Random telegraph signal: A sensitive and nondestructive tool for gate oxide single trap characterization

This paper presents the electrical characterization of thick and thin SiO₂ oxynitride performed by thermal and plasma nitridation processes. The impact of the nitridation technique is investigated using random telegraph signal (RTS) noise analysis. The variation of the gate oxide trap characteristics is determined with respect to the nitridation technique. Significant properties of traps are also pointed out. Main trap parameters, such as their depth with respect to the interface, nature, capture and emission times are extracted. These results illustrate the potential of RTS noise investigation for gate oxide characterizations.     

Monitoring plasma-process induced damage in thin oxide

Plasma etching and resist ashing processes cause current to flow through the thin oxide and the resultant plasma-induced damage can be simulated and modeled as damage produced by constant current electrical stress. The oxide charging current produced by plasma processing increases with the `antenna' size of the device structure. Oxide charge measurement such as CV or threshold voltage is a more sensitive technique for characterizing plasma-processing induced damage than oxide breakdown. The oxide charging current is collected only through the aluminum surfaces not covered by the photoresist during plasma processes. Although forming gas anneal can passivate the traps generated during plasma etching, subsequent Fowler-Nordheim stressing causes more traps to be generated in these devices than in devices that have not been through plasma etching. Using the measured charging current, the breakdown voltage distribution of oxides after plasma processes can be predicted accurately. Oxide shorts density of a single large test capacitor is found to be higher than that in a multiple of separated small capacitors having the same total oxide area. This would lead to overly pessimistic oxide defect data unless care is taken     

Post-stress interface trap generation induced by oxide-field stresswith FN injection

Interface trap generation in nMOS transistors during both stressing and post-stress periods under the conditions of oxide field (dynamic and dc) stress with FN injection is investigated with charge pumping technique. In contrast to the post-stress interface trap generation induced by hot carrier stress which is a logarithmical function of post-stress time, the post-stress interface trap generation induced by oxide-field stress with FN injection first increases with post-stress time but then becomes saturated. The mechanisms for the interface trap generation in both stressing and post-stress periods are described     

Device scaling effects on hot-carrier induced interface andoxide-trapped charge distributions in MOSFETs

The influence of channel length and oxide thickness on the hot-carrier induced interface (N_it) and oxide (N_ot) trap profiles is studied in n-channel LDD MOSFET's using a novel charge pumping (CP) technique. The technique directly provides separate N_it and N_ot profiles without using simulation, iteration or neutralization, and has better immunity from measurement noise by avoiding numerical differentiation of data. The N_it and N_ot profiles obtained under a variety of stress conditions show well-defined trends with the variation in device dimensions. The N_it generation has been found to be the dominant damage mode for devices having thinner oxides and shorter channel lengths. Both the peak and spread of the N_it profiles have been found to affect the transconductance degradation, observed over different channel lengths and oxide thicknesses. Results are presented which provide useful insight into the effect of device scaling on the hot-carrier degradation process     

Hot-carrier stress effects on the amplitude of Random Telegraph Signals in small area Si p-MOSFETS

This paper studies the effect of avalanche hot-carrier (HC) stress on the amplitude of pre-existing Random Telegraph Signals (RTSs) in small area Si p-MOSFETs. It is shown that the RTS amplitude of a particular oxide trap increases after HC stress, both in linear operation and in saturation. From this, it is concluded that the effect of such a trap on the carrier transport in a small area MOSFET is also determined by the charges present at the interface and in the oxide. The impact of the observations on the RTS based modeling of flicker noise in MOSFETs will be briefly addressed.     

In-depth exploration of Si-SiO2 interface traps in MOStransistors using the charge pumping technique

It is shown that the charge pumping (CP) technique can be used for extraction of the depth concentration profile of traps situated in the oxide of metal-oxide-semiconductor (MOS) transistors, near and at the Si-SiO₂ interface. The trap density is obtained from the variation of the charge pumping current as a function of frequency, the other measurement parameters being kept constant. The concentration profiles are measured on n and p-channel transistors from several technologies, and on virgin and stressed devices. The results show that the trap concentration decreases rapidly from the Si-SiO₂ interface in the direction of the oxide depth and suggest that it becomes constant at a fraction of a nanometer from the silicon interface. The method easily demonstrates the trap creation due to Fowler-Nordheim stress. The profiles compare favorably with those measured using a new drain-current transient technique. In all cases, the integration of the depth concentration profiles leads to the interface trap densities measured using the conventional charge pumping method     

Low-Frequency Noise Assessment of Silicon Passivated Ge pMOSFETs With TiN/TaN/ HfO2 Gate Stack

The low-frequency noise of pMOSFETs fabricated in epitaxial germanium-on-silicon substrates is studied. The gate stack consists of a TiN/TaN metal gate on top of a 1.3-nm equivalent oxide thickness HfO₂/SiO₂ gate dielectric bilayer. The latter is grown by chemical oxidation of a thin epitaxial silicon film deposited to passivate the germanium surface. It is shown that the spectrum is of the 1/f^gamma type, which obeys number fluctuations for intermediate gate voltage overdrives. A correlation between the low-field mobility and the oxide trap density derived from the 1/f noise magnitude and the interface trap density obtained from charge pumping is reported and explained by considering remote Coulomb scattering     

