高剂量注氮对注氧隔离硅材料埋氧层中正电荷密度的影响

为研究注氮改性对注氧隔离硅材料中埋氧层性质的影响,向其埋氧层内注入了10¹⁶ cm^-2的高剂量氮.实验结果表明,与未注氮的埋氧层相比,所有注氮的埋氧层中的正电荷密度显著增加.实验还发现,注氮后的退火可使埋氧层内的正电荷密度进一步上升.但与注氮导致的埋氧层内正电荷密度的显著上升相比,退火时间对注氮的埋氧层内正电荷密度的影响不大.电容-电压测量结果显示,在埋氧层内部,注氮后未退火的样品与在1100 ℃的氮气气氛下退火2.5 h的样品相比,二者具有近似相同的等效正电荷 关键词： 注氧隔离 埋氧 注氮 正电荷密度     

SIMOX SOI埋氧注氮工艺对埋氧中固定正电荷密度的影响

在SIMOX SOI材料的埋氧中注氮是为了增强该类材料的抗辐射能力.通过C-V研究表明，对于埋氧层为150 nm的SIMOX SOI材料来说，当在其埋氧中注入4×10¹⁵cm^-2剂量的氮后，与未注氮埋氧相比，注氮埋氧中的固定正电荷密度显著增加了；而对于埋氧层为375nm的SIMOX SOI材料来说，当注氮剂量分别为2×10¹⁵cm^-2和3×10¹⁵cm^{-2关键词： SIMOX 埋氧 注氮 固定正电荷密度}     

埋氧层注氮工艺对部分耗尽SOI nMOSFET特性的影响

研究了埋氧层中注氮后对制作出的部分耗尽SOInMOSFET的特性产生的影响.实验发现，与不注氮的SIMOX基片相比，由注氮SIMON基片制作的nMOSFET的电子迁移率降低了.且由最低注入剂量的SIMON基片制作的器件具有最低的迁移率.随注入剂量的增加，迁移率略有上升，并趋于饱和.分析认为，电子迁移率的降低是由于Si/SiO2界面的不平整造成的.实验还发现，随氮注入剂量的提高，nMOSFET的阈值电压往负向漂移.但是，对应最低注入剂量的器件阈值电压却大于用SIMOX基片制作出的器件.固定氧化物正电荷及界面陷阱密度的大小和分布的变化可能是导致阈值电压变化的主要因素.另外发现，用注氮基片制作出的部分耗尽SOInMOSFET的kink效应明显弱于用不注氮的SIMOX基片制作的器件. 关键词： SOI nMOSFET 氮注入 电子迁移率 阈值电压     

离子注入形成SOI结构的界面及埋层的俄歇能谱研究

本文中研究了O⁺(200keV,1.8×10¹⁸/cm²)和N⁺(190keV,1.8×10¹⁸/cm²)注入Si形成SOI(Silicon on Insulator)结构的界面及埋层的化学组成。俄歇能谱的测量和研究结果表明:注O⁺的SOI结构在经1300℃,5h退火后,其表层Si和氧化硅埋层的界面存在一个不饱和氧化硅状态,氧化硅埋层是由SiO₂相和这不饱和氧化硅态组成,而且氧化硅埋层和体硅界面不同于表层Si和氧化硅埋层界面;注N⁺的SOI结构在经1200℃,2h退火后,其氮化硅埋层中存在一个富N的疏松夹层,表层Si和氮化硅埋层界面与氮化硅埋层和体硅界面性质亦不同。这些结果与红外吸收和透射电子显微镜及离子背散射谱的分析结果相一致。还对两种SOI结构界面与埋层的不同特征的原因进行了分析讨论。 关键词：     

质子与中子辐照对电荷耦合器件暗信号参数的影响及其效应分析

对科学级电荷耦合器件(charge-coupled device, CCD)进行了质子和中子辐照试验及退火试验, 应用蒙特卡洛方法计算了质子和中子在CCD中的能量沉积, 分析了器件的辐射损伤机理. 仿真计算了N⁺埋层内沉积的位移损伤剂量, 辐照与退火试验过程中主要考察暗信号的变化规律. 研究结果显示, 质子与中子辐照均会引发暗信号退化, 其退化的规律与位移损伤剂量变化一致; 退火后, 质子辐照所致CCD暗信号大幅度恢复, 其体暗信号增加量占总暗信号增加量的比例最多为22%; 中子辐照引发的暗信号增长主要为体暗信号. 质子和中子在N⁺埋层产生相同位移损伤剂量的情况下, 两者导致的体暗信号增长量相同, 质子与中子辐照产生的体缺陷对体暗信号增长的贡献是同质的.     

