Early effect modeling of silicon-on-insulator SiGe heterojunction bipolar transistors

Silicon germanium(SiGe) heterojunction bipolar transistor(HBT) on thin silicon-on-insulator(SOI) has recently been demonstrated and integrated into the latest SOI BiCMOS technology.The Early effect of the SOI SiGe HBT is analysed considering vertical and horizontal collector depletion,which is different from that of a bulk counterpart.A new compact formula of the Early voltage is presented and validated by an ISE TCAD simulation.The Early voltage shows a kink with the increase of the reverse base-collector bias.Large differences are observed between SOI devices and their bulk counterparts.The presented Early effect model can be employed for a fast evaluation of the Early voltage and is useful to the design,the simulation and the fabrication of high performance SOI SiGe devices and circuits.     

Weak avalanche multiplication in SiGe heterojunction bipolar transistors on thin film silicon-on-insulator

In this paper, we propose an analytical avalanche multiplication model for the next generation of SiGe silicon-on-insulator (SOI) heterojunction bipolar transistors (HBTs) and consider their vertical and lateral impact ionizations for the first time. Supported by experimental data, the analytical model predicts that the avalanche multiplication governed by impact ionization shows kinks and the impact ionization effect is small compared with that of the bulk HBT, resulting in a larger base-collector breakdown voltage. The model presented in the paper is significant and has useful applications in the design and simulation of the next generation of SiGe SOI BiCMOS technology.     

Substrate bias effects on collector resistance in SiGe heterojunction bipolar transistors on thin film silicon-on-insulator

An analytical expression for the collector resistance of a novel vertical SiGe heterojunction bipolar transistor(HBT) on thin film silicon-on-insulator(SOI) is obtained with the substrate bias effects being considered.The resistance is found to decrease slowly and then quickly and to have kinks with the increase of the substrate-collector bias,which is quite different from that of a conventional bulk HBT.The model is consistent with the simulation result and the reported data and is useful to the frequency characteristic design of 0.13 μm millimeter-wave SiGe SOI BiCMOS devices.     

Comparison of total dose effects on SiGe heterojunction bipolar transistors induced by different swift heavy ion irradiation

The degradations in NPN silicon-germanium （SiGe） heterojunction bipolar transistors （HBTs） were fully studied in this work, by means of 25-MeV Si, 10-MeV C1, 20-MeV Br, and 10-MeV Br ion irradiation, respectively. Electrical parameters such as the base current （IB）, current gain （β）, neutral base recombination （NBR）, and Early voltage （VA） were investigated and used to evaluate the tolerance to heavy ion irradiation. Experimental results demonstrate that device degradations are indeed radiation-source-dependent, and the larger the ion nuclear energy loss is, the more the displacement damages are, and thereby the more serious the performance degradation is. The maximum degradation was observed in the transistors irradiated by 10-MeV Br. For 20-MeV and 10-MeV Br ion irradiation, an unexpected degradation in Ic was observed and Early voltage decreased with increasing ion fluence, and NBR appeared to slow down at high ion fluence. The degradations in SiGe HBTs were mainly attributed to the displacement damages created by heavy ion irradiation in the transistors. The underlying physical mechanisms are analyzed and investigated in detail.     

含有本征SiGe层的SiGe异质结双极晶体管集电结耗尽层宽度模型

本文分别建立了含有本征SiGe层的SiGe HBT(异质结双极晶体管)集电结耗尽层各区域的电势、电场分布模型,并在此基础上,建立了集电结耗尽层宽度和延迟时间模型,对该模型进行了模拟仿真,定量地分析了SiGe HBT物理、电学参数对集电结耗尽层宽度和延迟时间的影响,随着基区掺杂浓度和集电结反偏电压的提高,集电结耗尽层延迟时间也随之增大,而随着集电区掺杂浓度的提高和基区Ge组分增加,集电结耗尽层延迟时间随之减小. 关键词： SiGe HBT 集电结耗尽层 延迟时间     

