I. INTRODUCTION

Gallium nitride (GaN)-based power transistors are the promising candidates for the future power electronics. Compared with the silicon (Si) devices, the GaN power devices have a larger bandgap, higher electron mobility, and higher critical electric field ^[1-6]. Due to these properties, the GaN power devices are suitable for various applications, such as the electric vehicles, the smart grids, the fast charging system, and the military field. Especially, in the field of the automatic driving systems, the high power drivability is a very important characteristic. Because of the AlGaN/GaN heterostructure, GaN HEMTs have the large electron density and channel conductivity ^[7]. Despite these merits, the conventional GaN devices have several limitations. First, to obtain the high BV, a long distance between the gate and the drain is required. Second, because the two-dimensional electron gas (2-DEG) is too close to the AlGaN/GaN interface, the device performance is affected by the surface roughness, such as the trapping effect ^[8-10]. Finally, the lateral GaN HEMTs based on the AlGaN/GaN heterostructure are typically normally-on devices. To obtain a normally-off operation, either a p-type GaN layer on the undoped AlGaN layer or a recessed gate structure is required ^[11-13]. To overcome these problems, the GaN vertical fin power transistor is proposed ^[14]. In this device, the BV is not affected by the chip area due to the vertically arranged source and drain. Also, this device operation is less sensitive to surface trapping because it is based on the junctionless FET, the normally-on operation can be implemented without the p-type GaN layer ^[15,16]. Furthermore, a multiple fin structure results in the high current performance.

In this study, the electric performances of the multiple fin-type vertical GaN power transistors were simulated, and the change of characteristics related to the number of fin (N$_{\mathrm{fin}}$) such as the BV and the R$_{\mathrm{on}}$ were investigated. We introduce the effect of the N$_{\mathrm{fin}}$ on the vertical GaN fin-type power transistor and the advantages of the multiple fin-type device.

II. DEVICE STRUCTURE AND SIMULATION

Fig. 1(a) and (b) show the schematic view of the 5-fins vertical GaN power transistor and a unit cell of this device, respectively. The details of all the parameters are summarized in Table 1. The epitaxial structure consists of a 10 ${\mu}$m-thick n-GaN substrate, a 200 nm-thick n$^{+}$-GaN layer, a 12 ${\mu}$m-thick n-GaN drift layer, a 700 nm-thick n-GaN channel, and a 300 nm-thick n$^{+}$-GAN source layer. The gate electrode metal is the molybdenum with a work function of 4.95 eV. The cutlines of A-A’ and B-B’ are located at the center of the channel and the center of the fin from the channel to the drift layer.

The operation principle of the vertical GaN fin power transistor is the same as that of the junctionless FET ^[17]. Fig. 2(a)-(d) show the cross-sectional view of the fin channel at different V$_{\mathrm{GS}}$’s. When the V$_{\mathrm{GS}}$ is applied between the GaN and the gate metal, there is no current flow. When the V$_{\mathrm{GS}}$ starts to become higher than V$_{\mathrm{th}}$, a neutral region begins to form in the center of the channel, and the bulk current begins to flow. When the V$_{\mathrm{GS}}$ reaches the flat-band voltage (V$_{\mathrm{FB}}$), the depletion region in the channel disappears completely. When the V$_{\mathrm{GS}}$ becomes higher than the V$_{\mathrm{FB}}$, electrons accumulate at the surface of the gate oxide, resulting in the accumulation layer current and bulk current. Fig. 2(e) shows the electron concentration distribution of the fin-channel along the A-A’ cutline at different gate biases in the range of 1-5 V, and V$_{\mathrm{DS}}$ = 0 V. Fig. 2(e) makes it easier to understand the channel formation process.

The simulations in this study were performed by applying the Shockley-Read-Hall recombination model, the Fermi-Dirac model, the low-field and high-field mobility models, and the impact ionization model ^[18,19]. In addition, the interface traps between the GaN layer and the Al$_{2}$O$_{3}$ layer was considered, as depicted in Fig. 3 ^[20].

Fig. 1. (a) Cross-sectional view of a 5-fins vertical GaN power transistor; (b) unit-cell.

Fig. 2. Schematics of (a) fully depleted fin channel; (b) partially depleted fin channel; (c) flat band mode; (d) accumulation mode; (e) Simulated electron concentration distribution along A-A’ cutline at different gate biases in the range of 1 to 5 V.

Fig. 3. GaN/Al$_{2}$O$_{3}$ interface trap distribution.

