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     

GIDL current degradation in LDD nMOSFET under hot hole stress

The degradation of gate-induced drain leakage（GIDL） current in LDD nMOSFET under hot holes stress is studied in depth based on its parameter I_DIFF.I_DIFF is the difference of GIDL currents measured under two conditions of drain voltage V_D=1.4 V and gate voltage V_G=-1.4 V while V_DG is fixed.After the stress GIDL currents decay due to holes trapping in the oxide around the gate-to-drain overlap region.These trapped holes diminishΔE_X which is the deference of the lateral electrical field of these two symmetrical measurement conditions in the overlap region so as to make I_DIFF lessening.I_DIFF extracted from GIDL currents decreases with increasing stress time t.The degradation shifts of I_DIFF,MAX(ΔI_DIFF,MAX) follows a power law against t:ΔI_DIFF,MAX∝t^m, m= 0.3.Hot electron stress is performed to validate the related mechanism.     

Hot-carrier stress effects on gate-induced-drain leakage current in n-channel MOSFETs studied by hydrogen/deuterium isotope effect

The degradation of gate-induced-drain leakage (GIDL) current under hot-carrier stress (HCS) has been studied in n-channel MOSFETs that were annealed in hydrogen (H) or deuterium (D). It is found that the degradation of GIDL current (I/sub GIDL/) can be effectively suppressed by deuterium passivation of interface traps. By using the H/D isotope effect, the impacts of oxide charge trapping (/spl Delta/N/sub ox/) and interface trap generation (/spl Delta/N/sub it/) on I/sub GIDL/ are successfully separated. The results indicate that, depending on stress and measurement conditions, I/sub GIDL/ may increase or decrease under HCS. /spl Delta/N/sub ox/ alters I/sub GIDL/ at high electric fields by varying the band-to-band tunneling current. /spl Delta/N/sub it/ alters I/sub GIDL/ at a low electric field by introducing a trap-assisted leakage component. Furthermore, evidence of hole trapping at the peak substrate current stress is indisputably presented for the first time and its impact on I/sub GIDL/ is discussed.     

Characterization of various stress-induced oxide traps in MOSFET'sby using a subthreshold transient current technique

An oxide trap characterization technique by measuring a subthreshold current transient is developed. This technique consists of two alternating phases, an oxide charge detrapping phase and a subthreshold current measurement phase. An analytical model relating a subthreshold current transient to oxide charge tunnel detrapping is derived. By taking advantage of a large difference between interface trap and oxide trap time-constants, this transient technique allows the characterization of oxide traps separately in the presence of interface traps. Oxide traps created by three different stress methods, channel Fowler-Nordheim (F-N) stress, hot electron stress and hot hole stress, are characterized. By varying the gate bias in the detrapping phase and the drain bias in the measurement phase, the field dependence of oxide charge detrapping and the spatial distribution of oxide traps in the channel direction can be obtained. Our results show that 1) the subthreshold current transient follows a power-law time-dependence at a small charge detrapping field, 2) while the hot hole stress generated oxide traps have a largest density, their spatial distribution in the channel is narrowest as compared to the other two stresses, and 3) the hot hole stress created oxide charges exhibit a shortest effective detrapping time-constant     

Gate-induced drain leakage current degradation and its time dependence during channel hot-electron stress in n-MOSFETs

The effects of channel hot-electron stress on the gate-induced drain leakage current (GIDL) in n-MOSFETs with thin gate oxides have been studied. It is found that under worst case stress, i.e. a high density of generated interface states Delta D/sub it/, the enhanced GIDL exhibits a significant drain voltage dependence. Whereas Delta D/sub it/ increases significantly the leakage current at low V/sub d/, it has minor effects at high V/sub d/. On the other hand, the electron trapping was found to increase the leakage current rather uniformly over both low and high V/sub d/ regions. In addition, GIDL degradation can be expressed as a power law time dependence (i.e. Delta I/sub leak/=A.t/sup n/), and the time dependence value n varies according to the dominant damage mechanism (i.e. electron trapping against Delta D/sub it/), similar to that reported for on-state device degradation.<>     

