Trapping Effects in the Transient Response of AlGaN/GaN HEMT Devices

José María Tirado, José Luis Sánchez-Rojas, and José Ignacio Izpura

Copyright © 2007 IEEE.
Reprinted from IEEE Transactions on Electron Devices,
VOL 54, NO 3, March 2007.

Manuscript received June 15, 2006; revised December 15, 2006. This work was supported in part by Junta de Comunidades de Castilla-La Mancha under Project PAC-05-001-2 and by Escuela Universitaria de Ingeniería Técnica Industrial (EUITI) de Toledo. The review of this paper was arranged by Editor M. Anwar.

J. M. Tirado is with the Department of Electrical, Electronic, Control and Communications Engineering, University of Castilla-La Mancha, 45071 Toledo, Spain (e-mail: JoseMaria.Tirado@uclm.es).

J. L. Sánchez-Rojas is with the Department of Electrical, Electronic, Control and Communications Engineering, University of Castilla-La Mancha, 13071 Ciudad Real, Spain (e-mail: JoseLuis.SanchezRojas@uclm.es).

J. I. Izpura is with the Department of Electronic Engineering, Universidad Politécnica de Madrid, 28040 Madrid, Spain (e-mail: izpura@die.upm.es).

Digital Object Identifier 10.1109/TED.2006.890592

Abstract

In this paper, the transient analysis of an AlGaN/GaN high-electron mobility transistor (HEMT) device is presented. Drain–current dispersion effects are investigated when gate or drain voltages are pulsed. Gate-lag and drain-lag turn-on measurements are analyzed, revealing clear mechanisms of current collapse and related dispersion effects. Numerical 2-D transient simulations considering surface traps effects in a physical HEMT model have also been carried out. A comparison between experimental and theoretical results is shown. The presence of donor type traps acting as hole traps, due to their low energy level of 0.25 eV relative to the valence band, with densities > 1e20 cm^-3 (> 5e12 cm^-2), uniformly distributed at the HEMT surface, and interacting with the free holes that accumulated at the top surface due to piezoelectric fields, accounts for the experimentally observed effects. Time constants close to 10 ms are deduced. Some additional features in the measured transient currents, with faster time constants, could not be associated with surface states.

Index Terms

AlGaN/GaN high-electron mobility transistor (HEMT), current collapse, device simulation, dispersion effects, donor traps, drain lag, gate lag, hole traps, surface states, trapping effects.

I. INTRODUCTION

The great interest raised by AlGaN/GaN high-electron mobility transistors (HEMTs) in the international semiconductor scientific community in general, for high-frequency, high-power, and high-temperature applications, has resulted in that an important number of researchers and centers in the world are nowadays mainly devoted to this new technology. However, there are still some problems in the production of GaN-based devices. The existence of dispersion effects observed in wide-bandgap devices has limited the initial expectations. The considerable list of advantages attributed to devices based on group-III nitrides in the last decade, due to their excellent properties, is partially limited by these negative effects. Great efforts are being dedicated to their understanding and their possible elimination or, at least, minimization.

The presence of trapping centers in FETs based on III–V compounds, related to surface, material, and/or interface states, has been considered as the main cause of these effects [1]–[15], already studied in other technologies. Some of the observed effects are threshold voltage shift [5], [16], current collapse [1], [2], [4], [5], [7]–[9], [11], [12], [14]–[16], reduction of short channel effect [16], light sensitivity [1]–[5], [8], [11], transconductance frequency dispersion [12], [17], gate-lag and drain-lag transients [2], [3], [7], and limited microwave power output [7], [12]. Current collapse—understood as a transient and recoverable reduction in drain–current response—in GaN devices has been associated mainly to the finite time required by surface traps to respond to an external voltage step. Although its origin is under debate, it seems to be induced by process damage—plasma and thermal—which generates nitrogen vacancies [18]. The filling and emptying of traps would change the density of surface charge in the semiconductor and influence the recombination statistics. These parasitic effects, commonly observed in GaN FETs, have been reported by several authors [1]–[6], [11], [13]–[15], [17], and hence, it is very important to include them in physical models in order to fit more exactly the operation of real devices.

