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     

A new approach to simulating n-MOSFET gate current degradation byincluding hot-electron induced oxide damage

A new gate current model which considers the hot-electron induced oxide damage in n-MOSFET's was developed for the first time. The spatial distributions of oxide damage, including the interface state (N_it ) and oxide trapped charge (Q_ox) were characterized by using an improved gated-diode current measurement technique. A numerical model feasible for accurately simulating gate current degradation due to the stress generated N_it and Q_ox has thus been proposed. Furthermore, the individual contributions of N_it and Q_ox to the degradation of gate current can thus be calculated separately using these oxide damage. For devices stressed under maximum gate current biases, it was found that the interface state will degrade the gate current more seriously than that of the oxide trapped charge. In other words, the interface states will dominate the gate current degradation under I_G,max. Good agreement of the simulated gate current has been achieved by comparing with the measured data for pre-stressed and post-stressed devices. Finally, the proposed degradation model is not only useful for predicting the gate current after the hot-electron stress, but also provides a monitor that is superior to substrate current for submicron device reliability applications, in particular for EPROM and flash EEPROM devices     

Striped-channel InAlAs/InGaAs HEMTs with shallow-grating structures

Striped-channel (SC) InAlAs/InGaAs HEMTs have been demonstrated with shallow gratings. The shallow grating structure keeps the gate from touching the channel layer and thus solves the gate leakage problem observed in the deep grating devices on InP substrates. Various channel widths have been realized to study the impact of the channel width on the dc and microwave performance. Due to the enhanced charge control in the SC HEMTs, enhanced transconductance/source-drain current (G_m /I_ds) and transconductance/output conductance (G_m /G_ds) were observed. Compared with conventional HEMTs, the SC HEMTs showed degraded f_T due to additional parasitic capacitances and improved f_max due to better carrier confinement     

Hot-carrier-induced degradation in reoxidized-nitrided-oxiden-MOSFETs under mixed AC-DC stressing

Reduced degradation rate can be observed for reoxidized-nitrided-oxide (RNO) n-MOSFETs under dynamic stressing versus the corresponding static stressing. A new degradation mechanism is proposed in which trapped holes in gate oxide are neutralized by the hot-electron injection, with no significant generation of interface states because of the hardening on the Si-SiO₂ interface by nitridation/reoxidation steps. The RNO device degradation during AC stressing arises mainly from the charge trapping in the gate oxide rather than the generation of interface states. Moreover, the AC-stressed RNO devices are significantly inferior to the fresh RNO devices in terms of DC stressing, possibly due to lots of neutral electron traps in the gate oxide resulting from the AC stressing     

Dynamic-stress-induced enhanced degradation of 1/f noise inn-MOSFETs

AC-stress-induced degradation of 1/f noise is investigated for n-MOSFETs with thermal oxide or nitrided oxide as gate dielectric, and the physical mechanisms involved are analyzed. It is found that the degradation of 1/f noise under AC stress is far more serious than that under DC stress. For an ac stress of V_G=0~0.5 V_D, generations of both interface states (ΔD_it) and neutral electron traps (ΔN_et) are responsible for the increase of 1/f noise, with the former being dominant. For another AC stress of V _G=0~V_D. a large increase of 1/f noise is observed for the thermal-oxide device, and is attributed to enhanced ΔN_et and generation of another specie of electron traps, plus a small amount of ΔD_it. Moreover, under the two types of AC stress conditions, much smaller degradation of 1/f noise is observed for the nitrided device due to considerably improved oxide/Si interface and near-interface oxide qualities associated with interfacial nitrogen incorporation     

Mechanisms for hot-carrier-induced degradation inreoxidized-nitrided-oxide n-MOSFET's under combined AC/DC stressing

Hot-carrier-induced degradation behavior of reoxidized-nitrided-oxide (RNO) n-MOSFETs under combined AC/DC stressing was extensively studied and compared with conventional-oxide (OX) MOSFETs. A degradation mechanism is proposed in which trapped holes in stressed gate oxide are neutralized by an ensuing hot-electron injection, leaving lots of neutral electron traps in the gate oxide, with no significant generation of interface states. The degradation behavior of threshold voltage, subthreshold gate-voltage swing, and charge-pumping current during a series of AC/DC stressing supports this proposed mechanism. RNO device degradation during AC stressing arises mainly from the charge trapping in gate oxide rather than the generation of interface states due to the hardening of the Si-SiO₂ interface by nitridation/reoxidation steps     