Interface trap generation by FN injection under dynamic oxide fieldstress

Interface trap generation under dynamic (bipolar and unipolar) and dc oxide field stress has been investigated with the charge pumping technique. It is observed that regardless of stress type, whether dc or dynamic (bipolar or unipolar), and the polarity of stress voltage, interface trap generation starts to occur at the voltage at which Fowler-Nordheim (FN) tunneling through the oxide starts to build up. For positive voltage, interface trap generation is attributed to the recombination of trapped holes with electrons and to the bond breaking by the hydrogen (H and H⁺) released during stressing. For negative voltage, in addition to these two mechanisms, the bond breaking by energetic electrons may also contribute to interface trap generation. The frequency dependence of interface trap generation is also investigated. Interface trap generation is independent of stressing frequency for unipolar stress but it shows a frequency dependence for bipolar stress     

Gate oxide damage reduction using a protective dielectric layer

Gate oxide damage from charge entering through the top surface of the gate electrode during plasma ashing, ion implantation, and LDD spacer oxide etching was measured using antenna structures. Significant charge damage to the 9.0 nm-thick gate oxide was detected for each of these processes. The damage was reduced by using a protective dielectric layer, in this case a thermally deposited TEOS oxide over the polycide gate electrode before gate definition. The dielectric appears to block charge penetration into the antenna. Damage can be reduced further by increasing the thickness of the dielectric layer; for a sufficiently thick layer (about 150 nm), charge entering through the top surface of the antenna was effectively eliminated     

Fowler-Nordheim stress degradation in gate oxide: results fromgate-to-drain capacitance and charge pumping current

The buildup of positive oxide charge and interface trap charge, due to Fowler-Nordheim stress, is observed in the gate-drain overlap region of the MOSFET. Results from gate-to-drain capacitance and charge pumping current show a steady increase in positive charge near the anode interface. Interface trap generation becomes significant when injected electron fluence exceeds ~10¹⁴ cm^-2, and dominates net charge creation at higher fluence     

Random telegraph noise in SiGe HBTs: Reliability analysis close to SOA limit

In this paper, we present extensive random telegraph signal (RTS) noise characterization in SiGe heterojunction bipolar transistors. RTS noise, observed at the base, originates at the emitter periphery while at the collector side distinct RTS noise is observed at high-injection that originates from the traps in the shallow trench regions. Time constants extracted from RTS during aging tests allow understanding of trap dynamics and new defect formation within the device structure. This paper provides the first demonstration of RTS measurements during accelerated aging tests to study and understand generation of defects under bias stress in SiGe HBTs operating at the limit of their safe-operating area.     

Spatial distribution of interface traps in DeMOS transistors

The spatial distribution of interface traps in a p-type drain extended MOS transistor is experimentally determined by the analysis of variable base-level charge pumping spectra. The evolution of the interface trap distribution can be monitored as a function of the hot-carrier stress time. A double peaked interface trap density distribution, located in the spacer oxide, is extracted. The interface trap density in the poly overlapped drift region is constant as a function of stress time. No channel degradation is observed.     

A comprehensive study of hot-carrier induced interface and oxidetrap distributions in MOSFETs using a novel charge pumpingtechnique

A novel simulation-independent charge pumping (CP) technique is employed to accurately determine the spatial distributions of interface (N_it) and oxide (N_0t) traps in hot-carrier stressed MOSFETs. Direct separation of N_it and N_0t is achieved without using simulation, iteration, or neutralization. Better immunity from measurement noise is achieved by avoiding numerical differentiation of data. The technique is employed to study the temporal buildup of damage profiles for a variety of stress conditions. The nature of the generated damage and trends in its position are qualitatively estimated from the internal electric field distributions obtained from device simulations. The damage distributions are related to the drain current degradation and well-defined trends are observed with the variations in stress biases and stress time. Results are presented which provide fresh insight into the hot-carrier degradation mechanisms     

Investigation of oxide charge trapping and detrapping in a MOSFETby using a GIDL current technique

We proposed a new measurement technique to investigate oxide charge trapping and detrapping in a hot carrier stressed n-MOSFET by measuring a GIDL current transient. This measurement technique is based on the concept that in a MOSFET the Si surface field and thus GIDL current vary with oxide trapped charge. By monitoring the temporal evolution of GIDL current, the oxide charge trapping/detrapping characteristics can be obtained. An analytical model accounting for the time-dependence of an oxide charge detrapping induced GIDL current transient was derived. A specially designed measurement consisting of oxide trap creation, oxide trap filling with electrons or holes and oxide charge detrapping was performed. Two hot carrier stress methods, channel hot electron injection and band-to-band tunneling induced hot hole injection, were employed in this work. Both electron detrapping and hole detrapping induced GIDL current transients mere observed in the same device. The time-dependence of the transients indicates that oxide charge detrapping is mainly achieved via field enhanced tunneling. In addition, we used this technique to characterize oxide trap growth in the two hot carrier stress conditions. The result reveals that the hot hole stress is about 10⁴ times more efficient in trap generation than the hot electron stress in terms of injected charge     