锗硅异质结双极晶体管单粒子效应加固设计与仿真

本文设计了一种通过在版图布局中引入伪集电极的方法来提高锗硅异质结双极晶体管(SiGe HBT)抗单粒子性能的方法. 利用半导体器件模拟工具, 针对加固前后的SiGe HBT开展了单粒子效应仿真模拟, 分析了伪集电极对SiGe HBT电荷收集机理的影响. 结果表明, 引入的伪集电极形成的新的集电极-衬底结具有较大的反偏能力, 加固后SiGe HBT伪集电极通过扩散机理, 大量收集单粒子效应产生的电荷, 有效地减少了实际集电极的电荷收集量, 发射极、基极电荷收集量也有不同程度的降低, 加固设计后SiGe HBT 的单粒子效应敏感区域缩小, 有效的提高了SiGe HBT 器件抗单粒子效应辐射性能. 此项工作的开展为SiGe HBT电路级单粒子效应抗辐射加固设计打下良好的基础.     

不同偏置影响锗硅异质结双极晶体管单粒子效应的三维数值仿真研究

针对国产锗硅异质结双极晶体管(SiGe HBT),采用半导体器件三维计算机模拟工具,建立单粒子效应三维损伤模型,研究不同偏置状态对SiGe HBT单粒子效应的影响.分析比较不同偏置下重离子入射器件后,各端口电流瞬变峰值和电荷收集量随时间的变化关系,获得SiGe HBT单粒子效应与偏置的响应关系.结果表明:不同端口对单粒子效应响应的最劣偏置不同,同一端口电荷收集量和瞬变电流峰值的最劣偏置也有所差异.载流子输运方式变化和外加电场影响是造成这种现象的主要原因.     

重离子导致的锗硅异质结双极晶体管单粒子效应电荷收集三维数值模拟

针对国产锗硅异质结双极晶体管(SiGe HBTs), 采用半导体器件模拟工具, 建立SiGe HBT单粒子效应三维损伤模型, 研究影响SiGe HBT单粒子效应电荷收集的关键因素. 分析比较重离子在不同位置入射器件时, 各电极的电流变化和感生电荷收集情况, 确定SiGe HBT电荷收集的敏感区域. 结果表明, 集电极/衬底结内及附近区域为集电极和衬底收集电荷的敏感区域, 浅槽隔离内的区域为基极收集电荷的敏感区域, 发射极收集的电荷可以忽略. 此项工作的开展为下一步采用设计加固的方法提高器件的抗辐射性能打下了良好的基础. 关键词： 锗硅异质结双极晶体管 单粒子效应 电荷收集 三维数值仿真     

Ge组分分布对基区杂质非均匀分布的SiGe HBT温度特性的影响

众所周知, 双极型晶体管的设计主要是基区的设计. 一般而言, 基区的杂质分布是非均匀的. 本文首先研究了非均匀的杂质高斯分布对器件温度分布、增益和截止频率的温度特性的影响, 发现增益和截止频率具有正温度系数, 体内温度较高. 随后研究了基区Ge组分分布对这些器件参数的影响. 均匀Ge组分分布和梯形Ge组分分布的SiGe 异质结双极型晶体管增益和截止频率具有负温度系数, 具有较好的体内温度分布. 进一步的研究表明, 具有梯形Ge组分分布的SiGe 异质结双极型晶体管, 由于Ge组分缓变引入了少子加速电场, 不但使它的增益和截止频率具有较高的值, 而且保持了较弱的温度敏感性, 在增益、特征频率大小及其温度敏感性、体内温度分布达到了很好的折中.     

锗硅异质结晶体管单粒子效应激光微束模拟

对国产锗硅异质结双极晶体管(SiGe HBT)进行了单粒子效应激光微束辐照试验,观测SiGe HBT单粒子效应的敏感区域,测试不同外加电压和不同激光能量下SiGe HBT集电极瞬变电流和电荷收集情况,并结合器件结构对试验结果进行分析。试验结果表明：国产SiGe HBT位于集电极/衬底结内的区域对单粒子效应敏感,波长为1064 nm的激光在能量约为1.5 nJ时诱发SiGe HBT单粒子效应,引起电流瞬变。入射激光能量增强,电流脉冲增大,电荷收集量增加;外加电压增大,电流脉冲的波峰增大;SiGe HBT的单粒子效应与外加电压大小和入射激光能量都相关,电压主要影响瞬变电流的峰值,而电荷收集量主要依赖于入射激光能量。     