In this paper, current collapse is characterized in AlGaN/ GaN HEMT by means of pulsed measurements based on gate-lag and drain-lag turn-on techniques. Our measurements suggest that the dispersion effects are characterized by fast time constants—due to surface states—and also, very fast time constants are identified. Two-dimensional numerical device simulations are performed to analyze the influence of surface states on the pulsed characteristics of an AlGaN/GaN HEMT device.

It is demonstrated that the current collapse effect originated from temporary variations in the concentration of donor traps ionized in both regions next to the gate contact (i.e., S–G and also D–G) due to the existence of density of traps lower than the polarization charge and higher depending on the test conditions, mainly when the gate-lag technique is employed.

The activation energy of traps (0.25 eV) is deduced consistently from two experimental techniques by following a fitting procedure through semilogarithmic curves between experimental and theoretical results, obtained from our 2-D physical model.

This paper shows the transient evolution of donor traps ionized and holes at the surface after the transient step voltage is applied, employing the two discussed techniques. It is suggested that the additional fast time constants observed in our results would be related with other mechanisms other than surface states due to the clear transient response obtained also in this case from our theoretical 2-D model in comparison with experimental results.

Section II is devoted to the analyzed structure and the method of analysis. Section III includes the physical model, the surface state model, and the basic equations employed for the analysis. The theoretical charge model and the nature, density, and energy level of traps are also considered there. In Section IV, a comparison between experimental results and theoretical data obtained by simulation is made. In Section V, the results are discussed and explained in detail with the time evolution and distribution of charges at surface (i.e., ionized traps and holes) when both techniques (i.e., gate lag and drain lag) are employed. Finally, conclusions are included in Section VI.

II. DEVICES AND EXPERIMENTAL SETUP

The Al_0.36Ga_0.64/GaN heterostructure analyzed in this paper is presented in Fig. 1. It was passivated with a 70-nm-thick SiN layer and deposited at 350 oC. It was grown by low-pressure metal–organic vapor phase epitaxy on a c-plane sapphire substrate starting with an undoped 1.9- and 0.2-µm-thick high-resistivity GaN multilayer buffer template, a 0.9-µm-thick GaN top layer, and a 200-Å AlGaN barrier with a composition of 36% in aluminum. In the interlayered buffer heterojunctions, two 20-nm-thick low-temperature AlN layers separated by a 0.5-µm GaN layer were first deposited [19] prior to the growth of the 0.9-µm-thick top buffer and the AlGaN barrier. The gate length is L_G = 5 µm, the gate width is L_W = 75 µm, and the separation between contacts were L_GS = 1.5 µm and L_GD = 2 µm.

Fig . 1 Schematic cross section of the studied AlGaN-GaN HEMT. Figure not to scale.

In Fig. 2, the widely used gate-lag and drain-lag measurement techniques [2], [3], [7], [16], [20] employed in this paper are presented. In our computational 2-D model, the current sensing resistance used in the measurement circuit is taken into account as part of the source contact resistance.

Fig. 2. Experimental set up for the different turn-on pulsed methods. (a) Gate-lag turn-on measurement technique: fixed voltage applied to the drain terminal (10 V), and the gate pulsed from pinchoff to open channel condition (from –8 to 0 V, respectively). (b) Drain-lag turn-on measurement technique: fixed voltage applied to the gate (0, V) and the drain pulsed from OFF-state to open channel condition (from 0 to ~ +10 V, respectively).

A. Gate-Lag Turn-On Measurement Technique
A transient voltage step is applied to the gate terminal, maintaining a fixed drain bias of V_D = 10 V; the HEMT device is driven under this situation from the initial pinchoff to an open channel condition—V_GS = -8 V and ~0 V, respectively. The drain–current transient (i.e., gate lag) versus time is registered and analyzed.

