Effect of bias condition on heavy ion radiation in bipolar junction transistor

The characteristic degradations in silicon NPN bipolar junction transistor (BJT) of 3DG142 type are examined under the irradiation with 40-MeV chlorine (Cl) ions under forward, grounded, and reverse bias conditions, respectively. Different electrical parameters are in-situ measured during the exposure under each bias condition. From the experimental data, larger variation of base current (I_B) is observed after irradiation at a given value of base-emitter voltage (V_BE), while the collector current is slightly affected by irradiation at a given V_BE. The gain degradation is affected mostly by the behaviour of the base current. From the experimental data, the variation of current gain in the case of forward bias is much smaller than that in the other conditions. Moreover, for 3DG142 BJT, the current gain degradation in the case of reverse bias is more severe than that in the grounded case at low fluence, while at high fluence, the gain degradation in the reverse bias case becomes smaller than that in the grounded case.     

Incident particle range dependence of radiation damage in a power bipolar junction transistor

The characteristic degradations in silicon NPN bipolar junction transistors(BJTs) of type 3DD155 are examined under the irradiations of 25-MeV carbon(C),40-MeV silicon(Si),and 40-MeV chlorine(Cl) ions respectively.Different electrical parameters are measured in-situ during the exposure of heavy ions.The experimental data shows that the changes in the reciprocal of the gain variation((1/β)) of 3DD155 transistors irradiated respectively by 25-MeV C,40-MeV Si,and 40-MeV Cl ions each present a nonlinear behaviour at a low fluence and a linear response at a high fluence.The(1/β) of 3DD155 BJT irradiated by 25-MeV C ions is greatest at a given fluence,a little smaller when the device is irradiated by 40-MeV Si ions,and smallest in the case of the 40-MeV Cl ions irradiation.The measured and calculated results clearly show that the range of heavy ions in the base region of BJT affects the level of radiation damage.     

基区表面势对栅控横向PNP晶体管中子位移损伤的影响

通过在常规横向PNP晶体管基区表面氧化层上淀积栅电极,制作了可以利用栅极偏置调制基区表面势的栅控横向PNP晶体管。对无栅极偏置电压和偏置电压分别为-10V和10V的栅控横向PNP晶体管,在西安脉冲反应堆上开展注量为2×1012,4×1012,6×1012,8×1012,1×1013 cm-2的中子辐照实验,研究基区表面势的增加和降低对栅控横向PNP晶体管中子位移损伤退化特性的影响。研究结果表明,基区表面势的增加引起栅控横向PNP晶体管共射极电流增益倒数的变化量随辐照中子注量的退化速率增加,基区表面势的降低对位移损伤退化速率无明显影响。     

偏置条件对NPN及PNP双极晶体管电离辐射损伤的影响研究

本文采用低能电子辐照源对NPN及PNP晶体管进行辐照试验. 在辐照试验过程中, 针对NPN及PNP晶体管发射结施加不同的偏置条件, 研究偏置条件对NPN及PNP晶体管辐射损伤的影响. 使用Keithley 4200-SCS半导体特性测试仪在原位条件下测试了双极晶体管电性能参数随低能电子辐照注量的变化关系. 测试结果表明, 在相同的辐照注量条件下, 发射结反向偏置时双极晶体管的辐照损伤程度最大; 发射结正向偏置时双极晶体管的辐照损伤程度最小; 发射结零偏时双极晶体管的辐照损伤程度居于上述情况之间. 关键词： 双极晶体管 低能电子 电离辐射     

氢气浸泡辐照加速方法在3DG111器件上的应用及辐射损伤机理分析

本文以~(60)Co为辐照源,针对3DG111型晶体管,利用半导体参数分析仪和深能级缺陷瞬态谱仪,研究高/低剂量率和有/无氢气浸泡条件下,电性能和深能级缺陷的演化规律.试验结果表明,与高剂量率辐照相比,低剂量率辐照条件下,3DG111型晶体管的电流增益退化更加严重,这说明该器件出现了明显的低剂量率增强效应;无论是高剂量率还是低剂量率辐照条件下,3DG111晶体管的辐射损伤缺陷均是氧化物正电荷和界面态陷阱,并且低剂量率条件下,缺陷能级较深;氢气浸泡后在高剂量率辐照条件下,与未进行氢气处理的器件相比,辐射损伤程度明显加剧,且与低剂量率辐照条件下器件的损伤程度相同,缺陷数量、种类及能级也相同.因此,氢气浸泡处理可以作为低剂量率辐射损伤增强效应加速评估方法的有效手段.     

