共查询到17条相似文献,搜索用时 187 毫秒
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为进行10 keV X射线和60Co γ射线总剂量辐射效应的比较,采用这两种辐射源对SOI (Silicon-on-Insulator) n-MOSFET在不同偏置条件下进行总剂量辐照试验,分析了SOI NMOS器件在两种辐射源下辐照前后的阈值电压的漂移值并进行比较.实验结果表明,SOI NMOS器件的前栅特性中X射线与60Co γ射线辐照感生阈值电压漂移值的比值α随总剂量增加而增大,而背栅特性中α值在不同偏置条件下变化趋势是不同的;在总剂量为1×106 rad(Si)时,前栅器件α值为0.6~0.75,背栅器件α值为0.76~1.0. 相似文献
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总剂量辐射效应会导致绝缘体上硅金属氧化物半导体场效应晶体管(DSOI MOSFET)器件的阈值电压漂移、泄漏电流增大等退化特性。由于背栅端口的存在,SOI器件存在新的总剂量效应加固途径,对于全耗尽SOI器件,利用正背栅耦合效应,可通过施加背栅偏置电压补偿辐照导致的器件参数退化。本文研究了总剂量辐照对双埋氧层绝缘体上硅金属氧化物半导体场效应晶体管(DSOI MOSFET)总剂量损伤规律及背栅偏置调控规律,分析了辐射导致晶体管电参数退化机理,建立了DSOI晶体管总剂量效应模拟电路仿真器(SPICE)模型。模型仿真晶体管阈值电压与实测结果≤6 mV,同时根据总剂量效应模型给出了相应的背栅偏置补偿模型,通过晶体管背偏调控总剂量效应SPICE模型仿真输出的补偿电压与试验测试结果对比,N型金属氧化物半导体场效应晶体管(NMOSFET)的背偏调控模型误差为9.65%, P型金属氧化物半导体场效应晶体管(PMOSFET)为5.24%,该模型可以准确反映DSOI器件辐照前后阈值特性变化,为器件的背栅加固提供参考依据。 相似文献
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讨论了CoSi2SALICIDE结构对CMOS/SOI器件和电路抗γ射线总剂量辐照特性的影响.通过与多晶硅栅器件对比进行的大量辐照实验表明,CoSi2SALICIDE结构不仅可以降低CMOS/SOI电路的源漏寄生串联电阻和局域互连电阻,而且对SOI器件的抗辐照特性也有明显的改进作用.与多晶硅栅器件相比,采用CoSi2SALICIDE结构的器件经过辐照以后,器件的阈值电压特性、亚阈值斜率、泄漏电流、环振的门延迟时间等均有明显改善.由此可见,CoSi2SALICIDE技术是抗辐照加固集成电路工艺的理想技术之一. 相似文献
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讨论了CoSi2SALICIDE结构对CMOS/SOI器件和电路抗γ射线总剂量辐照特性的影响.通过与多晶硅栅器件对比进行的大量辐照实验表明,CoSi2SALICIDE结构不仅可以降低CMOS/SOI电路的源漏寄生串联电阻和局域互连电阻,而且对SOI器件的抗辐照特性也有明显的改进作用.与多晶硅栅器件相比,采用CoSi2 SALICIDE结构的器件经过辐照以后,器件的阈值电压特性、亚阈值斜率、泄漏电流、环振的门延迟时间等均有明显改善.由此可见,CoSi2SALICIDE技术是抗辐照加固集成电路工艺的理想技术之一. 相似文献
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采用CoSi2 SALICIDE结构CMOS/SOI器件辐照特性的实验研究 总被引:2,自引:0,他引:2
讨论了CoSi2SALICIDE结构对CMOS/SOI器件和电路抗γ射线总剂量辐照特性的影响。通过与多晶硅栅器件对比进行的大量辐照实验表明,CoSi2SALICIDE结构不仅可以降低CMOS/SOI电路的源漏寄生串联电阻和局域互连电阻,而且对SOI器件的抗辐照特性也有明显的改进作用。 相似文献
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采用硅离子注入工艺对注氧隔离(SIMOX)绝缘体上硅(SOI)材料作出改性,分别在改性材料和标准SIMOXSOI材料上制作部分耗尽环型栅CMOS/SOI器件,并采用10keVX射线对其进行了总剂量辐照试验。实验表明,同样的辐射总剂量条件下,采用改性材料制作的器件与标准SIMOX材料制作的器件相比,阈值电压漂移小得多,亚阈漏电也得到明显改善,说明改性SIMOXSOI材料具有优越的抗总剂量辐射能力。 相似文献
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A technique is developed to measure silicon-on-insulator (SOI) silicon device film thickness using a MOSFET. The method is based on CV measurements between gate and source/drain at two different back-gate voltages. The SOI devices used in this study were n+ polysilicon gate n-channel MOSFETs fabricated with modified submicrometer CMOS technology on SIMOX (separation by implanted oxygen) wafers. The SIMOX wafers were implanted with a high dose of oxygen ions (1018 cm-2) at 200 keV and subsequently annealed at 1230°C. The NMOS threshold boron implant dose is 2×1012 cm-2. This method is simple, nondestructive, and no special test structure is needed. Using this technique, SOI film thickness mapping was made on a finished wafer and a thickness variation of ±150 Å was found 相似文献
