直流磁控溅射制备AlN薄膜的结构和表面粗糙度

采用直流磁控反应溅射法,在Si(111)基底上成功制备了多晶六方相AlN薄膜.研究了溅射过程中溅射气压对薄膜结构和表面粗糙度的影响.结果表明:当溅射气压低于0.6 Pa时,薄膜为非晶态,在傅里叶变换红外光谱中,没有明显的吸收峰;当溅射气压不低于0.6 Pa时,薄膜的X射线衍射图中均出现了六方相的AlN(100)、(110)和弱的(002)衍射峰,说明所制备的AlN薄膜为多晶态,在傅里叶变换红外光谱中,在波数为677 cm-1处有明显的吸收峰;随着溅射气压的增大,薄膜表面粗糙度先减小后增大,而薄膜的沉积速率先增大后减少,且沉积速率较大有利于减小薄膜的表面粗糙度;在溅射气压为0.6 Pa时,薄膜具有最小的表面粗糙度和最大的沉积速率.     

直流磁控溅射制备AlN薄膜的结构和表面粗糙度

采用直流磁控反应溅射法,在Si(111)基底上成功制备了多晶六方相AlN薄膜.研究了溅射过程中溅射气压对薄膜结构和表面粗糙度的影响.结果表明:当溅射气压低于0.6 Pa时,薄膜为非晶态,在傅里叶变换红外光谱中,没有明显的吸收峰;当溅射气压不低于0.6 Pa时,薄膜的X射线衍射图中均出现了六方相的AlN(100)、(11...     

磁控溅射制备的AlN薄膜的结构、组分及性能分析

采用DC磁控溅射法,分别在p-Si(111)和玻璃基片上沉积AlN薄膜.利用X射线衍射(XRD)、X射线能谱仪(EDS)、原子力显微镜(AFM)、台阶仪紫外/可见分光光度计和傅里叶变换红外光谱仪(FTIR)分析了薄膜的结构组分、表面形貌、膜厚、光学性能和红外吸收特性.结果 表明:溅射电流对A1N薄膜的生成有很大的影响,当电流增加到0.40A时,薄膜中出现明显的h-AlN(100)和AlN(110)衍射峰;样品的最大高度都小于30nm;样品在250-1000nm波长范围内具有较高的透射率,当溅射电流为0.4A时,薄膜的禁带宽度约为5.94eV;在677.12cm1处出现强烈的吸收峰.     

计算机的“聪明”与“笨”

 计算机聪明吗?你一定会觉得这还用问!现在几乎什么事情都离不开计算机,它几乎什么事情都能干,而且比人干得快、干得好。日常生活、文化娱乐、行政事业管理,工厂、企业、银行、金融业的运营,公安交通管理,案件侦破、医疗卫生、科学技术的研究开发等等,几乎样样都离不开计算机。随随便便就可以举出很多例子。用计算机写文章比手写要方便得多,写错了,不合适,很容易修改;到超市买东西,选了一大筐,收银员一下子就把账结清,还打出一张收据,比手工结算快多了;照的照片不理想,计算机可以修改,老照片可以复原,模糊的照片可以变清晰.     

计算机的“快”与“大”

 1946年第一台真空管电子数字计算机问世,当时主要用于数值计算。50余年以来,计算机技术发展迅速,从用于数值计算到今天可以处理各种形式的信息,极大地推动了信息技术的发展。现代信息技术是以数字计算机为基础的。几十年来,数字计算机的发展,始终围绕着两个基本问题,这就是“快”和“大”。所谓“快”,就是运算速度快;所谓“大”,就是存储器的容量大。回顾人类历史的发展,信息技术的进步与发展起着十分重要的作用。过去人类以符号、图形、图画、声音、语言、文字等模拟量记录信息,传递信息。随着人类社会的进步,产生的信息越来越多。人们用信息爆炸来形容当前信息的数量和产生的速度。     

溅射功率对多层膜质量的影响

用磁控溅射技术制备薄膜，用X射线衍射研究在基片和靶间距离固定的情况下不同的溅射功率对薄膜结构的影响。结果表明：过低的溅射功率下淀积的薄膜有畸变的X射线衍射特征峰，特征峰强度小，半峰全宽大。而比较高溅射功率得到的薄膜有比较尖锐的X射线衍射特征峰，强度高和半峰全宽非常窄。研究表明，X射线衍射特征峰强度小和半峰全宽大的薄膜结构疏松，而强度高和半峰全宽非常窄的薄膜结构致密。     