Analytical base–collector depletion capacitance in vertical SiGe heterojunction bipolar transistors fabricated on CMOS-compatible silicon on insulator

The base--collector depletion capacitance for vertical SiGe npn heterojunction bipolar transistors (HBTs) on silicon on insulator (SOI) is split into vertical and lateral parts. This paper proposes a novel analytical depletion capacitance model of this structure for the first time. A large discrepancy is predicted when the present model is compared with the conventional depletion model, and it is shown that the capacitance decreases with the increase of the reverse collector--base bias--and shows a kink as the reverse collector--base bias reaches the effective vertical punch-through voltage while the voltage differs with the collector doping concentrations, which is consistent with measurement results. The model can be employed for a fast evaluation of the depletion capacitance of an SOI SiGe HBT and has useful applications on the design and simulation of high performance SiGe circuits and devices.     

SOI SiGe HBT电学性能研究

研究了SOI衬底上SiGe npn异质结晶体管的设计优化.给出了器件基本直流交流特性曲线,分析了与常规SiGeHBT的不同.由于SOI衬底的引入使SOI SiGe HBT成为四端器件,重点研究了衬底偏压对Gummel曲线、输出特性曲线以及雪崩电流的影响.最后仿真实现材料物理参数和几何物理参数对频率特性的改变.结果表明SOI SiGeHBT与常规器件相比具有更大的设计自由度.SOI SiGe HBT的系统分析为毫米波SOI SiGe BiCMOS电路的设计提供了有价值的参考.     

不同剂量率下锗硅异质结双极晶体管电离损伤效应研究

对于相同制作工艺的NPN锗硅异质结双极晶体管(SiGe HBT), 在不同辐照剂量率下进行⁶⁰Co γ射线的辐照效应与退火特性的研究. 测量结果表明, 两种辐照剂量率下, 随着辐照总剂量增加, 晶体管基极电流增大, 共发射极电流放大倍数降低, 且器件的辐照损伤、性能退化与辐照剂量率相关, 低剂量率下辐照损伤较高剂量率严重. 在经过与低剂量率辐照等时的退火后, 高剂量率下的辐照损伤仍较低剂量率下的损伤低, 即待测SiGeHBT具有明显的低剂量率损伤增强效应(ELDRS). 本文对相关的物理机理进行了探讨分析. 关键词： 锗硅异质结双极晶体管 低剂量率辐照损伤增强 辐照效应     

Angular dependence of proton-induced single event transient in silicon-germanium heterojunction bipolar transistors

We investigate the angular dependence of proton-induced single event transient (SET) in silicon-germanium heterojunction bipolar transistors. Experimental results show that the overall SET cross section is almost independent of proton incident angle. However, the proportion of SET events with long duration and high integral charge collection grows significantly with the increasing angle. Monte Carlo simulations demonstrate that the integral cross section of proton incident events with high ionizing energy deposition in the sensitive volume tends to be higher at larger incident angles, which is associated with the angular distribution of proton-induced secondary particles and the geometry of sensitive volume.     

Designing power heterojunction bipolar transistors with non-uniform emitter finger lengths to achieve high thermal stability

With the aid of a thermal-electrical model,a practical method for designing multi-finger power heterojunction bipolar transistors with finger lengths divided in groups is proposed.The method can effectively enhance the thermal stability of the devices without sacrificing the design time.Taking a 40-finger heterojunction bipolar transistor for example,the device with non-uniform emitter finger lengths is optimized and fabricated.Both the theoretical and the experimental results show that,for the optimum device,the peak temperature is lowered by 26.19 K and the maximum temperature difference is reduced by 56.67% when compared with the conventional heterojunction bipolar transistor with uniform emitter finger length.Furthermore,the ability to improve the uniformity of the temperature profile and to expand the thermal stable operation range is strengthened as the power level increases,which is ascribed to the improvement of the thermal resistance in the optimum device.A detailed design procedure is also summarized to provide a general guide for designing power heterojunction bipolar transistors with non-uniform finger lengths.     

