InGaAs(InAlAs)/InP和InP/InAlAs湿法选择腐蚀研究

介绍了两种选择腐蚀液对InGaAs(InAlAs)I/nP和InPI/nAlAs异质结构材料选择腐蚀的实验结果,重点介绍在InAlAs上面生长InP的湿法选择腐蚀,用HClH∶3PO4C∶H3COOH系列腐蚀液,InPI/nAlAs选择比大于300。InPI/nAlAs湿法选择腐蚀的结果可以很好应用到OEIC芯片制作中,并取得了较好的器件及电路结果。

GaAs MISFET制备中柠檬酸/双氧水溶液对GaAs/Al_xGa_(1-x)As结构的选择湿法腐蚀

用α台阶仪和原子力显微镜(AFM)研究了不同体积比的柠檬酸(50%)/双氧水溶液对GaAs/AlxGa1-xAs系统的选择湿法腐蚀特性,对AlxGa1-xAs停止层的组分和腐蚀液体积比进行了优化.当腐蚀液体积比在1.5∶1到2∶1范围时获得了最好的选择腐蚀效果.在25℃.温度条件下,当腐蚀液体积比为1.5∶1时,对Al摩尔分数x为0.2、0.3和1的GaAs/AlxGa1-xAs系统腐蚀比分别为45、74和大于200,表面腐蚀形貌均匀平整.将这种选择腐蚀技术用于GaAsMISFET的栅槽工艺,获得了良好的阈值电压均匀性.

GaAs MISFET制备中的选择性腐蚀研究

研究了体积比为1:1到10:1的50%柠檬酸/双氧水溶液对GaAs/AlxGa(?)-xAs结构腐蚀的选择特性, 用α台阶仪、原子力显微镜(AFM)等方法研究了腐蚀样品表面的微观形貌。利用这种选择腐蚀技术制备了undoped-GaAs/n-GaAs调制掺杂沟道金属-绝缘体-半导体场效应晶体管,获得了很好的器件特性参数,证明了这种腐蚀溶液适合于器件制备中的栅挖槽工艺。

基于GaAs/AlAs腐蚀自停止的新型水听器工艺

针对感应耦合等离子(ICP)刻蚀气室气体分布不均匀性所导致的被刻蚀台面中间厚、边缘薄及干法刻蚀后残余应力大等缺点,进行了GaAs/AlAs的选择性湿法腐蚀工艺研究.腐蚀液为50%一水柠檬酸(C6H8O7.H2O)溶液与30%双氧水(H2O2)的混合物,当二者体积比为3∶1时,GaAs/AlAs的选择比达到79以上.用原子力显微镜(AFM)和扫描电镜(SEM)对腐蚀后的试验片测试后发现,该体积比腐蚀液腐蚀的试验片具有表面粗糙度低、刻蚀各向异性好、选择比高等优点,能够满足传感器加工的需要;结合试验结果,设计了一种待加工梁厚3μm的外延材料结构,并对传感器的加工工艺进行了优化;最后,采用ANSYS对所设计的结构进行了仿真分析,仿真结果表明,该结构具有可行性,可实现水平面内的声学探测.

新型长波长InP基谐振腔增强型光探测器

介绍了一种新型长波长InP基谐振腔增强型(RCE)光探测器。通过V(FeCl3):V(H2O)溶液对InGaAs牺牲层的选择性湿法腐蚀,制备出具有InP/空气隙的高反射率分布布拉格反射镜(DBR),并将该选择性湿法腐蚀技术成功地应用到长波长InP基谐振腔增强型光探测器的制备中去,从而彻底解决了InP/InGaAsP高反射率分布布拉格反射镜难以外延生长的问题。所制备出的谐振腔增强型光探测器,其台面面积为50μm×50μm,底部反射镜为1.5对的InP/空气隙分布布拉格反射镜,顶部反射镜靠InGaAsP与空气的界面反射来实现。测试结果表明,该谐振腔增强型光探测器在波长1.510μm处获得了约59％的峰值量子效率,在3V反偏压下暗电流为2nA,3dB响应带宽达到8GHz。

Two-step gate-recess process combining selective wet-etching and digital wet-etching for InAIAs/InGaAs InP-based HEMTs

A two-step gate-recess process combining high selective wet-etching and non-selective digital wet-etching techniques has been proposed for InAlAs/InGaAs InP-based high electron mobility transistors （HEMTs）. High etching-selectivity ratio of InGaAs to InA1As material larger than 100 is achieved by using mixture solution of succinic acid and hydrogen peroxide （H202）. Selective wet-etching is validated in the gate-recess process of InA1As/InGaAs InP-based HEMTs, which proceeds and auto- matically stops at the InA1As barrier layer. The non-selective digital wet-etching process is developed using a separately controlled oxidation/de-oxidation technique, and during each digital etching cycle 1.2 nm InAIAs material is removed. The two-step gate-recess etching technique has been successfully incorporated into device fabrication. Digital wet-etching is repeated for two cycles with about 3 nm InAIAs barrier layer being etched off. InP-based HEMTs have demonstrated superior extrinsic trans- conductance and RF characteristics to devices fabricated during only the selective gate-recess etching process because of the smaller gate to channel distance.