1. Introduction
Thin film transistors (TFTs) are widely used in various applications, such as active matrix organic light-emitting diodes, active matrix liquid crystal, and flat panel displays. Oxide-based TFTs have the advantages of reasonable mobility, high transparency, low processing temperature, amorphous phase, and high uniformity for flexible substrates or large-area production. Both electrical and optical properties of oxide-based TFTs can be bandgap engineered by the doping method, and their cutoff wavelength can be easily tuned by alloying them with other oxide semiconductors. Oxide semiconductor detectors are used for ultraviolet (UV) detection due to their wide bandgap of >3 eV, high breakdown field, and thermal stability. Thus, oxide semiconductors are promising materials for phototransistors. Phototransistors can integrate light detection and signal magnification properties in one device due to their high sensitivity, low noise, low cost, and easy fabrication [
1,
2]. Accordingly, phototransistors have various potential applications, such as optoisolators, optical switches, and retrosensor circuits with voltage-switching capability [
3,
4,
5]. Among them, UV detection is of utmost importance because of its specific applications, such as flame detection, short-range communication, and UV astronomy [
6]. However, commercial silicon-based UV detectors are limited by high leakage current due to their narrow bandgap and requirement of expensive wood filters that are unsuitable for UV detecting [
7]. Visible- (λ ≤ 400 nm) and solar- (λ ≤ 280 nm) blind phototransistors can be divided on the basis of the cutoff wavelength, which has three regional classifications, namely, UV-A (400–320 nm), UV-B (320–280 nm), and UV-C (280–10 nm) [
8]. The visible- or solar-blind phototransistor requires a wide bandgap. Metal oxide semiconductors are promising materials for UV light detection sensors.
Metal oxide semiconductors with wide bandgap (>2 eV) demonstrate intrinsic visible blindness, high chemical bonding strength, and simple fabrication properties, which are suitable for UV-light detection [
9]. Among them, In
2O
3-based materials are used in UV phototransistors. In
2O
3 is a high mobility and wide bandgap n-type material typically used as carrier supplier in metal oxide-based semiconductors. Oxygen vacancies are major defects of In
2O
3 that produce two free electrons as donors [
10]. However, the excessively large number defects can lead to high visible light sensitivity and high off-stead current in In
2O
3 TFTs and the doping behavior can be a function of carrier suppressors in the active layer. Park et al. reported the improved performance of lanthanum indium zinc oxide (La-IZO) TFTs using radio frequency cosputtering by controlling the sputtering power applied to the La target. Compared with electronegativity values of indium (1.78), zinc (1.65), and oxygen (3.44), the lower electronegativity value of lanthanum at 1.1 results in a strong ionic bond between La and O due to the large difference in their electronegativity values [
11]. Park et al. [
12] investigated the incorporation of gadolinium into IZO TFTs and demonstrated that the formation of stable Gd–O ionic bonds due to the large difference in electronegativity values between Gd and O can improve the device performance of Gd-IZO TFTs and Gd can be used as an element of carrier suppressor. Choi et al. [
13] assessed the carrier-suppressing effect of Sc in InZnO systems applied to TFTs and used Sc as the carrier suppressor to control oxygen vacancies effectively and supply free electrons due to its low standard electrode potential (SEP) (−2.36) and lower electronegativity (1.3) than oxygen (3.4).
Compared with indium and oxygen, the higher electronegativity values of the Mg element (1.2) can reduce the defect by forming oxygen vacancies [
14]. Furthermore, MgO is suitable for solar-blind photodetection because of its transparent semiconductor with a wide bandgap of ~7.8 eV and ability to remain physically and chemically stable at high temperatures [
15]. Electrical properties of In
2O
3 TFTs can be improved and bandgaps engineered via MgO doping and tuning the composition of MgO and In
2O
3 in the active layer. In this work, the cosputtered method was applied to the fabricated MgInO phototransistor to modulate the power of the In
2O
3 target, change the vacancy concentration, and engineer the cutoff wavelength. Electrical and photo properties of devices are discussed in the following section.
