Channel width dependence of AC stress on bulk nMOSFETs

Channel width dependence of AC stress was investigated. OFF-state stress generated negative interface traps, positive oxide charges, and neutral traps in the whole channel region. Comparison of drain currents of parasitic and main MOSFET during OFF-state indicates that more defects were generated on channel edge than near its center. During ON-state stress, electrons were dominantly trapped in the neutral traps near channel edge. These results cause degradation due to AC stress to become increasingly severe as W is scaled down. The operating voltage to guarantee 10-year lifetime decreased as width decreased. The above results show that electron trapping in neutral traps near the channel edge induce severe degradation on narrow nMOSFET during AC stress. Therefore, degradation of channel edge during AC stress is an importantly considered in narrow nMOSFET.     

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.     

Characterization of the frequency dispersion of transconductance and drain conductance of GaAs MESFET

Frequency dispersions of the transconductance and the drain conductance of ion-implanted gallium arsenide (GaAs) metal-semiconductor field-effect transistors (MESFETs) are measured and analyzed. In the linear region of the MESFET (low drain voltage), a positive transconductance dispersion is observed, which is caused by the deep-level traps at the surface between the source and the gate. In the saturation region (high drain voltage), however, a negative transconductance dispersion becomes dominant. The drain conductance does not show a dispersion in the linear region, while a distinct positive dispersion is observed in the saturation region with the same activation energy as the negative transconductance dispersion. The difference of the dispersion activation energy of the MESFET with and without the p-buried layer beneath the channel indicates that the negative transconductance and the drain conductance dispersion are caused by the deep-level traps at the channel-substrate interface. Because there exists the high electric field at the drain edge of the gate and an electron accumulation layer is formed, the potential in the channel becomes lower when the drain current is larger with high gate voltage. The emission of electrons from electron traps with lower potential is the cause of the negative frequency dispersion.     

Hot-carrier-induced degradation in short p-channel nonhydrogenatedpolysilicon thin-film transistors

The effects of low gate voltage |V_g| stress (V_g =-2.5 V, V_d=-12 V) and high gate voltage |V_g| stress (V_g=V_d=-12 V) on the stability of short p-channel nonhydrogenated polysilicon TFTs were studied. The degradation mechanisms were identified from the evolution with stress time of the static device parameters and the low-frequency drain current noise spectral density. After low |V_g| stress, transconductance overshoot, kinks in the transfer characteristics, and positive threshold voltage shift were observed. Hot-electron trapping in the gate oxide near the drain end and generation of donor-type interface deep states in the channel region are the dominant degradation mechanisms. After high |V_g| stress, transconductance overshoot and "turn-over" behavior in the threshold voltage were observed. Hot-electron trapping near the drain junction dominates during the initial stages of stress, while channel holes are injected into the gate oxide followed by interface band-tail states generation as the stress proceeds     

New degradation mechanism observed for AlGaN/GaN HEMTs with sub 100 nm scale unpassivated regions around the gate periphery

AlGaN/GaN HEMTs with low gate leakage current in the μA/mm range have been fabricated with a small-unpassivated region close to the gate foot. They showed considerably higher critical voltage values (average VCR = 60 V) if subjected to step stress testing at OFF-state conditions and room temperature as compared to standard devices with conventional gate technology. This is due to the fact that electrons injected from the gate can be accumulated at the unpassivated region and thus builds up negative charge. The lower gate leakage is due to virtual gate formation, which is reducing local electric field in the vicinity of the gate. In contrast to devices with standard gate technology, degradation during step stressing is not associated with a simultaneous gate leakage and drain leakage current increase but with a strong increase of drain current at OFF-state conditions while the gate leakage is practically not affected. Then a relatively higher critical voltage of around 60 V is achieved. An abrupt increase of subthreshold drain current implies the formation of a conductive channel bypassing the gate region without influencing gate leakage. It is believed that hopping conductivity via point defects formed during device stressing creates this channel. Once this degradation mode takes place, the drain current of affected devices significantly drops. This can be explained by negative trap formation in the channel region affecting the total charge balance in 2DEG region. Electroluminescence measurements on both fresh and degraded devices showed no hot spots at OFF-state conditions. However, there is additional emission at ON-state bias, which suggests additional energetic states that lead to radiative electron transition effects in the degraded devices, most possibly defect states in the buffer.     

