High voltage degradation of GaN High Electron Mobility Transistors on silicon substrate

We have electrically stressed GaN High Electron Mobility Transistors on Si substrate at high voltages. We observe a pattern of device degradation that differs markedly from previous reports in GaN-on-SiC HEMTs. Similarly to these devices, the gate leakage current of GaN-on-Si HEMTs increases by several orders of magnitude at a certain critical voltage and this increase is irreversible. However, in contrast with devices on SiC, the critical voltage varies substantially across the wafer, even over short distances, with values as high as 75 V being observed. In addition, for voltages below the critical voltage, we observe a prominent degradation in the drain current and the source and drain resistances, something not observed in devices on SiC. This degradation is almost completely recoverable under UV illumination. We attribute these results to the high mismatch that exists between GaN and Si that leads to a large concentration of electrically active traps and a lower and non-uniform initial strain in the AlGaN barrier. This is evidenced by observed correlations between threshold voltage and maximum drain current in fresh devices and their corresponding critical voltages.     

High-energy tail electrons as the mechanism for the worst-case hot-carrier stress degradation of the deep submicrometer N-MOSFET

Experimental evidence, based on sensitively modulating the concentration of the high-energy tail of the electron energy distribution, reveals an important trend in the mid-to-high gate stress voltage (V/sub g/) regime, where device degradation is seen to continuously increase with the applied V/sub g/, for a given drain stress voltage V/sub d/. The shift in the worst-case degradation point from V/sub g//spl ap/V/sub d//2 to V/sub g/=V/sub d/, depicting an uncorrelated behavior with the substrate current, is caused by the injection of the high-energy tail electrons into the gate oxide, when the oxide field near the drain region becomes increasingly favorable as V/sub g/ approaches V/sub d/. This letter offers an improved framework for understanding the worst-case hot-carrier stress degradation of deep submicrometer N-MOSFETs under low bias condition.     

SOI NLIGBT热载流子效应研究

SOI NLIGBT中热载流子效应分别通过直流电压的应力测试、TCAD仿真和电荷泵测试三种方法进行了研究。其中,不同直流电压应力条件下测得的衬底电流Isub和导通电阻Ron用来评估因热载流子效应引起的器件退化程度。为了进行理论分析,对器件内部的电场强度和碰撞离化率也进行了仿真。测试得到的电荷泵电流直接验证了器件表面的损伤程度。最后讨论了SOI LIGBT在不同栅压条件下的退化机制。     

Generation mechanism of gate leakage current due to reverse-voltagestress in i-AlGaAs/n-GaAs HIGFETs

Device degradation characterized as an increase in the gate leakage current due to continuous reverse-voltage stress was investigated for a 0.35-μm WSi gate i-AlGaAs/n-GaAs doped channel HIGFET (heterostructure insulated-gate field-effect transistor). The gate leakage current, which was dominated by a hole current generated by impact ionization, was found to increase after the application of a gate-to-drain voltage of -6 V for a certain period. The occurrence of the impart ionization was evidenced by the generation of a substrate current and by the negative temperature coefficient of the gate current. The degradation was retarded at an elevated temperature, indicative of hot-carrier-related degradation. The degraded device also showed an ohmic-like gate leakage current. Subsequent annealing at temperatures above 300°C significantly restored the current-voltage (I-V) characteristics. From these observations, a degradation model was developed in which hot holes generated by impact ionization are trapped in the insulator/semiconductor interface, contracting the surface depletion region and thereby increasing the electric field near the gate-edge. A surface treatment using CF₄ plasma was used to suppress the degradation. An FET fabricated using this treatment showed a remarkable decrease in degradation     

Experimental extraction of degradation parameters after constant voltage stress and substrate hot electron injection on ultrathin oxides

The impact of hot electrons on gate oxide degradation is studied by investigating devices under constant voltage stress and substrate hot electron injection in thin silicon dioxide (2.5–1.5 nm). The build-up defects measured using low voltage stress induced leakage current is reported. Based on these results, we propose to extract the critical parameter of the degradation under simultaneous tunnelling and substrate hot-electron stress. During a constant voltage stress the oxide field, the injected charge and the energy of carriers are imposed by V_G and cannot be studied independently. Substrate hot electron injection allows controlling the current density independent of the substrate bias and oxide voltage. The results provide an understanding for describing the reliability and the parameters dependence under combined substrate hot electron injection and constant voltage stress tunnelling.     