III. RESULTS AND DISCUSSION

Fig. 4(a)-(c) show the I$_{\mathrm{D}}$-V$_{\mathrm{GS}}$ transfer curve, the output current curve, and the breakdown characteristic curve of the 5-fins vertical GaN power transistor. The drain current density (I$_{\mathrm{D}}$) and the specific R$_{\mathrm{on}}$ are normalized to the total substrate area. The I$_{\mathrm{on}}$ is defined at V$_{\mathrm{GS}}$ = 6 V and V$_{\mathrm{DS}}$ = 5 V. The R$_{\mathrm{on}}$ is extracted at V$_{\mathrm{GS}}$ = 6 V and V$_{\mathrm{DS}}$ = 0.1 V. The 5-fins vertical GaN power transistor has I$_{\mathrm{on}}$ = 5.49 kA/cm$^{2}$, V$_{\mathrm{th}}$ = 3.41 V, R$_{\mathrm{on}}$ = 0.884 m${\Omega}$·cm$^{2}$, and BV = 1,999 V. Based on this result, the characteristics and advantages of the multiple fin-type vertical GaN power transistors are analyzed by comparing with those of the single-fin device.

Fig. 5(a) and (b) show I$_{\mathrm{D}}$-V$_{\mathrm{GS}}$ characteristics and transconductance according to N$_{\mathrm{fin}}$. As the N$_{\mathrm{fin}}$ increases from 1 to 10, the I$_{\mathrm{on}}$ increases from 4.87 to 5.58 kA/cm$^{2}$, and V$_{\mathrm{th}}$ decrease from 3.83 to 3.20 V. The I$_{\mathrm{on}}$ of the 10-fins device increases by 14.6% compared with that of the single-fin device, and as the N$_{\mathrm{fin}}$ increases, the increase rate of the I$_{\mathrm{on}}$ decreases significantly. Fig. 5(c) shows the BV and the R$_{\mathrm{on}}$ as a function of the N$_{\mathrm{fin}}$. As the N$_{\mathrm{fin}}$ increases from 1 to 10, the BV increases from 1,925 to 2,021 V and the R$_{\mathrm{on}}$ decreases from 1.007 to 0.867 m${\Omega}$·cm$^{2}$.

The change in the I$_{\mathrm{on}}$ and the R$_{\mathrm{on}}$ can be explained in terms of the resistance structure of the device ^[21]. As shown in Fig. 1(a), the resistance (R$_{\mathrm{on,N}}$) of the N fins vertical power transistor consists of the resistances from the fins (R$_{\mathrm{finN}}$) connected in parallel with each other, the drift layer resistance (R$_{\mathrm{drift}}$), the n$^{+}$-GaN layer resistance (R$_{\mathrm{n+}}$), and the substrate resistance (R$_{\mathrm{sub}}$).

(1)

The vertical GaN Schottky barrier diode (SBD) is used to extract the resistance occupied by the fin. As presented in Fig. 6(a), the SBD has an identical u-GaN drift layer, an n$^{+}$-GaN layer, an n-GaN substrate, and a backside contact with the vertical GaN fin power transistor.

(2)

Fig. 6(b) shows the I-V curve of the vertical GaN SBD; the simulated R$_{\mathrm{SBD}}$ is 0.852 m${\Omega}$·cm$^{2}$. When simulated in the same manner, the values of R$_{\mathrm{drift}}$, R$_{\mathrm{n+}}$, and R$_{\mathrm{sub}}$ are 0.827, 0.0005, and 0.024 m${\Omega}$·cm$^{2}$, respectively. The fin resistance of the N-fins device (R$_{\mathrm{Nfin}}$) can be extracted through the difference between the on-resistance of the N-fins device (R$_{\mathrm{on,N}}$) and the resistance of the SBD (R$_{\mathrm{SBD}}$).

(3)

Determining R$_{\mathrm{Nfin}}$ by applying (3) is possible only when each fin has the same resistance. Fig. 6(c) shows the I$_{\mathrm{D}}$ of each fin of the 5-fins device along the A-A’ cutline. The current flowing through each fin is equal regardless of the location of fins. Therefore, R$_{\mathrm{fin}}$ is the same in the N-fins device. Since the number of fins does not affect the channel formation of each fin, channels formed in one fin are all the same. Therefore, the R$_{\mathrm{Nfin}}$ is constant regardless of the number of fins. The determined R$_{\mathrm{1fin}}$, R$_{\mathrm{5fin}}$, and R$_{\mathrm{10fin}}$ are 0.155, 0.160, and 0.153 m${\Omega}$·cm$^{2}$, respectively. To verify the method of determining R$_{\mathrm{fin}}$ applying (3), the simulated R$_{\mathrm{on,N}}$ and calculated R$_{\mathrm{on,N}}$ using the determined R$_{\mathrm{Nfin}}$ and R$_{\mathrm{SBD}}$ are compared, as shown in Table 2.