A new insight into the degradation behavior of the LDD N-MOSFETduring dynamic hot-carrier stressing

A new degradation behavior of LDD N-MOSFETs during dynamic hot-carrier stress is presented. Increased degradation occurs during the gate pulse transition, and involves hot-hole injection that initially begins in the oxide-spacer region, and later propagates to the channel region. Experimental results clearly show that increased degradation of the linear drain current and transconductance is mainly due to hole-induced interface traps in the oxide-spacer region. Electron trapping at hole-induced oxide defects, on the other hand, is mainly responsible for the enhanced threshold voltage shift in the late stage, when hole injection coincides with electron injection in the channel region     

Current Collapse and High-Electric-Field Reliability of Unpassivated GaN/AlGaN/GaN HEMTs

Long-term ON-state and OFF-state high-electric-field stress results are presented for unpassivated GaN/AlGaN/GaN high-electron-mobility transistors on SiC substrates. Because of the thin GaN cap layer, devices show minimal current-collapse effects prior to high-electric-field stress, despite the fact that they are not passivated. This comes at the price of a relatively high gate-leakage current. Under the assumption that donor-like electron traps are present within the GaN cap, two-dimensional numerical device simulations provide an explanation for the influence of the GaN cap layer on current collapse and for the correlation between the latter and the gate-leakage current. Both ON-state and OFF-state stresses produce simultaneous current-collapse increase and gate-leakage-current decrease, which can be interpreted to be the result of gate-drain surface degradation and reduced gate electron injection. This study shows that although the thin GaN cap layer is effective in suppressing surface-related dispersion effects in virgin devices, it does not, per se, protect the device from high-electric-field degradation, and it should, to this aim, be adopted in conjunction with other technological solutions like surface passivation, prepassivation surface treatments, and/or field-plate gate     

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     

Dynamic hot-carrier induced degradation in n-channel polysilicon thin-film transistors

The effects of hot-carriers under dynamic stress on the transfer characteristics and the noise performance of n-channel polysilicon thin-film transistors are analysed. The observed decrease in the on-state current is directly related to the mobility of a damaged region extended over a length of about 0.53 μm beside the drain, which is evaluated through analysis of the transfer characteristics at low drain voltage. The mobility degradation in the damaged region is due to the formation of traps located near the polysilicon/gate oxide interface as evidenced by the 1/f noise measurements.     

Analysis of the DCIV peaks in electrically stressed pMOSFETs

This paper presents the effects of Fowler-Nordheim (FN) and hot-carrier (HC) stress in the direct-current current voltage (DCIV) measurements. The effect of interface trapped charge on DCIV curves is reported. Stress-induced oxide charge shifts the DCIV peaks, while stress-induced interface trapped charge causes a spread in the DCIV peaks. It is found that under HC stress, when the absolute value of stress gate voltage changes from low to high, the interface trap spatial location moves from the drain region to the channel region. It is inferred that the generation of oxide charge in the drain region is a two-step process. For short stress times, electrons mainly fill the process-induced neutral oxide traps, while for long stress times, electrons fill the stress created electron traps     

Implications of gate-edge electric field in AlGaN/GaN high electron mobility transistors during OFF-state degradation

Gate degradation in high electron mobility transistors (HEMTs) under OFF-state stress results from the high electric field near the gate edge. We investigate the evolution of this field over time in AlGaN/GaN HEMTs upon OFF-state stress using a combination of electroluminescence (EL) microscopy and spectroscopy. EL analysis suggests that the electric field at the sites of generated surface defects is lowered after the stress, with greater lowering at higher stress temperature. The ON-state EL spectrum remains unchanged after the stress, suggesting that the regions without generated defects are not affected during the degradation. A finite element model is employed to further demonstrate the effect of surface defects on the local electric field. A correlation is observed for the spatial distribution of the EL intensity before and after the generation of leakage sites, which provides a prescreening method to predict possible early failures on a device.     

