新型图形化 SOI LDMOS结构的性能分析

提出一种图形化SOILDMOSFET结构,埋氧层在器件沟道下方是断开的,只存在于源区和漏区.数值模拟结果表明,相对于无体连接的SOI器件,此结构的关态和开态击穿电压可分别提高57%和70%,跨导平滑,开态I-V曲线没有翘曲现象,器件温度低100K左右,同时此结构还具有低的泄漏电流和输出电容.沟道下方开硅窗口可明显抑制SOI器件的浮体效应和自加热效应.此结构具有提高SOI功率器件性能和稳定性的开发潜力.     

新型PSOI LDMOSFET的结构优化

针对沟道下方开硅窗口的图形化SOI(PSOI)横向双扩散MOSFET(LDMOSFET)进行了结构优化分析,发现存在优化的漂移区长度和掺杂浓度以及顶层硅厚度使PSOI LDMOSFET具有最大的击穿电压和较低的开态电阻.PSOI结构的RESURF条件为Nd·tsi=1.8～3×101 2cm-2.对结构优化的PSOILDMOSFET进行了开态输出特性模拟,输出特性曲线没有曲翘现象和负导现象,开态击穿电压可达到1 6V,器件有源区的温度降低了50℃.结构优化有利于提高器件性能和降低器件的开发成本.     

用于智能功率集成电路的PTG-LDMOST

提出一种用于智能功率集成电路的基于绝缘体上硅(SOI)的部分槽栅横向双扩散MOS晶体管(PTG-LDMOST)。PTG-LDMOST由传统的平面沟道变为垂直沟道,提高了器件击穿电压与导通电阻之间的折衷。垂直沟道将开态电流由器件的表面引向体内降低了导通电阻,而且关态的时候耗尽的JFET区参与耐压,提高单位漂移区长度击穿电压。仿真结果表明:对于相同的10微米漂移区长度,新结构的击穿电压从常规结构的111V增大到192V,增长率为73%。     

一种新型全耗尽双栅MOSFET

提出一种新型全耗尽双栅MOSFET,该器件具有异质栅和LDD结构.异质栅由主栅和两个侧栅组成,分区控制器件的沟道表面势垒.通过Tsuprem-4工艺模拟和Medici器件模拟验证表明,与普通双栅全耗尽SOI相比,该器件获得了更好的开态/关态电流比和亚阈值斜率.在0.18μm工艺下,开态/关态电流比约为1010,亚阈值斜率接近60mV/dec.     

一种新型全耗尽双栅MOSFET

提出一种新型全耗尽双栅MOSFET,该器件具有异质栅和LDD结构.异质栅由主栅和两个侧栅组成,分区控制器件的沟道表面势垒.通过Tsuprem-4工艺模拟和Medici器件模拟验证表明,与普通双栅全耗尽SOI相比,该器件获得了更好的开态/关态电流比和亚阈值斜率.在0.18μm工艺下,开态/关态电流比约为1010,亚阈值斜率接近60mV/dec.     

50nm SOI-DTMOS器件的性能

利用二维器件模拟软件ISE对5 0nm沟道长度下SOI DTMOS器件性能进行了研究,并与常规结构的SOI器件作了比较.结果表明,在5 0nm沟长下,SOI DTMOS器件性能远远优于常规SOI器件.SOI DTMOS器件具有更好的亚阈值特性,其亚阈值泄漏电流比常规SOI器件小2～3个数量级,从而使其具有更低的静态功耗.同时,SOI DTMOS器件较高的驱动电流保证了管子的工作速度,并且较常规SOI器件能更有效地抑制短沟道器件的穿通效应、DIBL及SCE效应,从而保证了在尺寸进一步减小的情况下管子的性能.对SOI DTMOS器件的物理机制进行了初步分析,揭示了其性能远优于常规结构的物理本质     

亚100nm SOI器件的结构优化分析

分析了SOI器件各结构参数对器件性能的影响,给出了器件各结构参数的优化方向,找出了可行硅膜厚度和可行沟道掺杂浓度之间的设计容区.在部分耗尽与全耗尽SOI器件的交界处,阈值电压的漂移有一个峰值,在器件设计时应避免选用这一交界区.此外,随着硅膜厚度的减小,器件的泄漏电流随着沟道掺杂浓度的不同,有一个极小值.通过模拟分析发现,只要合理选择器件的结构参数,就能得到性能优良的SOI器件.     

