F,Al共掺杂ZnO透明导电薄膜的制备及掺杂机理研究

本文采用磁控溅射技术,对F和Al共掺杂ZnO(FAZO)薄膜进行研究,系统地研究了溅射气压对薄膜结构、形貌、光电等特性的影响.实验研究结果表明:F,Al共掺入并未改变ZnO的生长方式,所制备的薄膜都呈(002)择优生长;随着溅射气压增加,FAZO薄膜的沉积速率降低,结晶质量恶化,表面形貌由“弹坑状”逐渐变为“弹坑状”与“颗粒状”并存的形貌特性,表面粗糙度增加.在0.5 Pa时制备的FAZO薄膜性能最优,迁移率40.03 cm2/(V·s),载流子浓度3.92×1020 cm–3,电阻率最低,为3.98×10–4 ΩW·cm,380-1200 nm平均透过率约90%.理论模拟结果表明:F和Al的共掺杂兼顾了F,Al单独掺杂的优点,克服了以往金属元素掺杂仅依靠金属元素轨道提供导电电子的不足,实现了既增加载流子浓度又减少了掺入原子各轨道间相互作用对载流子散射的影响.掺入的F 2p电子轨道对O 2p及Zn 4s电子轨道产生排斥,使它们分别下移,提供导电电子;同时掺入的Al的3s和3p电子轨道也为导电电子提供了贡献.F和Al共掺之后载流子浓度提升更加显著,导电性能增强.

胀接口失效分析及保证运行空冷器的更换方案

在某水电站检查过程中发现空冷器出现漏水的情况,对空冷器运行故障进行排查,发现空冷器故障原因为胀接口位置管壁减薄。为保障电站的运行安全,需要一段时间对空冷器的部件进行更换,并且在停运时间内制定了特训制度等相关运行策略。如何确定更换冷却管的材质、壁厚以及胀接工艺等成为更换方案制定过程中的困难因素。对此状况针对性地提出了一套更换方案:采用不锈钢冷却管胀焊工艺,增加管道壁厚。该方案的实施对确保大型水电站空冷器安全稳定的运行具有重要意义。

FAULT CAUSED BY WATER PRESSURE IN THE HEAD-COVER CHAMBER

Owing to the high temperature of the thrust beating pads, the No.l unit wasn＇t performed in the upgrading test at Liujiaxia Hydropower Plant. Through the experimental and theoretical analysis, it has been confirmed that the fault unit was caused by the high water pressure in the head-cover chamber. This type of the fault is out-of-the-way. After the suitable measure wags against the fault were taken, the No. 1 unit can stably operate. The conclusions and the methodology are of the certain reference value to the fault-diagnosis of the hydroelectric unit.