Examination of the time power law dependencies in hot carrierstressing of n-MOS transistors

The origins of the different power laws arising from hot carrier stressing at low and high gate voltages are examined. It is found that damage at V_g=V_d (predominantly electron trapping in the oxide) has the same underlying 0.5 power law exponent dependence as stress under I_b(max) (interface state creation) conditions, if degradation is measured as a function of injected electronic charge instead of time. It is proposed that the reduced gradient normally seen under V_g=V_d stresses arises due to the repulsive electrostatic oxide fields created by the trapped oxide charge and does not reflect the fundamental rate of trap creation. Stressing at low gate voltages (V_g=V_d/5) also reveals the presence of a similar time power law of exponent 0.5 when the oxide trap contribution alone is separated out from the rest of the damage. It is concluded that the 0.5 power law appears to be the fundamental underlying kinetic equation that is seen throughout the gate voltage stress range, despite the different types of damage and the very different trap creation mechanisms     

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.     

Hot-carrier-stress effects on gate-induced drain leakage current inn-channel MOSFETs

The effects of hot-carrier stress on gate-induced drain leakage (GIDL) current in n-channel MOSFETs with thin gate oxides are studied. It is found that the effects of generated interface traps (ΔD _it) and oxide trapped charge on the GIDL current enhancement are very different. Specifically, it is shown that the oxide trapped charge only shifts the flat-band voltage, unlike ΔD _it. Besides band-to-band (B-B) tunneling, ΔD _it introduces an additional trap-assisted leakage current component. Evidence for this extra component is provided by hole injection. While trapped-charge induced leakage current can be eliminated by a hole injection subsequent to stress, such injection does not suppress interface-trap-induced leakage current     

Excellent immunity of GIDL to hot-electron stress in reoxidizednitrided gate oxide MOSFET's

The authors present an investigation of the enhancement in gate-induced drain leakage (GIDL) caused by hot-electron stress in MOSFETs with control oxides, nitrided oxides, and reoxidized nitrided oxides as gate dielectrics. The contributions of interface state generation and electron trapping to GIDL enhancement in these MOSFETs were compared based on stress condition and stress time dependencies. Although no improvement resulted at large drain biases, under low drain voltage conditions, reoxidized nitrided oxides exhibited less GIDL enhancement under hot-electron stress than a nitrided oxide that was not reoxidized     

Oxide thickness dependence of nitridation effects on TDDB characteristics

Wet oxide thicknesses dependence of nitridation effects on electrical characteristics, charge trapping properties and TDDB (Time Dependent Dielectric Breakdown) characteristics have been investigated. It is found that the difference of conduction current between the wet and nitrided wet oxide increases with increasing oxide thickness both for negative and positive bias to the gate until constant current stress is applied. After the stress, with decreasing oxide thickness both in wet and nitrided wet oxide leakage current increases. Up to 60 Å no difference was observed between the wet and nitrided wet oxide but at 50 Å nitrided wet oxide has less increase of current comparing to the wet oxide for the same stress. In wet oxide with increasing stress current density initial hole trap decreases but electron trap increases whereas in nitrided wet oxide has less initial hole trap and also electron trap is less comparing to the wet oxide. Both in wet and nitrided wet oxide for negative bias stress, time to 50 % breakdown decreases with decreasing thickness but at 50 Å a turn-around effect was observed due to nitridation i.e., the 50 % breakdown time is greater for nitrided wet oxide comparing to the wet oxide. On the contrary, for positive bias stress 50 % breakdown time increases with decreasing oxide thickness both in wet and nitrided wet oxide. For positive bias also a turn-around effect is observed at 50 Å i.e., 50% breakdown time is less in nitrided wet oxide comparing to the wet oxide. The improved reliability of nitrided wet oxide at the thin region of 50 Å seems to be due to the increase of more Si---N bond to the interface of oxide and Si comparing to the thick oxide of above 60 Å for the same nitridation conditions.     