B. Drain-Lag Turn-On Measurement Technique
A transient voltage step is applied to the drain terminal, maintaining a fixed gate bias of V_G = 0 V; the HEMT device is driven under this situation from the initial OFF-state to an open channel condition—V_D = 0 V and ~ 10 V, respectively. The drain–current transient (i.e., drain lag) versus time is registered and analyzed.

In this paper, a stress drain voltage of V_DS ~ 10 V is employed in the two techniques. The electrical stress effect on the transient characteristics has been suggested in [21], where the dispersion characteristics are found to be bias dependent, which is associated with the drain bias dependence of trapped carrier concentration. The measurement set up was built by using an Agilent 33250A 80-MHz Function/Arbitrary Waveform generator for gate and drain pulsing, the pulse rise time in both cases was next to 20–30 ns, and a power supply to maintain V_D = 10 V in the first case was employed. An Agilent 54642A digital oscilloscope (two-channel 500-Mhz bandwidth, 2 Gsa/s, and MegaZoom technology) is employed to register the excitation signals and the drain response in both cases.

III. PHYSICAL MODEL AND METHOD OF ANALYSIS

The 2-D device simulator used in this paper was Silvaco ATLAS [22]. Basic equations to be solved are the Poisson equation including the contribution of mobile and fixed charges and ionized traps, the carrier continuity equations for electrons and holes, and the transport equations using the drift-diffusion model. The dynamic traps are modeled by a Shockley–Read–Hall recombination term, included in the continuity equations. An additional differential rate equation is solved to account for emission and capture processes in transient trap simulations. In this paper, carrier lifetimes are controlled by capture cross sections.

The device structure corresponding to the AlGaN/GaN HEMT, modeled and simulated, corresponds to the scheme in Fig. 1 and the same dimensions of the device analyzed in Section II. Various dielectric materials on the surface were considered in the simulations. As expected, the dielectric properties of the layer do not appreciably change our results and conclusions, which certainly depend on the trap parameters considered. The electron GaN mobility measured in the studied heterostructure was next to 1100 cm²/V . s, and this value has also been maintained in our simulation model. The GaN hole mobility assumed in our model was 30 cm2/V . s [23]. Mobilities of 100 and 5 cm²/V . s were used in AlGaN for electrons and holes, respectively. Saturation velocities for electron and holes in GaN were taken as vsatn = 1.91e7 cm/s and vsatp = 1e6 cm/s, respectively, according to Monte Carlo fits [22], [24]. Saturation velocities for electron and holes in AlGaN were linearly interpolated from the binaries [22].

The built-in fields due to spontaneous polarization and strain (piezoelectric effect) are taken into account as fixed sheet charges at the AlGaN surface and AlGaN/GaN interface. A positive sheet charge -_pol with density +1.5e13 cm^-2 was defined at the interface, and the equivalent negative sheet charge -_pol was defined at the AlGaN surface. Newton numerical method was used in the models for calculations, and a temperature of 300 K was employed by default in the simulations. Surface states are included through a fixed donor trap density _T , uniformly distributed on the regions between source and gate and between gate and drain. A depth of 5 Å [25] is considered, which allows to translate volume densities into sheet densities. This charge is added to the space charge term in Poisson’s equation [22]. Although in the analyzed structure a sapphire substrate was employed, and obviously self-heating effects could be a very important aspect to consider as has been suggested by other authors [20], [21], in order to avoid selfheating effects, we have employed a low drain bias (VDS ~ 10 V), and short-time voltage steps were applied to the analyzed device (£ 10 ms).

Similar to the experimental test conditions discussed in Section II, a turn-on step voltage (£ 10 ns) is applied to the gate terminal (from V_GS = -8 to 0 V), maintaining a fixed drain bias of V_D = 10 V. The drain–current transient (gate lag) versus time is analyzed. Analogously and independently, a turn-on step voltage (< 10 ns) is applied to the drain terminal (from V_DS = 0 to 10 V), maintaining a fixed gate bias of V_G = 0 V. The drain–current transient (drain lag) versus time is also analyzed.