氦离子注入4H-SiC晶体的纳米硬度研究

4H-SiC晶体经能量为100 keV,剂量为3×10¹⁶ cm^-2的氦离子高温（500 K）注入后,再在773—1273 K温度范围内进行了退火处理,最后使用纳米压痕仪测量了样品注入面的硬度.测试结果表明,在500—1273 K温度范围内样品的硬度随退火温度升高呈现先增大后减小再增大的趋势,其中773 K退火样品的硬度增大明显.分析认为,退火样品的硬度变化是由退火过程中缺陷复合与氦泡生长导致样品内部的Si—C键密度、键长和键角改变引起的. 关键词： SiC 注入 氦泡 纳米压痕     

退火对含氮氟非晶碳膜结构及光学带隙的影响

采用射频等离子体增强化学气相沉积法,在不同条件下制备了含氮氟非晶碳膜,着重考察了退火温度对膜结构和光学带隙的影响. 研究发现：在350℃时,膜仍很稳定,当退火温度达到400℃时,其内各化学键的相对含量发生很大的改变. 膜的光学带隙随着退火温度的升高而增大,红外和拉曼光谱分析显示其原因是：退火使得膜内F的相对浓度降低,sp²相对含量升高,导致σ-σ^*带边态密度降低. 关键词： 含氮氟非晶碳膜 退火 光学带隙     

直拉硅中氮在高温退火过程中对氧沉淀的影响

研究了掺氮直拉硅单晶（NCZ）中氮在高温退火过程中对氧沉淀的影响.通过不同温度高温退 火后，测量氧沉淀的生成量和观察硅片体内微缺陷（BMD）密度与高温形核时间的变化关系 ，同时用透射电子显微镜(TEM)观察氧沉淀及相关缺陷的微观结构.实验结果表明高温退火后 氮对硅中氧沉淀形核有明显的促进作用，在相同退火条件下NCZ硅中BMD密度要远远高于相应 的普通直拉硅.这是由于氮在高温下与氧反应形成氮氧复合体（N-V-O）促进了氧沉淀的形核 ，而且TEM的结果表明氧沉淀的形态都是平板状，周围存在应力场. 关键词： 直拉硅 掺氮 氧沉淀     

碳化硅中氦离子高温注入引入的缺陷及其退火行为的光谱研究

对氦（He）离子高温（600 K）注入6H-SiC中的辐照缺陷,在阶梯温度退火后演化行为的拉曼光谱和室温光致发光谱的特征进行了分析.这两种方法的实验结果表明,离子注入所产生晶格损伤的程度与注入剂量有关;高温退火导致损伤的恢复,不同注入剂量造成的晶格损伤需要不同的退火温度才可恢复.在阶梯温度退火下呈现出了点缺陷的复合、氦-空位团的产生、氦泡的形核、长大等特性.研究表明：高温（600 K）注入在一定剂量范围内是避免注入层非晶化的一个重要方法,为后续利用氦离子注入空腔掩埋层吸杂或者制备低成本、低缺陷密度的绝缘层 关键词： 6H-SiC 离子注入 拉曼光谱 光致发光谱     

退火对微构造黑硅光致发光瞬态性质的影响

研究了热退火对飞秒激光脉冲在空气中微构造的黑硅材料的光致发光(PL)时间分辨光谱和发光强度衰减性质的影响,分析了退火后黑硅材料内光生载流子的运动和缺陷的性质。通过应用双指数函数拟合PL的强度衰减曲线,得到退火导致黑硅材料光谱变化的可能机理。采用热扩散理论说明退火造成氧缺陷的增加和非平衡载流子辐射复合率的增大,导致退火黑硅的PL强度随着退火温度的升高而增大。退火后时间常数增大且慢衰减过程比重增大,说明退火消除并修复了微构造表面及内部的一些缺陷,增加表面束缚态,减小非辐射复合中心的密度,从而增大了辐射复合所占的比重,导致退火黑硅的PL谱强度增大。黑硅发光的最佳退火条件是800℃真空退火30 min。     

Total dose radiation response of modified commercial silicon-on-insulator materials with nitrogen implanted buried oxide

Nitrogen ions of various doses are implanted into the buried oxide(BOX) of commercial silicon-on-insulator(SOI) materials,and subsequent annealings are carried out at various temperatures.The total dose radiation responses of the nitrogen-implanted SOI wafers are characterized by the high frequency capacitance-voltage(C-V) technique after irradiation using a Co-60 source.It is found that there exist relatively complex relationships between the radiation hardness of the nitrogen implanted BOX and the nitrogen implantation dose at different irradiation doses.The experimental results also suggest that a lower dose nitrogen implantation and a higher post-implantation annealing temperature are suitable for improving the radiation hardness of SOI wafer.Based on the measured C-V data,secondary ion mass spectrometry(SIMS),and Fourier transform infrared(FTIR) spectroscopy,the total dose responses of the nitrogen-implanted SOI wafers are discussed.     

