阶梯栅氧结构的NLDMOS热载流子效应研究

本文对一种新型的阶梯栅氧结构的NLDMOS（Step Gate Oxide NLDMOS , SG-NLDMOS）的热载流子效应进行了研究。采用直流电压应力实验、TCAD仿真、电荷泵测试等方法,对退化现象进行了分析,并提出了退化机制。然后研究了漂移区注入剂量对器件热载流子效应的影响,结果表明低的漂移区注入剂量可以更有效地减小器件导通电阻的退化。     

A thorough investigation of hot-carrier-induced gate oxide breakdown in partially depleted N- and P-channel SIMOX MOSFETs

In this paper, the hot-carrier-injected oxide region in the front interfaces is systematically investigated for partially depleted silicon-on-insulator (PDSOI) metal-oxide-semiconductor field-effect transistors (MOSFETs) devices fabricated on a SIMOX wafer. The gate oxide properties associated with channel hot-carrier effects are investigated and the hot-carrier-induced device degradations are analyzed using stress experiments with three main types of hot-carrier injections-maximum gate current, maximum substrate current and parasitic bipolar transistor action. Based on experimental results, the influence of these injected carriers on the gate oxide properties is clarified. As a matter of fact, NMOSFETs degradation mechanism is shown to be caused by hot holes injected into the drain side of the gate oxide, and electrons trapped in the gate oxide can accelerate the gate oxide breakdown. PMOSFETs degradation mechanism depends on the biasing conditions. For the first time, we conclude that the electrical characteristics of NMOSFETs are significantly different from that of PMOSFETs after the gate oxide breakdown. An extensive discussion of the experimental results is provided.     

The degradation mechanisms in high voltage pLEDMOS transistor with thick gate oxide

The hot-carrier degradation behavior in a high voltage p-type lateral extended drain MOS (pLEDMOS) with thick gate oxide is studied in detail for different stress voltages. The different degradation mechanisms are demonstrated: the interface trap formation in the channel region and injection and trapping of hot electrons in the accumulation and field oxide overlapped drift regions of the pLEDMOS, depending strongly on the applied gate and drain voltage. It will be shown that the injection mechanism gives rise to rather moderate changes of the specific on-resistance (Ron) but tiny changes of the saturation drain current (Idsat) and the threshold voltage (Vth). CP experiments and detailed TCAD simulations are used to support the experimental findings. In this way, the abnormal degradation of the electrical parameters of the pLEDMOS is explained. A novel structure is proposed that the field oxide of the pLEDMOS transistor is used as its gate oxide in order to minish the hot-carrier degradation.     

Leakage current variation during two different modes of electrical stressing in undoped hydrogenated n-channel polysilicon thin film transistors (TFTs)

Leakage current evolution during two different modes of electrical stressing in hydrogenated-undoped n-channel polysilicon thin film transistors (TFTs) is studied in this work. On-state bias stress (high drain bias and positive gate bias) and off-state bias stress (high drain bias and negative gate bias) were performed in order to study the degradation of the leakage current. It is found that during off-state bias stress the gate oxide is more severely damaged than the SiO₂-polySi interface. In contrast, during on-state bias stress, two different degradation mechanisms were detected which are analyzed.     

Investigation on hot-carrier-induced degradation of SOI NLIGBT

The hot-carrier-induced (HCI) degradations of silicon-on-insulator (SOI) lateral insulated gate N-type bipolar transistor (NLIGBT) are investigated in detail by DC voltage stress experiment, TCAD simulation and charge pumping test. The substrate current I_sub and on-state resistance Ron at different voltage stress conditions are measured to assess the HCI effect on device performance. The electric field and impact ionization rate are simulated to assist in providing better physical insights. And charge pumping current is measured to determinate the front-gate interface states density directly. The degradation mechanisms under different gate voltage stress conditions are then presented and summarized.     

Characteristics of PBTI and Hot Carrier Stress for LTPS-TFT With High- $kappa$ Gate Dielectric

In this letter, the characteristics of positive bias temperature instability (PBTI) and hot carrier stress (HCS) for the low-temperature poly-Si thin-film transistors (LTPS-TFTs) with gate dielectric are well investigated for the first time. Under room temperature stress condition, the. PBTI shows a more serious degradation than does HCS, indicating that the gate bias stress would dominate the hot carrier degradation behavior for LTPS-TFT. In addition, an abnormal behavior of the degradation with different drain bias stress under high-temperature stress condition is also observed and identified in this letter. The degradation of device's performance under high-temperature stress condition can be attributed to the damages of both the gate dielectric and the poly-Si grain boundaries.     