A basic graphical scheme of space charge components in a HEMT device [10], [11], [25] is presented in Fig. 3. Our physical model includes a fixed dipole charge due to polarization induced charges -_pol at the AlGaN surface and +-_pol at the AlGaN/GaN interface, charge due to the 2-D electron gas _2DEG next to the AlGaN/GaN interface, charge due to donor-trap ionization (DTI) -_DTI when donor-type traps are considered at the AlGaN surface, and charge due to holes accumulation next to the AlGaN surface _holes. Additional sources of charge, due to traps in locations other than the AlGaN surface, such as bulk GaN, AlGaN barrier material, or even AlGaN/GaN interface, have not been included.

Fig. 3. Scheme of space charge components in a HEMT device considering ±pol (dipole charge due to polarization-induced charges), 2DEG (charge due to the 2-D electron gas), holes (charge due to holes accumulation next to AlGaN surface), and DTI (charge due to DTI).

The surface states assumed in the model are a key variable since the device response is determined by their magnitude. As shown below, reasonable values, coherent with the measured curves, for the density of donor traps were _T1 = 1.5e20 cm^-3 and _T2 = 3.8e20 cm^-3 by following a fitting procedure to the experimental behavior; the degeneracy factor was 1.0, and capture cross sections of the traps for electrons and holes assumed were _n = _p = 1e - 19 cm²; similar orders of magnitude are found in the literature employing sapphire substrates [26]. The energy level of traps employed in our simulations was 0.25 eV, relative to the valence band, as will be discussed in the next section.

IV. EXPERIMENTAL AND NUMERICAL RESULTS

In this section, the experimental results obtained by the electrical characterization techniques discussed in Section II are presented. A comparison is also made with numerical simulations, according to the physical model seen in Section III.

A. Gate-Lag Turn-On Pulsing Mode
Fig. 4 shows the drain–current response using the gate-lag technique, as shown in Fig. 2(a). Two different behaviors are identified in the transient response, depending on the relative times involved.

1. In the first case, the device is analyzed starting from an initial situation under relaxed conditions—without electrical excitation applied for at least several minutes. In this situation, a step voltage Vg1 (dashed line) is applied to the gate terminal—with a rising edge time next to 30 ns. The drain–current registered (gate lag) is presented in the plot as ID1 (solid line). As clearly observed, the HEMT device initially presents a fast transition in current response during the first 30 ns, trying to follow with the same edge the evolution of the applied stimulus Vg1, as expected. Far from the desirable behavior, an initial decrease in current next to 15% (current collapse)—see arrow labeled as ΔI_D1 in the plot—is observed. Later on, during a transient evolution, a noticeable increase in current delay is obtained. Current response suffers a lapsed time next to approximately six decades since the step voltage V_g1 was applied. Finally, a steady-state condition is achieved for t ≥ 10 ms, maintaining I_D1 almost constant with time.
   
2. Also in Fig. 4, a second situation is analyzed. Immediately after several step voltages are applied at the gate terminal, a subsequent step voltage V_g2 (dashed line) is applied, and the current response registered (ID2 curve). In this second case, an initial current collapse next to 27% is observed—see ΔI_D2 arrow in the plot—with the transient response similar to the previous case. The little differences between V_g1 and V_g2 are due to jitter effects in the pulse generator. The differences in the results of the above different excitation conditions are discussed next.
   

The calculated curves for the transient current responses are also plotted in Fig. 4. By following a fitting procedure in our theoretical model, the two previously analyzed cases are modeled. As shown, considering case 1, both I_D1 curves, experimental (solid line) and theoretical (squares line), are very similar, predicting our model with remarkable precision the experimental results obtained. Such a good fitting is achieved with a density of traps _T1 = 1.5e20 cm^-3 at the surface and uniformly distributed between contacts; the energy level of traps being 0.25 eV relative to the valence band. The existence of multiple trap levels (< 0.25 eV) may well be an acceptable alternative picture, according to our calculations [25].