Correlation of trap generation to charge-to-breakdown (Qbd): a physical-damage model of dielectric breakdown

Ultrathin gate and tunnel oxides in MOS devices are subjected to high-field stress during device operation, which degrades the oxide and eventually causes dielectric breakdown. Oxide reliability, therefore, is a key concern in technology scaling for ultra-large scale integration (ULSI). Here we provide critical new insight into oxide degradation (and consequently, reliability) by a systematic study of five technologically relevant parameters, namely, stress-current density, oxide thickness, stress temperature, charge-injection polarity (gate versus substrate), and nitridation of pure oxide. For all five parameters, a strong correlation has been observed between oxide degradation and the generation of new traps (distinct from the filling of intrinsic traps). Further, we observe that this correlation is independent of the trap polarity (positive versus negative). Based on this correlation, and based on the fundamental link between electronic properties and atomic structure, a physical-damage model of dielectric breakdown has been proposed. The concept of the physical-damage model is that the oxide suffers dielectric breakdown when physical damage due to broken bonds forms a defect-filled filamentary path in the oxide, that conducts excessive current. A good monitor of this physical damage is trap generation, which we believe is caused by physical bond breaking in the oxide and at the interface. The model has been quantified empirically by the correlation between trap generation and Q_bd     

Channel hot-carrier stressing of reoxidized nitrided silicondioxide

The mechanisms of channel hot-carrier-induced degradation in short n-channel MOSFETs with reoxidized nitrided oxide as the gate dielectric are discussed. Charge pumping measurements, supported by observations on the gate voltage dependence of degradation and the power law dependence of Δg_m on stress time, demonstrate that virtually no interface trap generation occurs in reoxidized nitrided oxides and that electron trapping is the dominant degradation mechanism. Although electron trapping can be enhanced in these dielectrics, this mechanism is not as important for device degradation as interface trap generation, and the net effect is substantially improved resistance to hot-carrier stress. A three-orders-of-magnitude improvement in device lifetime (versus conventional oxide) is demonstrated     

热载流子应力下n-MOSFET线性漏电流的退化

研究了不同沟道和栅氧化层厚度的n-M O S器件在衬底正偏压的VG=VD/2热载流子应力下,由于衬底正偏压的不同对器件线性漏电流退化的影响。实验发现衬底正偏压对沟长0.135μm,栅氧化层厚度2.5 nm器件的线性漏电流退化的影响比沟长0.25μm,栅氧化层厚度5 nm器件更强。分析结果表明,随着器件沟长继续缩短和栅氧化层减薄,由于衬底正偏置导致的阈值电压减小、增强的寄生NPN晶体管效应、沟道热电子与碰撞电离空穴复合所产生的高能光子以及热电子直接隧穿超薄栅氧化层产生的高能光子可能打断S i-S iO2界面的弱键产生界面陷阱,加速n-M O S器件线性漏电流的退化。     

Anomalous variations of OFF-State leakage current in poly-Si TFTunder static stress

Studies the anomalous variations of the OFF-state leakage current (I_OFF) in n-channel poly-Si thin-film transistors (TFTs) under static stress. The dominant mechanisms for the anomalous I_OFF can be attributed to (1) I_OFF increases due to channel hot electrons trapping at the gate oxide/channel interface and silicon grain boundaries and (2) I_OFF decreases due to hot holes accumulated/trapped near the channel/bottom oxide interface near the source region. Under the stress of high drain bias, serious impact ionization effect will occur to generate hot electrons and hot holes near the drain region. Some of holes will be injected into the gate oxide due to the vertical field (~(V_Gstress V_Dstress)/T _OX) near the drain and the others will be migrated from drain to source along the channel due to lateral electric field (~V_Dstress/L_CH)     

Stability of short-channel P-channel polysilicon thin-filmtransistors with ECR N2O-plasma gate oxide