170 keV Proton radiation effects on low-frequency noise of bipolar junction transistors

In this paper, the electrical properties and low-frequency noise for bipolar junction transistors irradiated by 170?keV proton are examined. The result indicates that for the sample under proton irradiation with fluence 1.25?×?10^14?p/cm², base current I_B in low bias range (V_BE < 0.7?V) increases due to superimposition of radiation-induced recombination current, while the gain decreases significantly. Meanwhile, the low-frequency noise increases in the proton-irradiated sample. By analysis of evolution of parameters extracted from low-frequency noise power spectra, it is demonstrated that radiation-induced noise is mainly originated from carrier fluctuation modulated by generation–recombination centers (G–R centers) located at the interface of Si/SiO₂, which are introduced by proton-radiation-induced defects. It is also confirmed that the electrical properties and noise behavior of irradiated sample are mostly affected by the carrier recombination process caused by G–R centers at the interface of Si/SiO₂ than by G–R centers in EB junctions.     

Two-dimensional analysis of the interface states effects on current gain for 4H－SiC bipolar junction transistor

This paper studies two-dimensional analysis of the surface state effect on current gain for a 4H--SiC bipolar junction transistor (BJT). Simulation results indicate the mechanism of current gain degradation, which is surface Fermi level pinning leading to a strong downward bending of the energy bands to form the channel of surface electron recombination current. The experimental results are well-matched with the simulation, which is modeled by exponential distributions of the interface state density replacing the single interface state trap. Furthermore, the simulation reveals that the oxide quality of the base emitter junction interface is very important for 4H--SiC BJT performance.     

Two-dimensional analysis of the interface state effect on current gain for a 4H-SiC bipolar junction transistor

This paper studies two-dimensional analysis of the surface state effect on current gain for a 4H-SiC bipolar junction transistor (BJT).Simulation results indicate the mechanism of current gain degradation,which is surface Fermi level pinning leading to a strong downward bending of the energy bands to form the channel of surface electron recombination current.The experimental results are well-matched with the simulation,which is modeled by exponential distributions of the interface state density replacing the single interface state trap.Furthermore,the simulation reveals that the oxide quality of the base emitter junction interface is very important for 4H-SiC BJT performance.     

Ni/4H-SiC肖特基势垒二极管的γ射线辐照效应

对制备的Ni/4H-SiC肖特基势垒二极管（SBD）进行了γ射线辐照试验,并在辐照过程中对器件分别加0和-30?V偏压.经过1?Mrad（Si）总剂量的γ射线辐照后,不同辐照偏压下的Ni/4H-SiC肖特基接触的势垒高度和理想因子没有退化,SiC外延层中的少子寿命也没有退化.辐照后器件的反向电流下降,这是由于器件表面的负界面电荷增加引起的.研究表明,辐照偏压对Ni/4H-SiC SBD的辐照退化效应没有明显的影响. 关键词： 碳化硅 肖特基 辐照效应 偏压     

Simulation of energy and fluence dependence of heavy ion induced displacement damage factor in bipolar junction transistor

This article presents the theoretical calculation of the variation of displacement damage factors as a function of energy and rad equivalent fluence in bipolar junction transistor for various particulate radiation viz., He, Si, Cl, Ti, Ni, Br, Ag, I, and Au. The calculation is based on the experimental data on γ-ray induced gain degradation in a commercial space borne BJT (2N3019). The method involves the calculation of γ-ray dose (rad(Si)) equivalent of effective particle fluence. The linear energy transfer (LET) in silicon for different particle radiation obtained from TRIM calculation has been used for the conversion of γ-dose into fluence of various particles. The estimation predicts a smooth increase in the displacement damage factor as the mass of the ion increases. Further, the displacement damage factor reaches a maximum at the same value of energy, which corresponds to maximum LET for all heavy ions. The maximum value of damage factor marginally decreases with increasing ion fluence for an ion of given energy. The results are compared with the data available in the literature for proton, deuteron, and helium induced displacement damage.     