溅射功率对Fe-Si-B-Nb-Cu薄膜微结构与磁性的影响

通过射频磁控溅射法制备了Fe_Si_B_Nb_Cu薄膜，采用x射线衍射与Mssb auer谱相结合分析了薄膜的微结构形态，研究了不同溅射功率对薄膜微结构的影响.其结果 表明：在较低溅射功率密度下，薄膜为无定型结构；随着溅射功率密度升高，沉积薄膜无需 热处理，便呈现出晶态和非晶态的混合相结构，晶态为纳米级的α_Fe(Si)和α_Fe(B)固溶 体；α_Fe(Si)相和α_Fe(B)相的体积分数、微结构组态、磁矩取向及宏观磁性能均随着溅 射功率的变化而变化. 关键词： 溅射功率 Fe_Si_B_Nb_Cu合金 薄膜微结构 磁矩取向     

Oblique-angle sputtered AlN nanocolumnar layer as a buffer layer in GaN-based LED

This work presents an aluminum nitride (AlN) nanocolumnar layer sputtered at various oblique angles and its application as a buffer layer for GaN-based light-emitting diodes (LEDs) that are fabricated on sapphire substrates. The OA-AlN nanocolumnar layer has a diameter of about 30-60 nm. The GaN-based LED structure is perpendicularly extended from the OA-AlN nanocolumnar layer. Then, the nanocolumnar structure is merged into p-GaN layer to form a mesa structure with a diameter of about 200-600 nm on the surface of the GaN-based LED. Moreover, optical characteristics of the LED were studied using photoluminescence, along with the blue-shifts observed as well.     

AlN/Al dual protective coatings on NdFeB by DC magnetron sputtering

AlN/Al dual protective coatings were prepared on NdFeB by DC magnetron sputtering in a home-made industrial apparatus. Comparing with Al coating, AlN/Al coatings have a denser structure of an outmost AlN amorphous layer following an inner Al columnar crystal layer. The coatings and NdFeB substrate combine well, and moreover, there is occurrence of metallurgy bonding in the interface layer. Both Al and AlN/Al coatings have a good protective ability to NdFeB. Especially, the corrosion resistance of AlN/Al coated NdFeB is improved largely. AlN/Al and Al protective coatings not only do not deteriorate the magnetic properties of NdFeB, but contribute to their slight increase.     

Structure and mechanical properties of Al/AlN multilayer with different AlN layer thickness

Nanometer scale Al/AlN multilayers have been prepared by dc magnetron sputtering technique with a columnar target. A set of Al/AlN multilayers with the Al layer thickness of 2.9 nm and the AlN layer thickness variation from 1.13 to 6.81 nm were determined. Low angle X-ray diffraction (LAXRD) was used to analyze the layered structure of multilayers. The phase structure of the coatings was investigated with grazing angle XRD (GAXRD). Mechanical properties of these multilayers were thoroughly studied using a nanoindentation and ball-on-disk micro-tribometer. It was found that the multilayer hardness and reduced modulus showed no strong dependence on the AlN layer thickness. Al2.9 nm/AlN1.13 nm multilayer had more excellent tribological properties than single layers and other proportion multilayers with a lowest friction coefficient of 0.15. And the tribological properties of all the multilayers are superior to the AlN single layer.     

等离子增强原子层沉积低温生长AlN薄膜

采用等离子增强原子层沉积技术在单晶硅基体上成功制备了AlN晶态薄膜, 利用椭圆偏振仪、原子力显微镜、小角掠射X射线衍射仪、高分辨透射电子显微镜、 X射线光电子能谱仪对样品的生长速率、表面形貌、晶体结构、薄膜成分进行了表征和分析, 结果表明, 采用等离子增强原子层沉积制备AlN晶态薄膜的最低温度为200 ℃, 薄膜表面平整光滑, 具有六方纤锌矿结构与(100)择优取向, Al_2p与N_1S的特征峰分别为74.1 eV与397.0 eV, 薄膜中Al元素与N元素以Al-N键相结合, 且成分均匀性良好. 关键词： 氮化铝 等离子增强原子层沉积 低温生长 晶态薄膜     