Considering case 2, the experimental I_D2 curve (solid line) and the theoretical curve (triangles line) are also very approximated as a result of a new fitting process using our theoretical model, which corresponds to a density of traps next to _T2 = 3.8e20 cm^-3, for the rest of the conditions being equal to the previous case analyzed. Discussions about the physical mechanism of HEMT response to the stimulus applied are presented in Section V.

Fig. 4. (a) Experimental and theoretical ID(t) transient response obtained in an AlGaN/GaN HEMT device using the gate-lag turn-on technique for two test conditions (ID1 and ID2) at VD = 10 V. In dashed line is shown the transient step voltages applied to the gate terminal (Vg1 and Vg2). (b) Expanded plot of (a).

B. Drain-Lag Turn-On Pulsing Mode
Fig. 5 shows the transient drain–current using the drainlag technique, as described in Fig. 2(b). Again, two situations are presented in a similar fashion to the case of excitation in the gate.

1. In the first case, the device is analyzed starting from an initial situation under relaxed conditions—no electrical stress applied for at least several minutes. In this situation, a step drain voltage V_D1 (dashed line) is applied to the drain terminal (with a rising edge time next to 30 ns), and the drain–current registered (drain lag) is presented in the plot as I_D1 (solid line). As clearly observed, the device initially shows an instantaneous and maximum peak of current, trying to follow with the same edge the evolution of the applied stimulus V_D1, as expected. However, the level of current instantaneously reached (in ~30 ns) has an overshoot next to ~15%, which is over the steady-state value obtained when the gate-lag technique was used. Starting from this point, a decrease—almost linear—of current is observed in curve I_D1 until a time next to ~8 µs (see the t_A label in the expanded plot), where the drain–current seems to be stabilized. After approximately one decade in time, the drain–current starts a less pronounced fall (see the t_B label in the expanded plot) until a steady-state condition for t ≥ 10 ms is reached again, with the current level very similar to that obtained when the gate-lag technique was employed. This particular response will be discussed in the next section.
   
2. In the second case, a similar procedure was followed using electrical stress conditions. Several step voltages are applied at the drain terminal, a subsequent step voltage V_D2 (dashed lined) is registered, and the current response is analyzed. However, unlike the gate-lag technique previously discussed, lower differences were obtained with respect to case 1 using this second technique. Hence, in this case, we represent in Fig. 5 only the maximum variations observed in our tests: curve I_D2 (solid line). Although due to the scale used it is not directly appreciated, the average variation in current level in the last decade, in both curves, was lower than 3 mA/mm.

Fig. 5. (a) Experimental and theoretical ID(t) transient response obtained in an AlGaN/GaN HEMT device using the drain-lag turn-on technique for two test conditions (ID1 and ID2) at VG = 0 V. In dashed line is shown the transient step voltages applied to the drain terminal (VD1 and VD2). (b) Expanded plot of (a).

In Fig. 5, the numerical results using the drain-lag technique are also presented for the two situations considered, analogous to the gate-lag technique previously described and also employing the same physical model. The densities of donor traps assumed in our simulations were again _T1 = 1.5e20 cm^-3 (squares line) and _T2 = 3.8e20 cm^-3 (triangles line). As can be observed in the figure, the current deviations between the two simulated curves are minimal, and similar time constants are obtained in both cases, with a delay of approximately two decades—from ~80 µs (t_B) to 10 ms—see expanded plot in Fig. 5(b).

V. DISCUSSION

In this section, the results shown in Section IV and presented in Figs. 4 and 5 are compared and discussed, describing our physical explanation to the HEMT behavior.

