Introduction

In the past several years, an intensive effort in the development of III-V nitride based devices has been expended [Reference Mohammad and Morkoc1]. The high electron saturation velocity, large breakdown field, high thermal conductivity, and superb mechanical stability of GaN are among its properties that make it an excellent candidate for high-temperature and high-power applications at high frequencies [Reference Morkoc, Strite, Gao, Lin, Sverdlov and Burns2]. The accomplishments made over the past couple years clearly demonstrate the rapid pace in which III-V nitride based FETs are being developed. However, the investigation of noise properties, particularly low-frequency noise has not yet gotten the necessary attention.

Flicker noise is an important figure-of-merit for semiconductor devices. It represents the lower limit of the signal that can be processed by the device. Previous studies of the phenomenon had shown that flicker noise in electron devices often arises from material defects which manifest themselves as the trapping and detrapping of carriers by localized states and grain boundary motion [Reference Surya, Ng, Brown and Maki3-Reference Ho and Surya5]. The objective of our work is to identify the underlying physical noise processes to pave the way for improving the noise properties of the device. To accomplish this, we studied the voltage noise power spectral density, S_V (f), over a wide range of temperatures and biases to investigate the role of localized states in the fluctuation process.

Experiment

Gallium nitride based MODFETs were fabricated with reactive MBE on (0001) sapphire substrates. An 800Å AlN buffer layer was first grown at 800°C followed by the deposition of a 1.2μm thick undoped GaN layer. The two-dimensional electron gas was formed at the heterointerface between the i-GaN layer and a 30Å i-AlGaN spacer layer which serves to separate the 2-dimensional electron gas from the ionized dopants to increase the mobility of the carriers. The electron donor layer consists of a 120Å-thick Si doped AlGaN layer of concentration 5×10¹⁸ cm⁻³. Ti/Al/Ti/Au (200Å/1700Å/450Å/550Å) multilayers were deposited to form ohmic contacts to the drain and source regions. The gate length and gate width are 2μm and 40μm, respectively.

The low-frequency noise of the device was characterized from room temperature down to 130 K, with the gate biased at a fixed voltage and the conduction channel was current biased with a passive current source. The detailed experimental set-up was described in previous publication [Reference Cheng and Surya6].

Results and Discussions

The experimental values for S_V (f) at 500Hz at V_G = 0.8V and V_D = 0.2V were found to be relatively insensitive to temperature change and were about 4×10⁻¹² V²Hz⁻¹ over the entire temperature range as shown in Fig. 1. However, S_V (f) exhibited strong dependencies on both the gate and drain voltages.

Fig. 1: The voltage noise power spectral density, S_V (f=500Hz), over the conduction channel as a function of device temperature.

The experimental results showed that S_V (f) ∝ V _D ²/(V_G − V_T )^β where β varied between 2.1 at room temperature to about 0.9 at T = 130K. Typical results of Log S_V (f) versus Log (V_G − V_T ) at T = 290K and 160K are shown in Fig. 2, which clearly indicates changes in β. Typical plot of Log S_V (f) versus Log V_D at 263K is shown in Fig. 3 for f=500Hz. The slope of the best fit is 2.05, which demonstrates a quadratic relationship with V_D .

Fig. 2: Log[S_V (f=500Hz)] is plotted versus Log(V_G − V_T ) at T = 290 K and T = 160K.

Fig. 3: Log[S_V (f=500Hz)] is plotted versus Log(V_D ) at V_G = 0.6 V and T = 263K.