c轴定向氮化铝薄膜的制备

利用电子回旋共振 (ECR)微波增强化学气相沉积法 (PECVD)并使用氮气 (N2 ) ,氩气 (Ar)和AlCl3蒸气作为气源在直径为 6 .35cm的 (10 0 )单晶硅片表面制备了c轴定向氮化铝 (AlN)薄膜 ,并使用X射线衍射仪及其X射线特征能谱和扫描电镜 (SEM)分析了薄膜特征 ,研究了微波功率、基板温度和N2 流量对薄膜c轴定向的影响 ,得到了c轴偏差角小于 5°的高质量大面积AlN薄膜。     

Structure evolution and mechanical properties enhancement of Al/AlN multilayer

A set of Al/AlN multilayers with various modulation periods were prepared using DC magnetron sputtering method. Low angle X-ray diffraction (LAXRD) was used to analyze the layered structure of multilayers. The phase structure of the films was investigated with grazing angle X-ray diffraction (GAXRD). LAXRD results indicate that well-defined multilayer modulation structures are formed for the relatively larger modulation periods. However, the loss of mutilayered structure is detected in the multilayer with low modulation period. A very wide amorphous peak is observed in multilayer with modulation period of 4 nm. The multilayers show obvious crystallization at larger modulation periods, however, the diffraction peaks are much wider than the Al single layer because of the interruption of the continuous columnar grain growth by alternating deposition processes. Nanoindentation experiments were performed to study the mechanical properties as a function of multilayer modulation period. It is found that the hardness of the multilayers is greater than the hardness calculated from rule of mixtures. With the modulation periods adjusted, the multilayers are even harder than its hard component (AlN). A maximum hardness of 24.9 GPa, about 1.9 times larger than its hard component (AlN) and 3.7 times larger than the hardness calculated from the rule of mixtures, is found at the multilayer with modulation period of 16 nm. The wear test results show that the multilayers possess lower and stable friction coefficient, and superior wear properties.     

基于AlN膜钝化层VCSEL激光器热特性的研究

 用ANSYS有限元热分析软件模拟了基于AlN膜钝化层和SiO2膜钝化层的高功率垂直腔面发射半导体激光器(VCSEL)器件内部的热场分布和热矢量分布。经模拟得到基于AlN膜钝化层的VCSEL热阻为3.123℃/W,而基于SiO2膜钝化层的VCSEL的热阻为4.377℃/W。经实验测得基于AlN膜钝化层的VCSEL热阻为3.54℃/W,而基于SiO2膜钝化层的VCSEL的热阻为4.75℃/W,模拟结果与实验结果吻合较好。     

Introducing voids around the interlayer of AlN by high temperature annealing

Introducing voids into AlN layer at a certain height using a simple method is meaningful but challenging. In this work, the AlN/sapphire template with AlN interlayer structure was designed and grown by metal-organic chemical vapor deposition. Then, the AlN template was annealed at 1700 ℃ for an hour to introduce the voids. It was found that voids were formed in the AlN layer after high-temperature annealing and they were mainly distributed around the AlN interlayer. Meanwhile, the dislocation density of the AlN template decreased from 5.26×10⁹ cm^-2 to 5.10×10⁸ cm^-2. This work provides a possible method to introduce voids into AlN layer at a designated height, which will benefit the design of AlN-based devices.     

Cu掺杂的AlN铁磁性和光学性质的第一性原理研究

采用基于密度泛函理论（DFT）的总体能量平面波超软赝势方法,结合广义梯度近似（GGA）,对Cu掺杂AlN 32原子超原胞体系进行了几何结构优化,计算了Cu掺杂AlN的晶格常数,能带结构,电子态密度和光学性质.结果表明,Cu掺杂AlN会产生自旋极化状态,能带结构显示半金属性质,掺杂后带隙变窄,长波吸收加强,能量损失明显减小.同传统的稀磁半导体（DMS）相比,Cu掺杂AlN不会有铁磁性沉淀物的问题,因为Cu本身不具有磁性.因而,Cu掺杂的AlN也许是一种非常有前途的稀磁半导体. 关键词： AlN 第一性原理 铁磁性 光学性质