The study of hot-carrier stress on poly-Si TFT employing C-V measurement

The degradation of n-type and p-type low-temperature polycrystalline silicon (poly-Si) thin-film transistors (TFTs) due to hot-carrier stress was investigated by capacitance-voltage (C-V) measurement. In C-V measurements, the fixed charges in the gate oxide of TFTs are not affected by a small-applied signal, whereas the trap states in the bandgap respond to the applied frequency, so that the dominant degradation mechanism of poly-Si TFTs can be evaluated. The capacitance (C/sub GS/) between the source and the gate, as well as the capacitance (C/sub GD/) between the drain and the gate, were measured. The difference between the C/sub GD/ and the C/sub GS/ indicates the location of degradation in the TFT. Our experimental results showed that the degradation of n-type TFTs was caused by additional trap states in the grain boundary, whereas the degradation of p-type TFTs was caused by electron trapping into the gate oxide.     

Enhanced degradation in polycrystalline silicon thin-filmtransistors under dynamic hot-carrier stress

We address the mechanisms responsible for the enhanced degradation in the polysilicon thin-film transistors under dynamic hot-carrier stress. Unlike the monotonic decrease of maximum transconductance (G_{m max}) in static stress, G_{m max} in dynamic stress is initially increased due to the channel shortening effect by holes injected into the gate oxide near the drain region and then decreased due to tail states generation at the gate oxide/channel interface and grain boundaries. The threshold voltage variations are dominated by two degradation mechanisms: (1) breaking of weak bonds and (2) breaking of strong bonds to obey the power-time dependence law with a slope of 0.4. The degradation of the sub-threshold slope is attributed to intra-grain bulk states generation     

Impact of gate placement on RF power degradation in GaN high electron mobility transistors

We have investigated the RF power degradation of GaN high electron mobility transistors (HEMTs) with different gate placement in the source–drain gap. We found that devices with a centered gate show different degradation behavior from those with the gate placed closer to the source. In particular, centered gate devices degraded through a mechanism that has a similar signature as that responsible for high-voltage DC degradation in the OFF state and is likely driven by electric field. In contrast, offset gate devices under RF power stress showed a large increase in source resistance, which is not regularly observed in DC stress experiments. High-power pulsed stress tests suggest that the combination of high voltage and high current stress maybe the cause of RF power degradation in these offset-gate devices.     

Gate oxide leakage due to temperature accelerated degradation under plasma charging conditions

Plasma-induced gate charging and resulting damage to the gate oxide during fabrication of submicron devices becomes a serious yield and reliability concern, especially when oxide thickness and device dimensions shrink to the nanoscale region. In this paper experimental results from plasma damaged submicron MOS transistors, namely low-level gate leakage and degraded charge-to-breakdown characteristics, are analyzed with respect to conditions of electrical stress. It is demonstrated that wafer temperature is a crucial parameter for charging-induced oxide degradation due to plasma processing. Laboratory experiments simulating plasma charging showed that low-level oxide leakage is the result of oxide breakdown after electrical wear-out under low-level injection conditions. High field stress, performed at 150°C, confirmed that elevated temperature during plasma processing strongly accelerates oxide degradation and even at low-level stress leads to the effects observed in plasma damaged devices.     

Improved stability of short-channel hydrogenated N-channelpolycrystalline silicon thin-film transistors with very thin ECR N2O-plasma gate oxide

Stability has been investigated for short-channel hydrogenated n-channel polycrystalline thin-film transistors (poly-Si TFTs) with very thin (12 nm) electron cyclotron resonance (ECR) N₂O-plasma gate oxide. The TFTs show negligible changes in the electrical characteristics after hot-carrier stresses, which is due to the highly reliable interface and gate oxide. The hydrogenated TFTs with 3-μm gate length TFTs exhibit very small degradation (ΔV_th<15 mV) under hot-carrier stresses and Fowler-Nordheim (F-N) stress (ΔV_th=₈₁ mV, ΔGm/Gm=2.2%, ΔS/S=4.7%)     

Device reliability study of AlGaN/GaN high electron mobility transistors under high gate and channel electric fields via low frequency noise spectroscopy

A set of different short term stress conditions are applied to AlGaN/GaN high electron mobility transistors and changes in the electronic behaviour of the gate stack and channel region are investigated by simultaneous gate and drain current low frequency noise measurements. Permanent degradation of gate current noise is observed during high gate reverse bias stress which is linked to defect creation in the gate edges. In the channel region a permanent degradation of drain noise is observed after a relatively high drain voltage stress in the ON-state. This is attributed to an increase in the trap density at the AlGaN/GaN interface under the gated part of the channel. It was found that self-heating alone does not cause any permanent degradation to the channel or gate stack. OFF-state stress also does not affect the gate stack or the channel.     