Hot-electron-induced degradation of conventional, minimum overlap,LDD and DDD N-channel MOSFETs

Substrate current characteristics of conventional minimum overlap, DDD (double-diffused drain), and LDD (lightly doped drain) n-channel MOSFETs with various LDD n^- doses have been studied. Threshold voltage shift, transconductance degradation, and change of substrate current for these devices after stressing were also investigated. The minimum gate/drain overlap devices had the highest substrate current and the worst hot-electron-induced degradation. The amount of gate-to-n⁺ drain overlap in LDD devices was an important factor for hot-electron effects, especially for devices with low LDD n^- doses. The injection of hot holes into gate oxide in these devices at small stressed gate voltages was observed and was clearly reflected in the change of substrate current. The device degradation of low-doped LDD n-channel MOSFETs induced by AC stress was rather severe     

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.     

Hot-carrier drifts in submicrometer p-channel MOSFET's

Hot-carrier-induced shifts in p-channel MOSFET operating characteristics have been observed down to drain voltages of - 6 V. Cases are discussed in which p-MOSFET's show up to two orders of magnitude larger degradation than corresponding n-MOSFET's. The shifts include current and threshold voltage increases. From dependences on stress gate voltage, stress drain voltage, time, and substrate current, the hot-carrier origin of the shifts is specified in detail.     

New experimental findings on hot carrier effects in deep submicrometer surface channel PMOS

The correlation between gate current and substrate current in surface channel(SC) PMOS with effective channel length down to 0.15 μm is investigated within the general framework of the lucky-electron model. It is found that the impact ionization rate increases, but the device degradation is not serious in deep submicrometer PMOS. To extend the lucky-electron model to deep submicrometer regime, we empirically model the effective pinch-off length as a function of the gate length and the gate bias voltage. SCIHE is suggested as the possible physical mechanism for the enhanced impact ionization and the gate current reduction.     

Subthreshold conduction in MOSFET's

The dependence of channel current in subthreshold operation upon drain, gate, and substrate voltages is formulated in terms of a simple model. The basic results are consistent with earlier approaches for long-channel devices. For short-channel devices, the variation of current with drain voltage up to the punch-through voltage is accurately described. The threshold voltage of a short-channel device as a function of applied voltages follows as a natural result of the derivation. Results are presented which confirm the theory over a wide range of drain and gate voltages. With the application of substrate bias it is concluded from the data and the theory that two-dimensional effects can cause dramatic increases in the drain conductance.     

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.     

HALO结构pMOSFETs在V_g=V_d/2应力模式下应力相关的热载流子退化

研究了超薄栅(2 .5 nm )短沟HAL O- p MOSFETs在Vg=Vd/ 2应力模式下不同应力电压时热载流子退化特性.随着应力电压的变化,器件的退化特性也发生了改变.在加速应力下寿命外推方法会导致过高地估计器件寿命.在高场应力下器件退化是由空穴注入或者电子与空穴复合引起的,随着应力电压的下降器件退化主要是由电子注入引起的.最后,给出了两种退化机制的临界电压并在实验中得到验证     

Degradation of ultra-thin gate oxide LDD NMOSFET under GIDL stress

The degradation of device under GIDL(gate-induced drain leakage current)stress has been studied using LDD NMOSFETs with 1.4 nm gate oxides.Experimental result shows that the degradation of device parameters depends more strongly on Vd than on Vg.The characteristics of the GIDL current are used to analyze the damage generated during the stress.It is clearly found that the change of GIDL current before and after stress can be divided into two stages.The trapping of holes in the oxide is dominant in the first stage,but that of electrons in the oxide is dominant in the second stage.It is due to the common effects of edge direct tunneling and band-to-band tunneling.SILC(stress induced leakage current)in the NMOSFET decreases with increasing stress time under GIDL stress.The degradation characteristic of SILC also shows saturating time dependence.SILC is strongly dependent on the measured gate voltage.The higher the measured gate voltage,the less serious the degradation of the gate current.A likely mechanism is presented to explain the origin of SILC during GIDL stress.     

Design and characteristics of a lightly doped drain (LDD) device fabricated with self-aligned titanium disilicide

An As-P double-diffused lightly doped drain (LDD) device has been designed and fabricated with a self-aligned titanium disilicide process. The device design was aided by using an analytical one-dimensional model, and analytic results agree well with experimental data on the avalanche breakdown voltage gain and the ratio of substrate current to source current. Threshold voltage and subthreshold characteristics of this device do not deviate from those of a conventional device without LDD and silicide. The drain avalanche breakdown voltage of the LDD device is higher by 2.5 V over the conventional device. Transconductance degradation was observed for the LDD devices due to the inherently high source-drain series resistance of the LDD structure. Substrate current is reduced and hot-electron reliability is greatly improved. The titanium disilicide process effectively reduces the sheet resistances of the source-drain diffusion and the polysilicon gate to 3 Ω/sq compared with 150 Ω/sq of the unsilicided counterparts. It is also found that larger polysilicon grain size increases the sheet resistance of the silicide gate due to discontinuous titanium disilicide formation on top of polysilicon.     