Thermal resistance matrix representation of thermal effects and thermal design in multi-finger power heterojunction bipolar transistors

The thermal resistance matrix including self-heating thermal resistance and thermal coupling resistance is presented to describe the thermal effects of multi-finger power heterojunction bipolar transistors. The dependence of thermal resistance matrix on finger spacing is also investigated. It is shown that both self-heating thermal resistance and thermal coupling resistance are lowered by increasing the finger spacing, in which the downward dissipated heat path is widened and the heat flow from adjacent fingers is effectively suppressed. The decrease of self-heating thermal resistance and thermal coupling resistance is helpful for improving the thermal stability of power devices. Furthermore, with the aid of the thermal resistance matrix, a 10-finger power heterojunction bipolar transistor (HBT) with non-uniform finger spacing is designed for high thermal stability. The optimized structure can effectively lower the peak temperature while maintaining a uniformity of the temperature profile at various biases and thus the device effectively may operate at a higher power level.     

一种InP双异质结双极晶体管小信号物理模型及其提取方法

研究了InP双异质结双极晶体管（DHBT）的能带结构对集电极电容的影响,解决了传统方法不能准确提取InP DHBT集电极电容的问题.考虑了基极-发射极和集电极-发射极引线间的交叠电容,并从物理上区分了InP DHBT的本征电阻、外部电阻与寄生电阻,建立了一个基于物理的InP基DHBT小信号模型.同时提出了一套直接提取模型参数的方法,该方法无需引入数学优化,具有清晰的物理意义.提取的结果在很宽的偏置范围内准确地拟合了器件特性,验证了模型的准确性与提取方法的有效性. 关键词： InP双异质结双极晶体管 集电极电容 小信号模型 参数提取     

新型宽温区高热稳定性微波功率SiGe 异质结双极晶体管

宽温区大电流下的热不稳定性严重制约着功率SiGe 异质结双极晶体管 (HBT) 在射频和微波电路中的应用.为改善器件的热不稳定性, 本文利用SILVACO TCAD建立的多指功率SiGe HBT模型, 分析了器件纵向结构中基区Ge组分分布对微波功率SiGe HBT电学特性和热学特性的影响. 研究表明, 对于基区Ge组分为阶梯分布的HBT, 由于Ge组分缓变引入了少子加速电场, 使它与均匀基区Ge组分HBT相比, 具有更高的特征频率f_T, 且电流增益β和f_T随温度变化变弱, 这有利于防止器件在宽温区工作时电学特性的漂移.同时, 器件整体温度有所降低, 但器件各指温度分布均匀性较差.考虑多指HBT各发射极指散热能力存在差异, 在器件纵向结构设计为基区Ge组分阶梯分布的同时, 对其横向版图进行发射极指间距渐变结构设计, 用于改善器件各指温度分布的均匀性, 进而提高HBT的热稳定性.结果表明, 与基区Ge组分为均匀分布的等发射极指间距结构HBT相比, 新器件各指温度分布均匀性明显改善, f_T保持了较高的值, 且β和f_T 随温度变化不敏感, 热不稳定性得到显著改善, 显示了新器件在宽温区大电流下工作的优越性. 关键词： SiGe 异质结双极晶体管 Ge组分分布 发射极指间距渐变技术 热稳定性     

伽玛辐照对SiGe异质结双极型晶体管的集电极电流和厄尔利电压的影响

 研究了伽玛辐照效应对SiGe异质结双极型晶体管的集电极电流和厄尔利电压的影响。经过10⁴ Gy的伽玛总剂量辐照后,集电极电流和厄尔利电压均增加。另外,辐照后发射结和极电结的开启电压和击穿电压也均有一定程度的减小。以上这些变化均是由于辐照产生的缺陷引起发射区和集电区有效掺杂浓度减小所致。     

伽玛辐照对SiGe异质结双极型晶体管的集电极电流和厄尔利电压的影响

研究了伽玛辐照效应对SiGe异质结双极型晶体管的集电极电流和厄尔利电压的影响。经过104 Gy的伽玛总剂量辐照后,集电极电流和厄尔利电压均增加。另外,辐照后发射结和极电结的开启电压和击穿电压也均有一定程度的减小。以上这些变化均是由于辐照产生的缺陷引起发射区和集电区有效掺杂浓度减小所致。