Degradation of short-channel MOSFET's under constant current stress across gate and drain

We have employed a technique of constant current stress between the gate and drain of a MOS transistor to study the degradation of the threshold voltage, transconductance, and substrate current characteristics of the transistor. From the transistor characteristics, we propose that the degradation mechanism is a combined effect of trapping of holes in the gate oxide created by impact ionization due to the high electric field (> 8 MV/cm) across the oxide, and electron trapping phenomena. The degradation characteristics of the transistor under this constant current stress are quite similar to that observed normally due to the injection of hot electrons in the gate oxide when the transistor is biased in "ON" condition and the gate and drain voltages are selected to produce maximum substrate current.     

Hot-carrier-induced MOSFET degradation under AC stress

The effects of gate and drain voltage waveforms on the hot-carrier-induced MOSFET degradation are studied. Drain votage transients have little effect on the degradation rate. Only the falling edge of the gate pulse in the presence of a high drain voltage enhances the degradation rate. For devices in typical inverter circuits, dc stress results together with the substrate current waveform can predict the degradation rate under ac stress for a wide range of rise and delay times.     

The influence of gate edge shape on the degradation in hot-carrierstressing of n-channel transistors

The hot-carrier properties of planar and graded gate structures (upturning of the gate edge in the gate overlap region) of n-MOS transistors were examined. It was found that the type of degradation suffered by each type of device depends on the shape of the gate edge. This is interpreted in terms of the degree of gate control of the gate over the region in which the damage takes place in the different devices. The nongraded gate (NGG) devices degrade chiefly by a V_t shift, whereas the graded gate (GG) devices show a pronounced transconductance decay, with practically no V_t shift. It is suggested that the damage is situated in the gate overlap region, and that the different degradations result from a weaker field control of the gate over the degraded region leading to a series resistance type of effect in the case of the GG structure. This is supported by two-dimensional simulations     

关态应力下P-MOSFETs的退化

研究了沟长从0.525μm到1.025μm 9nm厚的P-MOSFETs在关态应力(Vgs＝0,Vds＜0)下的热载流子效应．讨论了开态和关态应力．结果发现由于在漏端附近存在电荷注入,关态漏电流在较高的应力后会减小．但是低场应力后关态漏电流会增加,这是由于新生界面态的作用．结果还发现开态饱和电流和阈值电压在关态应力后变化很明显,这是由于栅漏交叠处的电荷注入和应力产生的界面态的影响．Idsat的退化可以用函数栅电流（Iｇ）乘以注入的栅氧化层电荷数（Qinj）的幂函数表达．最后给出了基于Idsat退化的寿命预测模型．     

Transconductance increase due to charge trapping during hot-carrier stress of nMOSFETs

An unusual hot-carrier degradation mode characterised by a transconductance increase during hot-carrier ageing of nMOS transistors is analysed. By measuring the effects of hot-carrier stress on drain and substrate characteristics and applying alternate static injection phases performed at different gate regimes, it is proved that the degradation is mainly due to negative charge trapping in a localised region near the drain. The transconductance increase is explained in terms of an exchange of the dominant role between the damaged and undamaged portions of the channel. This model is fully corroborated by 2D device electric simulation results.     