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nMOSFET低能X射线辐照特性研究 总被引:1,自引:1,他引:0
讨论了MOSFET的辐照损伤机理,通过低能(10keV)X射线辐照试验,分析了不同X射线辐照总剂量、不同剂量率对nMOSFET单管的转移特性以及阈值电压的影响。结果表明X射线辐照对nMOSFET的阈值电压变化的影响与^60Co辐照影响的规律基本一致。 相似文献
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目前,SOI(SiliconOnInsulator)材料的一个主要用途是用来制作抗辐照电路,本文以SIMOX(SeperationbyIMplantationofOXygen)技术为主,详细论述了SOI材料和器件(MOSFET)的辐照特性及其机理,包括总剂量、瞬时和单粒子效应,并以总剂量效应为主。经过恰当的加固工艺和优化设计,可以制造出优良的抗辐照集成电路。 相似文献
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Konstantin O. Petrosyants Lev M. Sambursky Igor A. Kharitonov Boris G. Lvov 《Journal of Electronic Testing》2017,33(1):37-51
The methodology of modeling and simulation of environmentally induced faults in radiation hardened SOI/SOS CMOS IC’s is presented. It is realized at three levels: CMOS devices – typical analog or digital circuit fragments – complete IC’s. For this purpose, a universal compact SOI/SOS MOSFET model for SPICE simulation software with account for TID, dose rate and single event effects is developed. The model parameters extraction procedure is described in great depth taking into consideration radiation effects and peculiarities of novel radiation-hardened (RH) SOI/SOS MOS structures. Examples of radiation-induced fault simulation in analog and digital SOI/SOS CMOS LSI’s are presented for different types of radiation influence. The simulation results show the difference with experimental data not larger than 10–20% for all types of radiation. 相似文献
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A novel nanoscaled device concept: quasi-SOI MOSFET to eliminate the potential weaknesses of UTB SOI MOSFET 总被引:2,自引:0,他引:2
Yu Tian Ru Huang Xing Zhang Yangyuan Wang 《Electron Devices, IEEE Transactions on》2005,52(4):561-568
For the first time, a novel device concept of a quasi-silicon-on-insulator (SOI) MOSFET is proposed to eliminate the potential weaknesses of ultrathin body (UTB) SOI MOSFET for CMOS scaling toward the 35-nm gate length, and beyond. A scheme for fabrication of a quasi-SOI MOSFET is presented. The key characteristics of quasi-SOI are investigated by an extensive simulation study comparing them with UTB SOI MOSFET. The short-channel effects can be effectively suppressed by the insulator surrounding the source/drain regions, and the suppression capability can be even better than the UTB SOI MOSFET, due to the reduction of the electric flux in the buried layer. The self-heating effect, speed performance, and electronic characteristics of quasi-SOI MOSFET with the physical channel length of 35 nm are comprehensively studied. When compared to the UTB SOI MOSFET, the proposed device structure has better scaling capability. Finally, the design guideline and the optimal regions of quasi-SOI MOSFET are discussed. 相似文献