The change in the I$_{\mathrm{on}}$ for different values of N$_{\mathrm{fin}}$ depends on the ratio of the resistance accounted for by the fin. The relationship between the I$_{\mathrm{on}}$ and the N$_{\mathrm{fin}}$ is non-linear because the resistance of the drift layer cannot be neglected. Since the R$_{\mathrm{drift}}$ constitutes a significant portion of R$_{\mathrm{on}}$, the result shown in Fig. 5(c) appears. Fig. 6(d) shows that the I$_{\mathrm{on}}$ and the 1/R$_{\mathrm{on}}$ at different values of N$_{\mathrm{fin}}$ have a similar tendency.

The V$_{\mathrm{th}}$ shift is related to the channel formation process. Table 3 shows the I$_{\mathrm{D}}$’s for different values of N$_{\mathrm{fin}}$ at different V$_{\mathrm{GS}}$ ranging from 3.2 to 3.8 V. For the same V$_{\mathrm{GS}}$, the channel is formed equally regardless of the value of N$_{\mathrm{fin}}$ and the position of the fin. The multiple fin-type device has N$_{\mathrm{fin}}$-channels. When the depletion layer disappears and the channel begins to form, most of the resistance is applied to the fin. Therefore, before the channels are accumulated, the I$_{\mathrm{D}}$ increases as the N$_{\mathrm{fin}}$ increases, thus resulting in the V$_{\mathrm{th}}$ shift.

Even if the N$_{\mathrm{fin}}$ changes, the difference in the BV is negligible. The BV of a 10-fins device is 4.99% higher than that of the single-fin device. Fig. 7 shows the electric field along the B-B’ cutline at V$_{\mathrm{GS}}$ = 0 V and V$_{\mathrm{DS}}$ = 1,800 V. The electric field is dispersed to fins, so that the peak electric field is slightly lowered. As the electric field applied vertically is considerably affected by the vertical parameter, T$_{\mathrm{d}}$, no significant difference is observed even if N$_{\mathrm{fin}}$ is varied.

Fig. 4. (a) I$_{\mathrm{D}}$-V$_{\mathrm{GS}}$ curve of 5-fins vertical GaN power transistor; (b) I$_{\mathrm{D}}$-V$_{\mathrm{DS}}$ curve; (c) Breakdown voltage curve at VGS = 0 V.

Fig. 5. (a) I$_{\mathrm{D}}$-V$_{\mathrm{GS}}$ curve with different number of fin; (b) Transconductance; (c) Breakdown voltage (BV) and R$_{\mathrm{on}}$ as a function of the number of fin.

Fig. 6. (a) Cross-sectional view of the vertical GaN Schottky barrier diode (SBD); (b) I-V curve of SBD; (c) Drain current of each fin of 5-fins device; (d) I$_{\mathrm{on}}$ and 1/R$_{\mathrm{on}}$ as a function of N$_{\mathrm{fin}}$.

Fig. 7. Electric field along B-B’ cutline at V$_{\mathrm{GS}}$ = 0 V and V$_{\mathrm{DS}}$ = 1,800 V.

IV. CONCLUSIONS

In this study, the electrical performances of multiple fin-type vertical GaN power transistors were analyzed by conducting ATLAS TCAD simulations. In the power electronics, the large-scale power devices are required to achieve high current. Thus, the effect of increasing N$_{\mathrm{fin}}$ in the device with L$_{\mathrm{sub}}$ = 5 ${\mu}$m was investigated. As N$_{\mathrm{fin}}$ increased from 1 to 10, I\-$_{\mathrm{on}}$ increased by 14.6%, R$_{\mathrm{on}}$ decreased by 13.9%, and BV increased slightly. The multiple fin-type vertical GaN transistors showed excellent performance. The 5-fins device exhibited I$_{\mathrm{on}}$ = 5.49 kA/cm$^{2}$, V$_{\mathrm{th}}$ = 3.41 V, R$_{\mathrm{on}}$ = 0.884 m${\Omega}$·cm$^{2}$, and the BV = 1,999 V. The performance improvement decreased with an increase in N$_{\mathrm{fin}}$, and it was saturated when N$_{\mathrm{fin}}$ exceeded 5. The results of this study provide insight into the electrical characteristic of multiple fin-type vertical GaN transistors.