Stability of hydrogenated short-channel (⩽3 μm) p-channel poly-Si TFT's with very thin (12 nm) electron cyclotron resonance N₂O plasma gate oxide is investigated. The fabricated poly-Si TFT's with gate length not less than 2 μm show excellent stability characteristics of less than 0.1 V in the threshold voltage shift and less than 3% in the percent change of transconductance after harsh electrical stresses. In a small |V_G| stress, an effective shortening of channel length is observed due to trapping of hot-electrons and the minimum leakage current is decreased. However, a large |V_G| stress causes more degradation on the subthreshold slope and minimum leakage current due to trapping of hot-holes     

A unified model for the self-limiting hot-carrier degradation inLDD n-MOSFETs

A new insight into the self-limiting hot-carrier degradation in lightly-doped drain (LDD) n-MOSFETs is presented. The proposed model is based on the charge pumping (CP) measurement. By progressively lowering the gate base level, the channel accumulation layer is caused to advance into the LDD gate-drain overlap and spacer oxide regions, extending the interface that can be probed. This forms the basis of a novel technique, that allows the contributions to the CP current, due to stress-induced interface states in the respective regions, to be effectively separated. Results show that interface state generation initiates in the spacer oxide region and progresses rapidly into the overlap/channel region with stress time. The close correspondence between the linear drain current degradation, measured at high and low gate bias, and the respective interface state generation in the spacer and the overlap/channel regions deduced from CP data, provides an unambiguous experimental evidence that the degradation proceeds in a two-stage mechanism, involving first a series resistance increase and saturation, followed by a carrier mobility reduction. The saturation in series resistance increase results directly from a reduced interface state generation rate in the spacer oxide. For a given density of defect precursors and considering an almost constant channel field distribution near the drain region during stress, interface trap generation rate is shown to exhibit an exponential stress time dependence, with a characteristic time constant determined by the applied voltages. This observation leads to a lifetime extrapolation methodology. Lifetime due to a particular stress drain voltage V_d, may be extracted from a single composite degradation characteristic, obtained by shifting characteristics for various stress V_d's, along the stress time axis, until the characteristics merge into a single curve     

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     

SiO2 degradation with charge injection polarity

We have investigated gate oxide degradation in metal-oxide-semiconductor (MOS) devices as a function of high-field constant-current stress for charge injection from both gate and substrate. The two polarities are asymmetric: gate injection, where the substrate Si-SiO₂ interface is the collecting electrode for the energetic electrons, shows a higher rate of interface-state generation (ΔD_it) and lower charge-to-breakdown Q_bd. Thus the collecting electrode interface, which suffers primary damage, emerges as a critical degradation site in addition to the injecting electrode interface, which has been the traditional focus. Consistent with a physical-damage model of breakdown, we demonstrate that interfacial degradation is an important precursor of breakdown, and that the nature of breakdown-related damage is physical, such as trap-generation by broken bonds     

0.15-$muhboxm$-Gate InAlAs/InGaAs/InP E-HEMTs Utilizing Ir/Ti/Pt/Au Gate Structure

High-current 0.15-mum-gate enhancement-mode high-electron mobility transistors utilizing Ir/Ti/Pt/Au gate metallization were fabricated using a new process including a high-temperature gate anneal that is required for Schottky-barrier height enhancement for the Ir-based gate contact. SiN_x encapsulation was employed to prevent thermal degradation of device layer during the high-temperature gate anneal. Excellent enhancement-mode operation, with a threshold voltage of 0.1 V and I_DSS of 2.1 mA/mm, was realized. Both the annealed and unannealed devices exhibited high g_m,max and I_D,max of 800 mS/mm and 430 mA/mm, respectively. A unity current-gain cutoff frequency f_T of 151 GHz and a maximum oscillation frequency f_MAX of 172 GHz were achieved. From the dc and RF characteristics, it can be deduced that there was no degradation of the gate contact and the heterostructure due to gate annealing. Furthermore, it was found that the gate diffusion during gate annealing was negligible since no increase in g_m,max was observed     

A unified approach to profiling the lateral distributions of bothoxide charge and interface states in n-MOSFET's under various biasstress conditions