Flicker noise in semiconductor devices has been a subject of interest for many years [Reference Cheng and Surya6,Reference Dutta and Horn7]. Of the various models presented in the past, the thermal activation model proposed by Dutta and Horn [Reference Dutta and Horn7] stands out in its success in explaining the temperature dependence of the noise. Application of the model in field-effect transistors was investigated by Surya and Hsiang [Reference Cheng and Surya6] who suggested that 1/f noise arises from thermal activation of carriers to traps at different energy levels. In this case the voltage noise power spectral density is

where C is a proportionality constant and E is the activation energy. It is shown that the Lorentzian peaks sharply at E_p = −k_BTln(2πτ₀). Consequently 1/f noise is highly sensitive to trap distribution at E_p . It can be shown that γ = 1 if N_T (E)| _{E ≈ Ep} is independent of E; γ > 1 if N_T (E)| _{E ≈ Ep} increases with E; and γ < 1 if N_T (E)| _{E ≈ Ep} decreases with E. Since E_p varies linearly with temperature, traps at energy level will be responsible for the observed noise as the device temperature is varied. Then γ will vary according to the relationship as discussed above if

changes with energy.

The observation of a systematic variation of γ as a function of T in our experimental data is indicative of a thermally activated process that underlies the noise. The experimental values of γ versus T for V_G = 0.8 V and V_D = 0.2 V are indicated in Fig. 4 in which γ decreased from 1.03 to about 0.85 when T varied from room temperature to 250K. Further decrease in the device temperature led to a gradual increase of γ to 0.98 at 220K. Below 220K, γ slowly decreased to about 0.9 as the device temperature was lowered to 130K.

Fig. 4: The temperature dependence of the frequency exponent, γ.

Both traps at the GaAlN/GaN interface or along the line defects within the two-dimensional electron gas are viable candidates for the observed 1/f noise. Given the high concentration of line defects in GaN, the latter mechanism is highly probable for our devices. To further investigate the physical origin of the noise we study the variations of γ as a function of V_G. It is observed that γ exhibited a systematic dependence in the applied gate bias. Typical results are shown in Fig. 5, for V_D = 0.2V at T = 250K where γ decreased initially from 0.9 to about 0.85 as V_G varied from 0.4V to 0.6V. Subsequent increase in V_G led to increase in γ to 0.96 at V_G = 1V. This can be explained by the change in band bending in the AlGaN layer with the application of a voltage bias resulting in a change in the trap energy levels with respect to the Fermi level in the device. Depending on the actual distribution of N_T (E) it may lead to a change in γ. Base on these results it appears that the noise arises from trapping and detrapping at GaN/AlGaN interface.

Fig. 5: Gate bias dependence of the frequency exponent, γ, at T = 260K and V_D = 0.2V.

McWhorter postulated that the capture of an electron by a trap causes the local modulation of the Fermi Level leading to fluctuations in the local carrier concentration. However, it was shown that the process may also lead to fluctuations in the carrier mobility due to Coulombic scattering. Studies on low-frequency noise in field-effect transistors showed that S_V (f) ∝ (V_D /( V_G − V_T ))² for noise dominated by number fluctuations. On the other hand, for 1/f^γ noise dominated by surface mobility fluctuations, the dependence of S_V (f) on V_G arises from the screening effect by the two-dimensional electron gas which generally demonstrate a different V_G dependence from number fluctuations and would exhibit stronger dependencies on temperature due to the variations of the screening parameter with T. The experimental results in Fig. 2 clearly deviated from the quadratic relationship as stipulated by numbers fluctuation model. However, a more definitive study that involves the characterization of random telegraph noise, which allows exact measurements of the fluctuations in the channel resistance resulting from single-electron events, is needed to conclusively prove the underlying fluctuating quantity of the noise. Such a phenomenon is typically seen in sub-micrometer size devices.

Conclusion

We have conducted systematic characterizations of 1/f ^γ noise in GaN MODFETs. Detailed analyses of the magnitudes and γ of the voltage noise power spectra showed that the noise originated from the thermal activation of carriers to localized states either at the AlGaN/GaN heterointerface or line defects within the two-dimensional electron gas. Our experimental data suggest that trapping and detrapping at the heterointerface dominated the observed flicker noise. In addition, it was found that S_V (f) ∝ V _D ²/(V_G − V_T )^β where β varied from about 2.1 at room temperature to about 0.9 at 130K. This suggests that the capture and emission of carriers by interface traps did not result in number fluctuations. A more detailed study of random telegraph noise is needed to confirm if surface mobility fluctuations due to Coulombic scattering played a major part in the observed noise.