Hot electron induced degradation of undoped AlGaN/GaN HFETs

This work presents the effects of hot electron stress on the degradation of undoped Al_0.3GaN_0.7/GaN power HFET’s with SiN passivation. Typical degradation characteristics consist of a decrease in the drain current and maximum transconductance, an increase in the drain series resistance, gate leakage and a subthreshold current. Degradation mechanism has been investigated by means of gate lag measurements (pulsed I-V) and current-mode deep level transient spectroscopy (DLTS). Stressed devices suffered from aggravated drain current slump (DC to RF dispersion) which indicates possible changes in surface charge profiles occurred during hot electron stress test. The DLTS was used to identify the trap creation by hot electron stress. The DLTS spectra of stressed device revealed the evidence of trap creation due to hot electron stress.     

Determination of trapped oxide charge in flash EPROMs and MOSFETswith thin oxides

A technique for determining the sign and the effective density of the trapped oxide charge near the junction transition region, based on the measurement of the gate-induced drain leakage (GIDL) current, is used to investigate the hot-carrier effects resulting from the erase operation and bit-line stress in flash EPROM devices. While the trapped oxide charge depends on the stress conditions, it has been found that a significant amount of hole trapping is likely when a sufficiently large potential difference exists between the gate and junction for either an abrupt or graded junction     

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     

Investigation of channel hot electron injection by localized charge-trapping nonvolatile memory devices

A novel measurement method to extract the spatial distribution of channel hot electron injection is described. The method is based on characterization of localized trapped-charge in the nitride read-only memory (NROM) device. The charge distribution is determined by iteratively fitting simulated subthreshold and gate induced drain leakage (GIDL) currents to measurements. It is shown that the subthreshold and the GIDL measurements are sensitive to charge trapped over the n+ junction edge. Their characteristics are determined by the trapped charge width, density and location and the associated fringing field. Extremely high sensitivity of the GIDL measurement to localized charge over the n+ junction is demonstrated. The extracted charge distribution width is shown to be /spl sim/40 nm, located over the junction edge.     

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     

Characterization of hot-hole injection induced SILC and relateddisturbs in flash memories

In this paper, we have proposed a new method for the study of disturb failure mechanisms caused by stress induced leakage current (SILC) in source-side erased flash memories. This method is able to directly separate the individual components of SILC due to either carrier charging/discharging in the oxide or the positive charge/trap assisted electron tunneling into the floating gate. In addition, the present method is very sensitive with capability of measuring ultralow current (<10^-19 A). Results show that, at low oxide field, the disturb is mainly contributed by the so-called charging/discharging of carriers into/from the oxide due to the capacitance coupling effect. While at high oxide field, the positive charge/trap assisted electron tunneling induced floating-gate charge variation is the major cause of disturb failure     

GIDL应力下超薄栅氧LDD NMOS器件退化

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.     

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.     

Enhanced negative substrate bias degradation in nMOSFETs with ultrathin plasma nitrided oxide

The degradation induced by substrate hot electron (SHE) injection in 0.13-/spl mu/m nMOSFETs with ultrathin (/spl sim/2.0 nm) plasma nitrided gate dielectric was studied. Compared to the conventional thermal oxide, the ultrathin nitrided gate dielectric is found to be more vulnerable to SHE stress, resulting in enhanced threshold voltage (V/sub t/) shift and transconductance (G/sub m/) reduction. The severity of the enhanced degradation increases with increasing nitrogen content in gate dielectric with prolonged nitridation time. While the SHE-induced degradation is found to be strongly related to the injected electron energy for both conventional oxide , and plasma-nitrided oxide, dramatic degradation in threshold voltage shift for nitrided oxide is found to occur at a lower substrate bias magnitude (/spl sim/-1 V), compared to thermal oxide (/spl sim/-1.5 V). This enhanced degradation by negative substrate bias in nMOSFETs with plasma-nitrided gate dielectric is attributed to a higher concentration of paramagnetic electron trap precursors introduced during plasma nitridation.     

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