. The small lattice mismatch of LGO to nitrides and easily achievable Ga-polarity of the grown films are the primary reasons for the smoother surface of AlGaN/GaN structure on this alternative substrate. Optimizations of growth conditions and substrate preparation results in step flow growth for an AlGaN/GaN structure with 300 Å thick Al_0.25Ga_0.75N on 2.4 μm thick GaN. A high III/V flux ratio during growth and recently improved polishing of LGO substrates aids in promoting two dimensional step flow growth. The GaN nucleation layer directly on the LGO substrate showed no evidence of mixed phase cubic and hexagonal structure that is typically observed in the nucleation buffer on sapphire substrates. Cross-sectional high-resolution transmission electron microscopy (HRTEM) was performed on an AlGaN/GaN heterostructure grown on LGO. The atomic arrangement at the AlGaN/GaN interface was sharp and regular, with locally observed monolayer and bilayer steps.     

Growth and characterization of ZnO nanowires on p-type GaN

ZnO nanowires were grown by catalyst-free metal-organic vapour-phase epitaxy on top of a p-type GaN buffer. The optical properties of the ZnO nanowires were investigated by temperature-dependent and time-resolved photoluminescence and compared to those of ZnO nanowires directly grown on sapphire. The luminescence intensity decrease with temperature of the nanowires grown on GaN reveals an original behavior since it is constant over 120 K, showing the existence of strong localization centers. In addition, the temperature-dependent decay time measurements indicate a lower density of non-radiative channels for the nanowires grown on GaN.     

Spontaneous growth of GaN nanowire nuclei on N- and Al-polar AlN: A piezoresponse force microscopy study of crystallographic polarity

The polarity of gallium nitride (GaN) nanowire nuclei grown on AlN layers was studied by piezoresponse force microscopy (PFM). N- or Al-polar AlN layers were grown by molecular beam epitaxy (MBE) on Si (111) substrates by use of Al- or N-rich growth conditions, respectively. Short and low density GaN nanowires were then grown on each AlN polarity type. PFM measurements verified the expected AlN layer polarity and further indicated that predominantly N-polar nanowires are produced for growth on both AlN polarity types. Cross-section scanning transmission electron microscopy (STEM) images further reveal that the nanowires on Al-polar AlN films are nucleated on regions in the AlN layer that contain inversion domains, which propagate into the GaN nanowire nuclei. PFM measurements were found to be a convenient technique for mapping the polarity of a statistically significant number of individual GaN nanowires.     

High-yield GaN nanowire synthesis and field-effect transistor fabrication

This letter describes a simple way to grow high-quality GaN nanowires in a specific area. The relationship between catalyst formation and nanowire growth was addressed. High-yield gallium nitride nanowire field-effect transistors were demonstrated successfully using a prealigned process: Ni catalysts with a diameter of 200 nm were deposited selectively at predetermined positions. GaN nanowires were then grown by vapor-liquid-solid mechanism in a chemical vapor deposition (CVD) reactor. Fabricated GaN nanowire FETs showed a high current density along with good saturation and pinch-off characteristics. These authors contributed equally to this work.     

Epitaxial growth of GaN layers on metallic TiN buffer layers

To improve GaN light-emitting diode light emission, we produced metal organic chemical vapor deposition (MOCVD)-grown, continuous, flat GaN layers on metallic TiN buffer layers deposited on sapphire substrates. Three important conditions were found: (a) the sapphire substrate surface plane should be (1120), (b) the TiN layer surface plane should be (111), and (c) the TiN buffer layer nitrogen content should be higher than that of stoichiometric TiN. Reduction of TiN layer thickness reduced TiN buffer layer surface roughness. Threading dislocation density in GaN layers grown on TiN buffer layers was much lower than that in GaN layers grown on AlN.