2. Experiment and Device Fabrication
The fabricated device comprises a bottom gate, dielectric layer, active layer, and Source/Drian (S/D) electrode. Three samples with various In2O3 target power values, namely, samples A, B, and C with 40, 50, and 60 W, respectively, were used in this study. First, heavily doped p-type silicon was cleaned with acetone, methanol, and water using an ultrasonic cleaner for 10 min in order to clean grease and particles from the glass. The p++ silicon wafers served as a bottom gate and used for growing a 300 nm thickness of SiO2 dielectric layer. After that, the active layer deposition 30 nm thick MgInO thin film used MgO and In2O3 targets by the cosputtering method with an interdigitated shadow mask. MgO target power was fixed at 100 W; the In2O3 target power was 40, 50, and 60 W for samples A, B, and C, respectively. Before opening the shutters, the targets were presputtered for 5 min to remove the impurities in the target surface. The sputtering time was carefully controlled to ensure the thin film thicknesses were equal, and that precision of sputtering power was maintained ±1 W. The working pressure was 0.8 Pa at an argon flow of 3 sccm at room temperature. Samples were then annealed at 300 °C for 1 h in argon ambient. Finally, thermal evaporation with an interdigitated shadow mask was performed using a 100 nm source and drain electrode. The channel width and length were 1000 and 100 μm, respectively. The photo and electric properties were measured in the dark region using Agilent B1500A and 150 W Xenon lamps (Agilent Technologies, Santa Clara, CA, USA), respectively. Glancing incidence angle X-ray diffractometry (GIAXRD) (XRD, D8 Discover, Bruker, Billerica, MA, USA) and X-ray photoelectron spectroscopy (XPS) (PHI 5000 VersaProbe, ULVAC, Chigasaki-shi, Japan) were applied to assess the crystal structure and determine the concentration of oxygen vacancy, respectively.
3. Results
Figure 1a,b show the GIAXRD spectra of samples A, B, and C, and the magnified picture of the (311) diffraction line in the MgIn
2O
4 phase. Samples A and B demonstrate significant amorphous phases and inconspicuous peaks located at 2θ = 32.5°, which correspond to the spinel MgIn
2O
4 (311) phase [
16]. Clear diffraction peaks in Sample C indicate its polycrystalline structure and its signal may be attributed to the In
2O
3 cubic structure (JCPDS Card No. 76-0152), which corresponds to <221>, <222>, <400>, <441>, <440>, <611>, and <622>; the In
2O
3 cubic structure (JCPDS Card No. 06-0416), which corresponds to <521>; and the MgIn
2O
4 spinel structure (JCPDS Card No 40-1402) which corresponds to <541>. Transfer characteristic curves of MgInO TFTs were measured under V
DS = 10 V and a range of V
GS = −30 to 20 V, as shown in
Figure 2.
Table 1 presents the electric performance of three samples, including threshold voltage, field effect mobility, subthreshold swing, and on/off ratio. Carrier mobility can be calculated as follows [
17]:
where W and
L are the width and length of the channel, respectively;
Ci is the capacitance of the dielectric layer per unit area;
μsat is the field effect mobility; and
Vth is the threshold voltage. Mobility increased from 0.134 to 2.01 cm
2/V-s when In
2O
3 content increased. The threshold voltage shifted in the negative direction, likely due to the increase in number of oxygen vacancies as the donor in the MgInO material system. In addition, the threshold voltage is defined from the linear extrapolation of
IDS1/2 versus
VGS. The intersection of the linear extrapolation and the
x-axis is the V
TH value. S.S is the change in gate voltage needed to increase the drain current by one order of magnitude with respect to the switching speed of the device, and can be expressed as follows:
S.S decreased from 2.59 to 1.81 V/decade and then increased to 2.83 V/decade, likely due to grain boundaries and other defects that act as carriers for scattering and trapping sites. Thus, gate controllability deteriorated and the gate insulator would likely be damaged because of the large sputter power of sample C. Moreover, the on/off ratio of samples was at approximately 105. However, when raising the In2O3 power from 70 W, however, greater In2O3 leads to high conductivity performance with no transfer characteristic. It is also worth noting that each measurement was repeated three times; the deviation value was less than 1% and there were differences between the three groups on the same variable.