HCS degradation of 5 nm oxide high-voltage PLDMOS

Hot carrier (HC) injection, inducing drain and gate leakage current increase in 5 nm oxide p-channel LDMOS transistors, is investigated. Devices with two different drain implants are studied. At low gate voltage (V_GS) and high drain voltage (V_DS), reduction of the ON-resistance (R_ON) is observed. At stress times at which R_ON almost reaches its constant level, an increase of the drain leakage in OFF state (V_DS = −60 V, V_GS = 0 V) is observed. Longer stress time leads to increased gate leakage and in some cases oxide breakdown. In contrast to what was reported for devices with 25 nm gate oxide thickness, the threshold voltage of 5 nm gate oxide PLDMOS transistors does not drift. The experimental data can be fully explained by hot carrier injection and the oxide damage can be explained by two different and competing degradation mechanisms. By combining experimental data and TCAD simulations we are further capable to locate the hot spot of maximum oxide damage in the accumulation (Acc) region of the PLDMOS.     

Recovery and stress dynamics in bipolar transistors and MOS devices

Stress and recovery dynamics of bipolar transistors and ultra thin oxide MOS devices have been investigated. We have found that these devices can exhibit similarities in the stress dynamics. The recovery during heat treatment was also investigated and it was found that both the dynamics and the temperature dependence of the recovery were very similar for both bipolar and MOS devices. These findings indicate that the defects might be similar where bipolar current gain degradation and MOS gate oxide charging are concerned.     

Anomalous turn-on voltage degradation during hot-carrier stress inpolycrystalline silicon thin-film transistors

In this letter, we present experimental data showing that hot-carrier stress in laser annealed polycrystalline silicon thin-film transistors provokes an anomalous turn-on voltage variation. Although under various hot-carrier stress intensities the maximum transconductance degradation shows the same power-time dependent law, turn-on voltage can exhibit different behaviors. This observation lead to the conclusion that turn-on voltage depends on two different degradation mechanisms: injection of hot carriers into the gate oxide and degradation of grain boundaries. We show that these two mechanisms may be distinguished since they obey different power-time dependent laws as a function of stress duration     

Hot carrier effects in n-MOSFETs with SiO2/HfO2/HfSiO gate stack and TaN metal gate

Charge trapping and trap generation in field-effect transistors with SiO₂/HfO₂/HfSiO gate stack and TaN metal gate electrode are investigated under uniform and non-uniform charge injection along the channel. Compared to constant voltage stress (CVS), hot carrier stress (HCS) exhibits more severe degradation in transconductance and subthreshold swing. By applying a detrapping bias, it is demonstrated that charge trapping induced degradation is reversible during CVS, while the damage is permanent for hot carrier injection case.     

Temperature accelerated gate oxide degradation under plasma-inducedcharging

Gate oxide charging during plasma processing of submicron devices becomes a serious yield and reliability concern, especially when oxide thickness and device dimensions shrink to the nanoscale region. This paper shows that wafer temperature is a crucial parameter for charging-induced oxide degradation due to plasma processing. Experimental results from plasma damaged submicron MOS transistors, namely low-level gate leakage and degraded charge-to-breakdown characteristics are analyzed from the point of view of conditions of electrical stress. Laboratory experiments simulating plasma charging, performed at 150°C, confirmed that elevated temperature during plasma processing strongly accelerates oxide degradation and even at low-level stress leads to effects observed in plasma damaged devices     

功率NLDMOS电学安全工作区的版图设计优化

在不调整制备工艺、不增加工艺成本条件下,研究了管芯版图优化对功率n型横向扩散金属氧化物半导体(NLDMOS)电学安全工作区(E-SOA)的影响。通过研究p^+带嵌入方式、p^+图形形状、p^+分布密度、阵列单元栅宽及总栅数、金属引线方式等进行了版图设计优化和流片。管芯传输线脉冲(TLP)E-SOA测试结果表明,优化后的版图使NLDMOS在5 V工作电压下TLP E-SOA提升约30%,金属引线的加宽和叠加使NLDMOS的开态电流提升约7%。带状紧凑型p^+带且双栅极嵌入的优化版图设计能更好地稳定硅衬底电位,抑制寄生三极管的开启,增大E-SOA,提高器件可靠性。因此,版图设计优化对提升功率NLDMOS的性能和可靠性具有实际意义。     

直接隧穿应力下超薄栅氧MOS器件退化

研究了栅氧厚度为1.4nm MOS器件在恒压直接隧穿应力下器件参数退化和应力感应漏电流退化. 实验结果表明,在不同直接隧穿应力过程中,应力感应漏电流（SILC）的退化和Vth的退化均存在线性关系. 为了解释直接隧穿应力下SILC的起因,建立了一个界面陷阱和氧化层陷阱正电荷共同辅助遂穿模型.     

Radiation source dependence of performance degradation in thin gate oxide fully-depleted SOI n-MOSFETs

The degradation of the electrical performance of thin gate oxide fully depleted SOI n-MOSFETs and its dependence on the radiation particles are investigated. The transistors are irradiated with 7.5-MeV protons and 2-MeV electrons at room temperature without bias. The shift of threshold voltage and the coupling effect with the degraded opposite gate are clarified. A remarkable reduction of the floating body effects is observed after irradiation. The degradation of the extracted parameters is discussed by a comparison with the damage coefficients.