A. Gate-Lag Results
The initial current collapse situation observed in Fig. 4 was directly caused by a significant amount of neutral donor states at the surface, filled with electrons. The surface states in the form of DTI (_DT1) contribute by adding a positive charge to the net total, expressed as _net = -_pol + _DTI + _holes [25]. According to our charge model seen in Fig. 3, _DT1 would have the lowest positive value. These effects of reduction of negative charges at the surface on the drain–current, under static conditions, were reported in [27], producing an opposite response to the classical behavior of a GaN-based MESFET device [28]. With minimum sDTI, the initial response of the device in drain–current has the minimum level, i.e., a “collapsed” situation in current is observed in the device under our experimental test conditions. This is clearly shown in Fig. 6, where the DTI concentration, just after application of the step gate voltage, is represented [t = 0+ s (dashed line)]. Another important source of positive charge to consider would be free holes that accumulated at the surface, as plotted in Fig. 7. The hole concentration at the surface _holes is given just after the step voltage was applied t = 0+ s (dashed line). As reported in [25], its magnitude is very dependent on the energy level of traps. However, the contribution of holes to the net charge _net, when donor states are included in the model, is minimal in all cases and does not have an important influence as positive charge.

Later on, the finite time required by surface states to respond to the external gate voltage step (V_gl or V_g2) would be the cause of the lapsed time observed in Fig. 4. As reported in [25], time constants are very dependent on the energy level of traps.

The increase of DTI with time at the surface—by emission of electrons or capture of holes—would be the direct origin of the transient evolution of current observed in curves I_D1 and I_D2. In our case, the capturing of holes seems to be the most reasonable because, as reported in [25], donor traps at the surface would be close to free holes that accumulated at the HEMT surface—due to piezo effects—making it very likely the process of capturing holes by donor traps. As deduced from [25] and according to [29] for energy of traps below Fermi level at equilibrium, traps would be essentially full or substantially filled with holes as it is this case, the lower is the energy level of traps, the greater is the probability that traps act as hole traps instead of recombination centers. Fig. 6 shows the DTI concentration for t ≥ 10 ms when a steady-state condition has been achieved (dash-dotted line). The temporary variation suffered by DTI and how this variation is greater in regions next to the gate contact and lower in regions next to the source and drain contacts are clear and evident. Therefore, this mechanism is mainly responsible for the effect of current collapse in AlGaN/GaN HEMTs, i.e., variations of charge at the surface next to the gate contact, independent of the existence of traps in another material location and/or interface. The bias conditions would determine the relative position of quasi-Fermi level for trapped holes with respect to the energy level of traps and consequently their degree of ionization. In Fig. 7, the variation experienced by the hole concentration for t ≥ 10 ms (dash-dotted line), following a similar behavior to the variation of DTI described, is also shown.

Fig. 6. DTI concentration in horizontal cut made at the HEMT surface for t = 0+s (gate lag, dashed line; and drain lag, solid line) and for t > 10 ms (dash-dotted line) in both cases.

Fig. 7. Hole concentration in horizontal cut made at the HEMT surface for t = 0+s (gate lag, dashed line; and drain lag, solid line) and for t > 10 ms (dash-dotted line) in both cases.

The very low influence of acceptor traps at the surface of our device—acting as electron traps—has also been reported in [25]. Another important aspect to add in these conclusions is a fact already reported in the literature [20]: it seems that no other source of traps—GaN, AlGaN material, or AlGaN/GaN interface—was detected in our measurements employing the described technique. The last aspect to be discussed at this point would be in connection to the number of active traps at the surface. As revealed by our results considering the two excitation conditions seen in Section IV-A, the number of active traps at the surface would depend on the electrical history suffered by the device.