GaInP/GaAs/Ge三结太阳电池不同能量质子辐照损伤模拟

以GaInP/GaAs/Ge三结太阳电池为研究对象,开展了能量为0.7, 1, 3, 5, 10 MeV的质子辐照损伤模拟研究,建立了三结太阳电池结构模型和不同能量质子辐照模型,获得了不同质子辐照条件下的I-V曲线,光谱响应曲线,结合已有实验结果验证了本文模拟结果,分析了三结太阳电池短路电流、开路电压、最大功率、光谱响应随质子能量的变化规律,利用不同辐照条件下三结太阳电池最大输出功率退化结果,拟合得到了三结太阳电池最大输出功率随位移损伤剂量的退化曲线.研究结果表明,质子辐照会在三结太阳电池中引入位移损伤缺陷,使得少数载流子扩散长度退化幅度随质子能量的减小而增大,从而导致三结太阳电池相关电学参数的退化随质子能量的减小而增大.相同辐照条件下,中电池光谱响应退化幅度远大于顶电池光谱响应退化幅度,中电池抗辐照性能较差,同时中电池长波范围内光谱响应的退化幅度比短波范围更大,表明中电池相关电学参数的退化主要来源于基区损伤.     

基极注入强电磁脉冲对双极晶体管的损伤效应和机理

建立了双极晶体管(BJT)在强电磁脉冲作用下的二维电热模型, 对处于有源放大区的BJT在基极注入强电磁脉冲时的瞬态响应进行了仿真. 结果表明, BJT烧毁点位置随注入脉冲幅度变化而变化, 低脉冲幅度下晶体管烧毁是由发射结反向雪崩击穿所致, 烧毁点位于发射结柱面区; 而在高脉冲幅度下, 由基区-外延层-衬底组成的p-n-n⁺ 二极管发生二次击穿导致靠近发射极一侧的基极边缘率先烧毁; BJT的烧毁时间随脉冲幅度升高而减小, 而损伤能量则随之呈现减小-增大-减小的变化趋势, 因而存在一个极小值和一个极大值. 仿真与实验结果的比较表明, 本文建立的晶体管模型不但能预测强电磁脉冲作用下BJT内部烧毁发生的位置, 而且能够得到损伤能量. 关键词： 双极晶体管 强电磁脉冲 烧毁点位置 损伤能量     

双极型晶体管损坏与强电磁脉冲注入位置的关系

 利用时域有限差分法，对双极型晶体管(BJT)在强电磁脉冲作用下的瞬态响应进行了2维数值模拟，研究了电磁脉冲从不同极板注入时BJT的响应情况，根据温度分布的集中程度分析了发生烧毁的难易程度。模拟得出：发射极注入最容易导致烧毁，集电极注入次之，基极注入相对不易导致烧毁；发射极注入烧毁所消耗能量随着脉冲电压上升而下降，到30 V以后基本与电压的升高无关，集电极注入烧毁所消耗的能量则随着电压上升而上升，到100 V以后由于BE结上热点的出现而开始下降。     

GaN基p-i-n型雪崩探测器的制备与表征

制备和表征了p-i-n型的GaN基雪崩探测器.器件在-5V下的暗电流约为0.05 nA,-20 V下的暗电流小于0.5 nA.响应增益-偏压曲线显示,可重复的雪崩增益起始于80 V附近,在85 V左右增益达到最大为120,表明所制备的器件具有较好的质量.C-V测量用来确定载流子的分布和耗尽信息,结果显示,P型层在15 ...     

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.     

电子辐照下GaAs/Ge太阳电池载流子输运机理研究

通过地面模拟辐照试验获得不同能量电子辐照下GaAs/Ge太阳电池电学参数退化的基本规律, 在此基础上使用PC1 D模拟程序分析太阳电池内部的载流子输运机理, 建立不同能量的电子辐照下GaAs/Ge太阳电池中多数载流子浓度和少数载流子扩散长度随辐照粒子注量变化的基本规律. 研究结果表明: 多数载流子浓度和少数载流子扩散长度均随入射电子注量的增大而减小, 多数载流子去除率和少数载流子扩散长度损伤系数均随电子能量的增高而增大, 多数载流子去除效应和少数载流子扩散长度缩短分别是电池开路电压和短路电流退化的主要原因.     