亚100nm SOI器件的结构优化分析

分析了SOI器件各结构参数对器件性能的影响,给出了器件各结构参数的优化方向,找出了可行硅膜厚度和可行沟道掺杂浓度之间的设计容区.在部分耗尽与全耗尽SOI器件的交界处,阈值电压的漂移有一个峰值,在器件设计时应避免选用这一交界区.此外,随着硅膜厚度的减小,器件的泄漏电流随着沟道掺杂浓度的不同,有一个极小值.通过模拟分析发现,只要合理选择器件的结构参数,就能得到性能优良的SOI器件     

短沟道SOI MOSFET栅结构研究与进展

系统比较了几种不同栅结构短沟道SOI MOSFET的性能,包括短沟道效应、电流驱动能力、器件尺寸等特性,获得了栅的数目与短沟道SOI器件的性能成正比的结论.介绍了两种新的短沟道SOI器件栅结构:Π栅和Ω栅,指出了短沟道SOI MOSFET栅结构的发展方向.     

SiGe SOI CMOS特性分析与优化设计

基于全耗尽SOI CMOS工艺，建立了具有SiGe沟道的SOI MOS器件结构模型，并利用ISE TCAD器件模拟软件，对SiGe SOl CMOS的电学特性进行模拟分析。结果表明，引入SiGe沟道可极大地提高PMOS的驱动电流和跨导（当Ge组分为0．3时，驱动电流提高39．3％，跨导提高38．4％），CMOS电路的速度显著提高；在一定的Ge总量下，改变Ge的分布，当沟道区呈正向递减式分布时，电路速度最快。     

具有T型电荷补偿区的横向超结SOILDMOS

非平衡超结器件的电荷补偿能力在薄层SOI器件中受到限制,文中提出一种具有T型电荷补偿区的器件结构。通过漏端刻蚀的PSOI结构使硅衬底与埋氧层同时参与纵向耐压,可以提高非平衡超结n区的电荷补偿能力;在埋氧层刻蚀区增加垂直的n型补偿区,弥补埋氧层的缺失。由横向的非平衡超结n区和漏端垂直的n区共同构成T型补偿区,可以有效缓解薄层SOI超结器件中的衬底辅助耗尽效应,优化横向电场,提高器件的耐压。器件的制作可以通过改进传统的PSOI工艺实现,应用于SOI功率集成电路。三维器件仿真结果表明,新结构下的器件耐压达到290V,相对于常规的SOI超结器件和非平衡超结器件提高了267%和164%。     

SOI器件中瞬态浮体效应的模拟与分析

针对 SOI器件中的瞬态浮体效应进行了一系列的数值模拟 ,通过改变器件参数 ,比较系统地考察了 SOI器件中瞬态浮体效应 ,同时也研究和分析了瞬态浮体效应对 CMOS/SOI电路 (以环振电路为例 )的影响 ,并提出了抑制器件浮体效应的器件结构和参数优化设计 .     

A novel nanoscale SOI MOSFET with Si embedded layer as an effective heat sink

A novel structure such as nanoscale silicon-on-insulator (SOI) MOSFET with silicon embedded layer (SEL-SOI) is proposed to reduce self-heating effects (SHEs) successfully. The SEL as a useful heat sink with high thermal conductivity is inserted inside the buried oxide. The SEL acts like a heat sink and is therefore easily able to distribute the lattice heat throughout the device. We noticed excellent improvement in the thermal performance of the device using two-dimensional and two-carrier device simulation. Our simulation results show that SHE has been dramatically reduced in the proposed structure. In regard to the simulated results, the SEL-SOI structure has shown good performance in comparison with the conventional SOI (C-SOI) structure when utilised in the high temperature applications.     