Investigation of the effect of temperature during off-state degradation of AlGaN/GaN High Electron Mobility Transistors

AlGaN/GaN High Electron Mobility Transistors were found to exhibit a negative temperature dependence of the critical voltage (V_CRI) for irreversible device degradation to occur during bias-stressing. At elevated temperatures, devices exhibited similar gate leakage currents before and after biasing to V_CRI, independent of both stress temperature and critical voltage. Though no crack formation was observed after stress, cross-sectional TEM indicates a breakdown in the oxide interfacial layer due to high reverse gate bias.     

Microwave-Rectification RFI Response in Field-Effect Transistors

This paper discusses the rectification of microwave energy in low-medium frequency feld-effect transistors (FET's) and develops a small-signal model for RHI noise analysis in low-frequency linear circuitry. The modeling procedure centers on a Taylor series expansion of the gate voltage-drain current characteristic which shows a small increase in drain current due to a nicrowave voltage at the gate. The increase in drain current is proportional to the variation in transconductance with gate voltage, and the square of the microwave voltage. Analysis of the microwave power in the transistor shows that critical parameters in determnination of the sensitivity are the gate capacitance and the real part ofthe device input impedance, which ultimately is limited by the parasitic resistance between the active channel and contacts.     

Snapback应力对90nm nMOSFET栅氧化层完整性的影响

基于测试对snapback应力引起的栅氧化层损伤特性和损伤位置进行了研究.研究发现应力期间产生的损伤引起器件特性随应力时间以近似幂指数的关系退化.应力产生的氧化层陷阱将会引起应力引起的泄漏电流增加,击穿电荷减少,也会造成关态漏泄漏电流的退化.栅氧化层损伤不仅在漏区一侧产生,而且也会在源区一侧产生.热空穴产生的三代电子在指向衬底的电场作用下向Si-SiO2界面移动,这解释了源区一侧栅氧化层损伤的产生原因.     

Hot-carrier-induced degradation in nitrided oxide MOSFETs

Hot-carrier-induced degradation in commercially prepared silicon-gate MOSFETs incorporating ammonia annealed, nitrided oxides as the gate dielectric is examined and compared with the degradation observed in similar devices incorporating conventional oxides. Nitridation at 1100°C for 2 h is observed to reduce the rate of transconductance degradation and threshold voltage increase by nearly half, compared to the oxide for stressing at both low and high gate bias, and to modify the effects of stressing on the substrate current characteristics. In contrast, nitridation at 1150°C produces both improvements and degradations in device stability depending on the parameter examined and the stress conditions. While ammonia annealing introduces nitrogen, it also appears to incorporate excess hydrogen in the dielectrics that alters charge trapping and interface-state generation so that the performance of the dielectric under electrical stress depends on the concentrations of both species     

Snapback应力对90nm nMOSFET栅氧化层完整性的影响

基于测试对snapback应力引起的栅氧化层损伤特性和损伤位置进行了研究．研究发现应力期间产生的损伤引起器件特性随应力时间以近似幂指数的关系退化．应力产生的氧化层陷阱将会引起应力引起的泄漏电流增加，击穿电荷减少，也会造成关态漏泄漏电流的退化．栅氧化层损伤不仅在漏区一侧产生，而且也会在源区一侧产生．热空穴产生的三代电子在指向衬底的电场作用下向Si-SiO2界面移动，这解释了源区一侧栅氧化层损伤的产生原因．     

GaN HEMT reliability

This paper reviews the experimental evidence behind a new failure mechanism recently identified in GaN high-electron mobility transistors subject to electrical stress. Under high voltage, it has been found that electrically active defects are generated in the AlGaN barrier or at its surface in the vicinity of the gate edge. These defects reduce the drain current, increase the parasitic resistance and provide a path for excess gate current. There is mounting evidence for the role of the inverse piezoelectric effect in introducing mechanical stress in the AlGaN barrier layer and eventually producing these defects. The key signature of this mechanism is a sudden and non-reversible increase in the gate leakage current of several orders of magnitude. This degradation mechanism is voltage driven and characterized by a critical voltage below which degradation does not occur. This hypothesis suggests several paths to enhance the electrical reliability of GaN HEMTs which are borne out by experiments.