双极晶体管中子注量探测器的标定

双极晶体管经中子辐照后会引起直流增益退化,在109~1016 cm-2的注量范围内,其直流增益倒数变化与辐照中子注量呈线性关系。对直流增益退化的双极晶体管进行高温退火,能使受到辐射损伤的双极晶体管性能恢复。鉴于此,将双极晶体管进行逆向工程应用,制作成中子注量探测器,经标定后,可实现对中子注量的监测。对探测器的装配结构进行设计后,依托中国工程物理研究院快中子脉冲堆(CFBR-Ⅱ),在1012~1013 cm-2的注量范围对3DK2222A型探测器和在1013 cm-2的注量范围对3DG121C型探测器进行标定。在得到探测器损伤常数K的分散性存在较小和较大的两种情况下,确定了分散性较小时的有效取值和应用方法,以及在分散性较大时,采取标定的损伤常数K只能应用在同只探测器上的方案,并通过高温退火实验证实了该方案的可行性。     

双极型晶体管高功率微波的损伤机理

在模拟集成电路的抗高功率微波加固研究中,对电路中的单个晶体管进行高功率微波损伤机理研究。对晶体管进行洲入微波损伤效应实验和失效分析,得到了双极型晶体管损伤的基本规律。损伤效应实验采用注入法,分别从晶体管的三极注入微波,得到了损伤结果。对样品进行的失效分析探明了器件的损伤部位和失效机理。结果表明,高功率微波注入主要造成B-E结的退化和损伤;从基极注入微波最易损伤晶体管,而从集电极注入则相反。     

Degradation mechanisms of current gain in NPN transistors

An investigation of ionization and displacement damage in silicon NPN bipolar junction transistors (BJTs) is presented. The transistors were irradiated separately with 90-keV electrons, 3-MeV protons and 40-MeV Br ions. Key parameters were measured {\em in-situ} and the change in current gain of the NPN BJTS was obtained at a fixed collector current (I_{\rm c}=1~mA). To characterise the radiation damage of NPN BJTs, the ionizing dose D_{\i} and displacement dose D_{\d} as functions of chip depth in the NPN BJTs were calculated using the SRIM and Geant4 code for protons, electrons and Br ions, respectively. Based on the discussion of the radiation damage equation for current gain, it is clear that the current gain degradation of the NPN BJTs is sensitive to both ionization and displacement damage. The degradation mechanism of the current gain is related to the ratio of D_{\rm d}/(D_{\rm d}+D_{\rm i}) in the sensitive region given by charged particles. The irradiation particles leading to lower D_{\rm d}/(D_{\rm d}+D_{\rm i}) within the same chip depth at a given total dose would mainly produce ionization damage to the NPN BJTs. On the other hand, the charged particles causing larger D_{\rm d}/(D_{\rm d}+D_{\rm i}) at a given total dose would tend to generate displacement damage to the NPN BJTs. The Messenger--Spratt equation could be used to describe the experimental data for the latter case.     

Study on the bias-dependent effects of proton-induced damage in CdZnTe radiation detectors using ion beam induced charge microscopy

The influence of damage induced by 2 MeV protons on CdZnTe radiation detectors is investigated using ion beam induced charge (IBIC) microscopy. Charge collection efficiency (CCE) in irradiated region is found to be degraded above a fluence of 3.3 × 10¹¹ p/cm² and the energy spectrum is severely deteriorated with increasing fluence. Moreover, CCE maps obtained under the applied biases from 50 V to 400 V suggests that local radiation damage results in significant degradation of CCE uniformity, especially under low bias, i. e., 50 V and 100 V. The CCE nonuniformity induced by local radiation damage, however, can be greatly improved by increasing the detector applied bias. This bias-dependent effect of 2 MeV proton-induced radiation damage in CdZnTe detectors is attributed to the interaction of electron cloud and radiation-induced displacement defects.