取样光栅分布布拉格反射半导体激光器的制作方法

一种取样光栅分布布拉格反射半导体激光器的制作方法，包括:在n型InP衬底上分别外延InP缓冲层和介质膜;在介质膜上刻出条形凹槽，并依次生长InGaAsP下限制层、InGaAsP/InGaAsP多量子阱、InGaAsP上限制层和InP光栅制作保护层;去除介质膜;刻出多条取样光栅窗口;制作取样光栅;腐蚀保护层;依次生长p-InP层、p-InGaAsP刻蚀阻止层、p-InP层和p+-InGaAs层;形成脊形波导;刻蚀形成电隔离沟;在p-InGaAsP刻蚀阻止层上进行He离子注入;在上述步骤制作的器件结构的上表面和脊形波导的侧面淀积介质绝缘层;在器件的上表面溅射p电极;将衬底减薄，并蒸发n电极，解理管芯，完成器件的制作

电动汽车减速器NVH仿真研究与优化

减速器是电动汽车电驱动总成的关键部件，是电动汽车的主要噪声来源之一。减速器噪声水平直接关系电动汽车整车噪声（Noise）、振动（Vibration）、声振粗糙度（Harshness）(简称NVH）性能和乘客舒适性。以某款减速器为研究对象，分析了减速器振动噪声产生机理。在此基础上，引出了评估减速器NVH的4个仿真指标：减速器传递误差、接触斑点、轴承座动刚度和模态。从这4个指标出发，分别进行了仿真研究和试验对标。结果说明，仿真和试验结果一致性较好。基于以上研究成果，判定该减速器二级齿轮的传递误差和接触斑点需要优化。通过加强轮辐结构和轮齿修形等优化手段，结果显示，二级齿轮仿真传递误差和接触斑点得到改善；优化方案装车试验测试的噪声也得到了改善

JUNO Sensitivity on Proton Decay p→νˉK+p\to \bar\nu K^+ Searches

The Jiangmen Underground Neutrino Observatory (JUNO) is a large liquid scintillator detector designed to explore many topics in fundamental physics. In this paper, the potential on searching for proton decay in $p\to \bar\nu K^+$ mode with JUNO is investigated.The kaon and its decay particles feature a clear three-fold coincidence signature that results in a high efficiency for identification. Moreover, the excellent energy resolution of JUNO permits to suppress the sizable background caused by other delayed signals. Based on these advantages, the detection efficiency for the proton decay via $p\to \bar\nu K^+$ is 36.9% with a background level of 0.2 events after 10 years of data taking. The estimated sensitivity based on 200 kton-years exposure is $9.6 \times 10^{33}$ years, competitive with the current best limits on the proton lifetime in this channel

JUNO sensitivity on proton decay p → ν K + searches*

The Jiangmen Underground Neutrino Observatory (JUNO) is a large liquid scintillator detector designed to explore many topics in fundamental physics. In this study, the potential of searching for proton decay in the $p\to \bar{\nu} K^+$ mode with JUNO is investigated. The kaon and its decay particles feature a clear three-fold coincidence signature that results in a high efficiency for identification. Moreover, the excellent energy resolution of JUNO permits suppression of the sizable background caused by other delayed signals. Based on these advantages, the detection efficiency for the proton decay via $p\to \bar{\nu} K^+$ is 36.9% ± 4.9% with a background level of $0.2\pm 0.05({\rm syst})\pm$$0.2({\rm stat})$ events after 10 years of data collection. The estimated sensitivity based on 200 kton-years of exposure is $9.6 \times 10^{33}$ years, which is competitive with the current best limits on the proton lifetime in this channel and complements the use of different detection technologies