Figure 3 shows the output characteristic curves under different gate voltages from 0 to 10 V. The increasing drain current and off-current of the device as gate voltages increase demonstrate the operational modes of n-channel TFTs. The conductivity of the channel layer increased due to the increase in sputtering power of indium oxide. The high sputtering power of indium oxide increases the carrier concentration in the thin film.
Figure 4 showed XPS and fitting spectra of O 1s deconvolution with Gaussian function confirms the concentration of oxygen vacancy in the thin film, the detail values were summarized in
Table 2. The three peaks, M–O, Vo, and M–OH, can be attributed to O
2− ions in metal oxide lattices, oxygen vacancies, and M–OH compounds on the surface, respectively [
18]. Magnesium content is from 17.5 to 11.56 at% and indium content is from 34.75 to 38.82 at%. Oxygen vacancies increased from 27.59 to 40.91% with the increased target power of In
2O
3. The elemental composition via XPS measurement is presented in
Table 3. The priority of bonding between multimetal oxide can be explained by electronegativity, which describes the tendency for attracting electrons. Electronegativity differences in Mg–O and In–O are 2.13 and 1.66, respectively. Thus, the stronger attraction of Mg to oxygen than In results in the reduction of oxygen vacancies. MgInO thin films demonstrate good application potential in UV light detection due to their high transmittance and wide bandgap. Tauc plots of the three samples are illustrated in
Figure 5 to determine the optical energy bandgap. Optical bandgap of 4.4, 4.1, and 3.65 eV for samples A, B, and C, respectively, indicate that band gaps can be engineered with different target power values of In
2O
3.
Figure 6 shows the three samples that are measured under light illumination with wavelengths from 500 to 240 nm in an interval of 40 nm to investigate their photo properties. The transfer curve was measured using a gate voltage ranging from −40 to 40 V and V
DS = 10 V. The photocurrent gradually increased when moving to short wavelength, the photo-induced current dominated the I
DS. Photo-excited holes trapped by shallow donor states (oxygen vacancies) originating from photo-generated electrons increased I
DS and subsequently reduced the barrier height from source to drain. Hence, the incident photon energy increased with increasing I
DS as V
TH shifted toward the negative direction.
Photoresponsivity of samples A, B, and C is depicted in
Figure 7. Photoresponsivity can be calculated as follows:
where
Ilight is the photocurrent,
Idark is the dark current, and
Popt is the power of incident light. Notably, responsivities are calculated under V
DS = 10 V and V
GS = −10 V, V
GS = −20 V, and V
GS = −38 V for samples A, B, and C, respectively. Responsivity and rejection ratios of samples A, B, and C are 0.0086, 0.17, and 2.6 A/W, and 1.2 × 10
4, 4.3 × 10
5, and 4.8 × 10
5, respectively. In addition, rejection ratios are defined as the responsivity at 280 nm divided by the responsivity at 460 nm. A high rejection ratio indicates that the device can distinguish between visible light and UV. The existence of oxygen vacancies deteriorates the device performance because responsivity continued to increase, although the light energy was lower than the bandgap energy, likely due to trap levels and band-tail states from the structural defect, especially in amorphous oxide [
19]. A comparison of optical characteristics demonstrated that sample C exhibited the best performance due to its high mobility, which indicated the highest induced photocurrent. XPS spectra confirmed that the composition of thin films can improve the photo and electric performance of the device by controlling oxygen vacancy defects. Meanwhile, UV phototransistors with precise control over composition can enhance the device performance. Hence, the device performance with moderate oxygen or hydrogen flow can lead to the control of oxygen vacancy concentration [
20,
21,
22].