Improvement of total-dose irradiation hardness of silicon-on-insulator materials by modifying the buried oxide layer with ion implantation

The hardening of the buried oxide (BOX) layer of separation by implanted oxygen (SIMOX) silicon-on-insulator (SOI) wafers against total-dose irradiation was investigated by implanting ions into the BOX layers. The tolerance to total-dose irradiation of the BOX layers was characterized by the comparison of the transfer characteristics of SOI NMOS transistors before and after irradiation to a total dose of 2.7 Mrad(SiO₂. The experimental results show that the implantation of silicon ions into the BOX layer can improve the tolerance of the BOX layers to total-dose irradiation. The investigation of the mechanism of the improvement suggests that the deep electron traps introduced by silicon implantation play an important role in the remarkable improvement in radiation hardness of SIMOX SOI wafers.     

埋氧注氮工艺对部分耗尽SOI PMOSFET顶栅氧的辐射硬度的影响

研究了埋氧注氮对部分耗尽SOI PMOSFET顶栅氧的总剂量辐射硬度所造成的影响。注入埋氧的氮剂量分别是8×1015 , 2×1016 和1×1017cm-2。实验结果表明，辐照前，晶体管的阈值电压随氮注入剂量的增加向负方向漂移。在正2V的栅偏压下，经5×105 rad(Si)的总剂量辐照后，同埋氧未注氮的晶体管相比，埋氧注氮剂量为8×1015 cm-2的晶体管呈现出了较小的阈值电压漂移量。然而，当注氮剂量高达2×1016 和 1×1017cm-2时，所测大多数晶体管的顶栅氧却由于5×105 rad(Si)的总剂量辐照而受到了严重损伤。另外，对于顶栅氧严重受损的晶体管，其体-漏结也受到了损伤。所有的实验结果可通过氮注入过程中对顶硅的晶格损伤来解释。     

Dual material insulator SOI-LDMOSFET: A novel device for self-heating effect improvement

The silicon-on-insulator (SOI) power devices show good electrical performance but they suffer from inherent self-heating effect (SHE), which limits their operation at high current levels. The SHE effect is because of low thermal conductivity of the buried oxide layer. In this paper we propose a novel silicon on insulator lateral double diffused MOSFET (SOI-LDMOSFET) where the buried insulator layer under the active region consists of two materials in order to decrease the SHE. The proposed structure is called dual material buried insulator SOI-LDMOSFET (DM-SOI). Using two-dimensional and two-carrier device simulation, we demonstrate that the heat dissipation and the SHE can be improved in a conventional SOI-LDMOSFET by replacement of the buried oxide with dual material buried insulator (silicon nitride and silicon oxide) beneath the active region. The heat generated in the active silicon layer can be flowed through the buried silicon nitride layer to the silicon substrate easily due to high thermal conductivity of silicon nitride. Furthermore, the channel temperature is reduced, negative drain current slope is mitigated and electron and hole mobility is increased during high-temperature operation. The simulated results show that silicon nitride is a suitable alternative to silicon dioxide as a buried insulator in SOI structures, and has better performance in high temperature.     

Influence of nitrogen implantation into the buried oxide on the radiation hardness of silicon-on-insulator wafers

In order to improve the total-dose radiation hardness of the buried oxide of separation by implanted oxygen silicon-on-insulator wafers, nitrogen ions were implanted into the buried oxide with a dose of 1016 cm-2 , and subsequent annealing was performed at 1100°C. The effect of annealing time on the radiation hardness of the nitrogen implanted wafers has been studied by the high frequency capacitance-voltage technique. The results suggest that the improvement of the radiation hardness of the wafers can be achieved through a shorter time annealing after nitrogen implantation. The nitrogen-implanted sample with the shortest annealing time 0.5 h shows the highest tolerance to total-dose radiation. In particular, for the 1.0 and 1.5 h annealing samples, both total dose responses were unusual. After 300-krad(Si) irradiation, both the shifts of capacitance-voltage curve reached a maximum, respectively, and then decreased with increasing total dose. In addition, the wafers were analysed by the Fourier transform infrared spectroscopy technique, and some useful results have been obtained.     

Research on total-dose hardening for H-gate PD NMOSFET/SIMOX by ion implanting into buried oxide

In this work,we investigate the back-gate I-V characteristics for two kinds of NMOSFET/SIMOX transistors with H gate structure fabricated on two different SOI wafers.A transistors are made on the wafer implanted with Si+ and then annealed in N2,and B transistors are made on the wafer without implantation and annealing.It is demonstrated experimentally that A transistors have much less back-gate threshold voltage shift AVth than B transistors under X-ray total dose irradiation.Subthreshold charge separation technique is employed to estimate the build-up of oxide charge and interface traps during irradiation,showing that the reduced △Vth for A transistors is mainly due to its less build-up of oxide charge than B transistors.Photoluminescence (PL) research indicates that Si implantation results in the formation of silicon nanocrystalline (nanocluster) whose size increases with the implant dose.This structure can trap electrons to compensate the positive charge build-up in the buried oxide during irradiation,and thus reduce the threshold voltage negative shift.