A new and accurate technique that allows the simultaneous determination of the spatial distributions of both interface states (N _it) and oxide charge (Q_ox) will be presented. The gated-diode current measurement in combination with the gate-induced drain leakage (GIDL) current were performed to monitor the generation of both N_it and Q_ox in n-MOSFET's. A special detrapping technique and simple calculations have been developed, from which the spatial distributions of both N_it and Q_ox under various bias stress conditions, such as the hot-electron stress (I_G,max), I_B,max, and hot-hole stresses, can be determined. The calculation of gated-diode current by incorporating the extracted profiles of N_it and Q_ox has been justified from numerical simulation. Results show very good agreement with the experimental results. The extracted interface damages for hot-electron and hot-hole stresses have very important applications for the study of hot-carrier reliability issues, in particular, on the design of flash EPROM, E²PROM cells since the above stress conditions, such as the I_G,max and hot-hole stress, are the major operating conditions for device programming and erasing, respectively     

多晶硅后热退火引起SiO_2栅介质可靠性下降的原因分析及其抑制方法

实验研究表明 ,多晶硅后的高温退火明显引起热 Si O2 栅介质击穿电荷降低和 FN应力下电子陷阱产生速率增加 .采用 N2 O氮化则可完全消除这些退化效应 ,而且氮化栅介质性能随着退火时间增加反而提高 .分析认为 ,高温退火促使多晶硅内 H扩散到 Si O2 内同 Si— O应力键反应形成 Si— H是多晶硅后 Si O2 栅介质可靠性退化的主要原因 ;氮化抑制退化效应是由于 N “缝合”了 Si O2 体内的 Si— O应力键缺陷 .     

Role of anode hole injection and valence band hole tunneling on interface trap generation during hot carrier injection stress

Interface trap (N/sub IT/) generation and recovery due to broken /spl equiv/Si-H bonds at the Si/SiO/sub 2/ interface is studied during and after hot carrier injection (HCI) stress and verified by a two-dimensional reaction-diffusion model. N/sub IT/ generation and recovery characteristics do not correlate with channel hot electron (HE) density distribution (verified by Monte Carlo simulations). Anode hole injection, which is triggered by HE injection into the gate poly, and valence band hole tunneling, which is triggered for thinner oxides, must be invoked to properly explain experimental results. The observed hole-induced, not electron-induced, breaking of /spl equiv/Si-H bonds during HCI stress is also consistent with that for negative bias temperature instability stress.     

Effect of a Two-Step Recess Process Using Atomic Layer Etching on the Performance of In0.52Al0.48As/In0.53Ga0.47As p-HEMTs

The characteristics of 0.15- mum InAlAs/InGaAs pseudomorphic high-electron mobility transistors (p-HEMTs) that were fabricated using the Ne-based atomic layer etching (ALET) technology and the Ar-based conventional reactive ion etching (RIE) technology were investigated. As compared with the RIE, the ALET used a much lower plasma energy and thus produced much lower plasma-induced damages to the surface and bulk of the In_0.52AI_0.48As barrier and showed a much higher etch selectivity (~70) of the InP spacer against the In_0.52Al_0.48As barrier. The 0.15-mum InAlAs/InGaAs p-HEMTs that were fabricated using the ALET exhibited improved G_m,max (1.38 S/mm), I_ONn/I_OFF(1.18X10⁴), drain-induced barrier lowering (80 mWV), threshold voltage uniformity (V_th,avg = -190 mV and alpha = 15 mV), and ftau (233 GHz), mainly due to the extremely low plasma-induced damage in the Schottky gate area.     

A study of interface trap generation by Fowler-Nordheim andsubstrate-hot-carrier stresses for 4-nm thick gate oxides

The generation of interface traps by different stresses to 4-nm thick SiO₂ gate oxide is studied. Four different kinds of constant current stresses were applied. The interface-trap density (D _it) generation due to hot holes under V_G<0 Fowler-Nordheim (FN) stress was characterized using quantum-yield measurement and substrate-hot-hole (SHH) stress. The interface-trap density (D_it) generated by SHH stress increases as gate-oxide field increases. Substrate-hot-electron (SHE) stress generates much less interface-trap density (D_it) than SHH stress. It is also observed that N₂O-grown gate-oxide has smaller hole-injection probability but larger electron-injection probability than O₂-grown oxide. N₂O-grown gate oxide is shown to have less SHH stress-induced interface traps than O₂-grown oxide in p-channel metal-oxide-semiconductor field-effect transistor (MOSFET) devices