A BSIM3-based flat-band voltage perturbation model for RTS and 1/fnoise

Recently, a new random telegraph signal (RTS) noise model for the drain current fluctuations (ΔI_d) associated with single-carrier trapping and detrapping has been developed from a flat-hand voltage perturbation (ΔV_fb) of the BSIM3 current-voltage (I-V) model (Martin et al., 1997). The model's accuracy in predicting the gate bias and geometry dependence of RTS magnitudes has been verified and summarized. In this letter, the perturbation model has been extended to yield a new formulation for the scattering coefficient (α) which predicts the magnitude and bias dependence of 1/f noise without fitting parameters. The absence of fitting parameters allows for a direct determination of the oxide trap density (N_t(E_fn)) from 1/f noise measurements. Results suggest that the BSIM3-based model accurately predicts the bias and geometry dependence of 1/f noise, that N₂O annealing may significantly increase the oxide trap density at strong inversion and that the bias dependence of N_t(E_fn) contains most of the 1/f noise dependence upon V_g     

Resist-related damage on ultrathin gate oxide during plasma ashing

This paper presents an important observation of plasma-induced damage on ultrathin oxides during O₂ plasma ashing by metal “antenna” structures with photoresist on top of the electrodes. It is found that for MOS capacitors without overlying photoresist during plasma ashing, only minor damage occurs on thin oxides, even for oxide thickness down to 4.2 nm and an area ratio as large as 10⁴. In contrast, oxides thinner than 6 nm with resist overlayer suffer significant degradation from plasma charging. This phenomenon is contrary to most previous reports. It suggests that the presence of photoresist will substantially affect the plasma charging during ashing process, especially for devices with ultrathin gate oxides     

Modeling of oxide breakdown from gate charging during resist ashing

Plasma damage was observed after exposing an antenna capacitor structure to an O₂ plasma in a single wafer resist asher. The observed early breakdown is well modeled by surface charging caused by plasma nonuniformity. Here, the plasma nonuniformity was induced by gas flow and electrode configuration. The present results agree well with our previous results where magnetic field leads to a nonuniform plasma. In this model, nonuniformity leads to a local imbalance of ion and electron currents which charge up the gate surface and degrade the gate oxide. Using SPICE, a circuit model for the test structure and plasma measurements, the Fowler-Nordheim current through the thin oxide regions at different points on the wafer was calculated and found to agree well with the observed damage. The important implication of this work on oxide reliability is that the modeling gives a clear picture to this breakdown mechanism. The charging model can also be applied to any ashing process in any nonuniform plasma. Moreover, this model provides a physical basis for design rules of device structures for the fabrication of reliable gate oxides in submicron MOS technology     

Traps centers impact on Silicon nanocrystal memories given by Random Telegraph Signal and low frequency noise

This work reports on a comprehensive process of trapping centers in Silicon nanocrystal (nc-Si) memories devices. The trap centers have been studied using Random Telegraph Signal (RTS) and Low Frequency (LF) techniques. The study of the traps which are responsible for RTS noise in non-volatile memories (NVM) devices as a function of gate voltage and temperature, offers the opportunity of studying the trapping/detrapping behaviour of a single interface trap center. The RTS parameters of the devices having random discrete fluctuations in the drain current get more information about trap energy level and spatial localization from the SiO₂/Si interface. The impact of trap centers has been also investigated showing the significant noise between memories and references devices. Furthermore, it has convincingly been shown that this discrete switching of the drain current between a high and a low state is the basic feature responsible for l/f^γ flicker noise in MOSFETs transistors.     

Hole trap generation in the gate oxide due to plasma-inducedcharging

The paper presents results of hole trapping studies in-thin gate oxide of plasma damaged MOS transistors. Process-induced damage was investigated with antenna test structures to enhance the effect of plasma charging. In addition to neutral electron traps and passivated interface damage, which are commonly observed plasma charging latent damage, we observed and identified hole traps, generated by plasma stress. The amount of hole traps increases with increasing antenna ratio, indicating that the mechanism of hole trap generation is based on electrical stress and current flow, forced through the oxide during plasma etching. The density of hole traps in the most damaged devices was found to be larger than that in reference, undamaged devices by about 100%     

On the tunneling component of charge pumping current in ultrathingate oxide MOSFETs

A simple method is described for separating the charge pumping current from the parasitic tunneling component in a charge pumping measurement performed on MOS transistors with ultrathin (<2 nm) gate oxide thickness. The method is presented here for a two-level charge pumping signal and can be used to significantly increase the accuracy of the technique to extract interface trap parameters in tunnel MOS devices