A novel 4H-SiC MESFET by lateral insulator region to improve the DC and RF characteristics

In this paper, a novel recessed gate metal–semiconductor field-effect transistor (RG-MESFET) is presented by modifying the depletion region and the electric field. The proposed structure improves the breakdown voltage, drain current and high frequency characteristics by embedding a lateral insulator region between drain and gate while is placed laterally into the metal gate and a silicon well exactly under the insulator region. We called this new structure as modified recess gate MESFET (MRG-MESFET). The radio frequency and direct current (DC) characteristics of the proposed structure is studied using numerical simulations and compared with a conventional MESFET (C-MESFET). The breakdown voltage, drain current DC transconductance and maximum power density of the proposed structure increase by 27%, 16.5%, 15% and 48%, respectively, relative to the C-MESFET. Also, the gate-source capacitance and the minimum noise figure of the proposed structure improve relative to the C-MESFET. The proposed structure can be used for high breakdown voltage, high saturation drain current, high DC transconductance, high power, high frequency, and low noise applications.     

Hot electron effects on Al0.25Ga0.75As/GaAspower HFET's under off-state and on-state electrical stress conditions

This work shows a detailed comparison of the degradation modes caused by off-state and on-state room temperature electrical stress on the DC characteristics of power AlGaAs/GaAs heterostructure field effect transistors (HFET's) for X- and Ku-band applications. The devices are stressed under DC bias conditions that result in electron heating and impact ionization in the gate-drain region. Incremental stress experiments carried out at gate-drain reverse currents up to 3.3 mA/mm (for a total of more than 700 h) show a remarkably larger degradation for the off state stress, due to more pronounced electron heating at any fixed value of gate reverse current. This represents an important piece of information for the reliability engineer when it comes to designing the accelerated stress experiments for hot electron robustness evaluation. The degradation modes observed, all of a permanent nature, include threshold voltage and drain resistance increase and drain current and transconductance reduction     

Performance and hot-carrier reliability of 100 nm channel lengthjet vapor deposited Si3N4 MNSFETs

Metal-nitride-semiconductor FETs (MNSFETs) having channel lengths down to 100 mm and a novel jet vapor deposited (JVD) Si₃N₄ gate dielectric have been fabricated and characterized. When compared with MOSFETs having a thermal SiO₂ gate insulator, the MNSFETs show a comparable drain current drive, transconductance, subthreshold slope and pre-stress interface quality. A novel charge pumping technique is employed to characterize the hot-carrier induced interface-trap generation in MNSFETs and MOSFETs. Under identical substrate current during stress, MNSFETs show less interface-state generation and drain current degradation, for various channel lengths, stress times and supply voltages, despite the fact that the Si-Si₃N₄ barrier (2.1 eV) is lower than the Si-SiO₂ barrier (3.1 eV). The time and voltage dependence of hot-carrier degradation has been found to be distinctly different for MNSFETs compared to SiO₂ MOSFETs     

Degradation of d.c. parameters in enhancement mode WNx self-aligned gate GaAs MESFETs under high temperature stress

The effect of thermal stress on the d.c. parameter degradation of enhancement mode tungsten nitride (WN_x) self-aligned gate GaAs MESFETs was investigated. Threshold voltage, source-drain current and transconductance were measured during the tests. The physical properties of the device after thermal stress were analyzed by means of Auger electron spectroscopy (AES), X-ray diffractometry to identify the degradation mechanism. The d.c. failure mode consists of an increase in the threshold voltage and a decrease in the current and transconductance of the FETs. The device simulator was also used for analytical understanding of the d.c. parameter degradation. The simulated results showed that d.c. parameter degradation was mainly attributed to the increase in source and drain ohmic contact resistances. From the AES analysis, we found that the increase of contact resistance was due to carrier compensation, which was caused by Ga outdiffusion and Ni indiffusion under the ohmic contact layer. Therefore the thermally activated carrier compensation effects by trap generation are proposed to be the main failure mechanism for d.c. parameter degradation of enhancement mode WN_x self-aligned gate GaAs MESFETs.