B. Drain-Lag Results
From the drain-lag turn-on measurements shown in Fig. 5, analyzing the interval between t > 0 and t < t_A [Fig. 5(b)], the transient decrease in current is not due, according to our simulations, to the presence of surface states, because a slower behavior and similar to the gate-lag case could be expected, and trapping centers in other locations, such as bulk GaN, AlGaN, and/or interface, are likely. At the present state of our investigations, we cannot give the exact origin of these observed effects. But in this case, a very fast response with time constants next to ~10 µs—see t_A in the expanded plot—is identified. On the other hand, analyzing the interval for t ≥ t_A, we identify the presence of fast donor surface traps in the current response with the associated time constants next to 10 ms— analogous to gate-lag measurements. Unlike the explanation given in case A, where current collapse was due to neutral donor traps filled with electrons, in this case, the behavior of traps at the surface would be the opposite. Considering 0 < t < t_B, initially, most of the traps are emptied and positively charged—electrons have been emitted or holes captured. This last situation seems to be more reasonable, according to our previous discussion. In Fig. 6, the DTI concentration, just after the drain step voltage was applied [t = 0+ s (solid line)], is shown. The concentration of DTI is greater than in the previous case. The contribution of surface states _DTI adding positive charge to the net charge at the surface _net would be maximum for t < t_B in Fig. 5(b). Later on, during the transient evolution, for t ≥ t_B, the finite time required by surface traps to respond to the external voltage step (V_d1 or V_d2) would be again the cause of this effect by a process of filling and subsequent neutralization—electrons captured or holes emitted. The decrease of DTI at the surface would be the direct cause of the transient evolution of current observed in the curves shown in Fig. 5. In this case, a decrease of positive charge sDTI is associated with the filling and neutralizing of positive donor traps by capture of electrons or emission of holes. In our case again, the emission of holes seems to be the most reasonable according the explanation given in Section V-A. In Fig. 6, the DTI concentration for t ≥ 10 ms (dash-dotted line), when a steady-state condition has been achieved, is also presented. The DTI concentration agrees with the result obtained in case A. In this second case, a decrease of DTI concentration is observed in the regions next to the gate contact. In Fig. 7, the hole concentration for t ≥ 10 ms (dash-dotted line) is shown for the same conditions, in agreement with the results obtained in case A.

As a conclusion to this section, our model accounts for all the features measured in the current response both in gate and drain pulse excitation, except for the initial and fast decrease of drain–current in the second case that would be related with other mechanisms than surface states.
In both analyzed responses, the mutual interaction between free holes that accumulated at the HEMT surface and donor traps turns out to be decisive in this particular behavior of AlGaN/GaN HEMT, unlike classical GaN MESFET behavior [25]. Holes and donor states play a decisive and very important electrostatic role on the physical mechanism of response of 2DEG in AlGaN/GaN HEMT and consequently in the variation of drain–current response in the device.

Finally, it is worth emphasizing that both gate and drain pulses lead to the same final steady-state condition in current response in a HEMT device, i.e., such mechanism is due to the contribution—increment or decrement—of positive charge, caused by the DTI _DTI, to the net charge _net in the regions next to the gate contact, leading to the same steady-state condition in a HEMT device, because the final DTI concentration at the surface _DTI—for t ≥ 10 ms—is the same in both cases; and as a result, the same level in current response is achieved when steady-state conditions are reached.

VI. CONCLUSION

In this paper, we have presented the trapping effects in the transient response of a HEMT device. The mechanism of drain current changes in the device has been analyzed by comparing experimental and calculated currents. We have demonstrated the existence of current collapse and related dispersion effects, employing an analysis based on the well-known techniques of gate-lag and drain-lag turn-on pulsing methods, and discussing their effects. These techniques have verified the model of donor surface states—acting as hole traps—being mainly responsible for the observed negative effects in this technology. Besides, the existence of additional sources of dispersion not associated with surface states has been deduced. A HEMT physical model has been studied to explain the experimental results, and the structure has been analyzed by means of a 2-D device simulator that includes time evolution of trap ionization. Donor states with an energy level of 0.25 eV—relative to the valence band—and densities in the range of 1.5e20 cm^-3 to 8e20 cm^-3, located at the ungated surface, and interacting with free holes that accumulated at the surface due to piezo effects, between contacts, would be the source of the current collapse effects; this is consistent with the time evolution of DTI concentration at the surface. Theoretical DTI evolution has been shown and described using the two discussed techniques, and time constants next to 10 ms have been obtained in both experimental and theoretical results. Experimental time constants next to 10 µs that have also been measured in the drain–current pulses may be associated with sources of trapping in locations other than the surface.

ACKNOWLEDGMENT

The authors would like to thank F. Garat of ESAESTEC for valuable discussions and suggestions, the Microsystems Laboratory, Universidad Politécnica de Madrid, for the use of clean room facilities, and Prof. E. Iborra and Prof. J. Sangrador for the assistance.

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