抑制浮体效应的薄膜SOI LDMOS

A novel CMOS-compatible thin film SOI LDMOS with a novel body contact structure is proposed. It has a Si window and a P-body extended to the substrate through the Si window, thus, the P-body touches the PC region to form the body contact. Compared with the conventional floating body SOI LDMOS(FB SOI LDMOS) structure, the new structure increases the off-state BV by 54%, decreases the specific on resistance by 20%, improves the output characteristics significantly, and suppresses the self-heating effect. Furthermore, the advantages of the low leakage current and low output capacitance of SOI devices do not degrade.     

A novel SOI-MESFET with symmetrical oxide boxes at both sides of gate and extended drift region into the buried oxide

In this paper a novel structure for silicon on insulator metal semiconductor field effect transistors (SOI MESFETs) is proposed. The proposed structure contains two symmetrical oxide boxes at both sides of gate metal and extended drift region into the buried oxide which is named SO-ED-SOI-MESFET. SO-ED stands for symmetrical oxide boxes and extended drift region. DC and radio frequency characteristics of the SO-ED are analyzed by 2-D numerical simulation and compared with conventional SOI MESFET (C-SOI MESFET) characteristics. The obtained results demonstrate the superiorities of the proposed structure over C-SOI MESFET including increased breakdown voltage, higher driving current and improved RF characteristics. The extended drift region improves the current capability by increasing the effective channel thickness. The oxide region boosts the breakdown voltage due to its high tolerable electric field. Also, RF performance of the device is enhanced because of modified gate-source and gate-drain capacitances in the proposed structure. Unilateral power gain, maximum available gain and current gain experience 63, 52 and 63.5% improvement by applying the proposed structure, respectively. Thus the proposed structure can be considered as a proper candidate for using in high power and high frequency applications.     

SOI铁电负电容晶体管亚阈值特性研究

随着微电子技术进入纳米领域,功耗成为制约技术发展的主要因素,因此,低功耗器件成为半导体器件领域的研究热点。负电容场效应晶体管基于铁电材料的负电容效应可有效地降低器件的亚阈值摆幅,从而降低器件的功耗。该文设计了一种基于绝缘体上硅(SOI)结构的铁电负电容场效应晶体管,利用TCAD Sentaurus仿真工具对负电容晶体管进行仿真研究,得到了亚阈值摆幅为30.931 mV/dec的负电容场效应晶体管的器件结构和参数。最后仿真研究了铁电层厚度、等效栅氧化层厚度对负电容场效应晶体管亚阈值特性的影响。     

Creation of a new high voltage device with capable of enhancing driving current and breakdown voltage

This work reports a novel SOI MESFET including silicon N-type and P-type wells inside the drift and buried oxide regions. The drift-diffusion equations along with the main physical models such as impact ionization, Shockley-Read-Hall and self-heating effect are carefully solved inside the structures. Modification of the potential profile occurs in the channel region and results in decrease in peak electric field. Output power density is successfully boosted owing to improved driving current and breakdown voltage, simultaneously. In addition, self-heating effect is alleviated in the proposed structure due to decreased effective thermal resistance of the channel region. Comprehensive DC and AC performance comparisons show that the proposed device promises a more reliable candidate than the conventional SOI structure for high voltage applications.     

Patterned silicon-on-insulator technology for RF Power LDMOSFET

This paper presents the first results of a practical SOI LDMOSFET in patterned SOI substrate that has been successfully prepared by masked SIMOX method. The device exhibits good electrical performance including a leakage current of 20 nA, the flat output characteristic curves, a cutoff frequency up to 8 GHz, and a voltage gain of 2.5 dB at 2 GHz. The proposed technology not only suppresses floating body effects effectively but also preserves SOI technology’s advantage of low power assumption. Moreover, the process is compatible with conventional SOI technology.