Abstract
Cd x Zn1−xO (0 ≤ x ≤ 0.20) thin films are deposited on soda lime glass substrates using spray pyrolysis technique. To check the thermal stability, Cd x Zn1−xO thin films are subjected to annealing. Both the as-deposited and annealed Cd x Zn1−xO thin films are characterized using X-ray diffraction (XRD), scanning electron microscope (SEM) and energy-dispersive X-ray analysis (EDAX) to check the structural, surface morphological and compositional properties, respectively. XRD analysis reveals that the both as-deposited and annealed Cd x Zn1−xO thin films are (002) oriented with wurtzite structure. SEM studies confirm that as-deposited, as well as annealed Cd x Zn1−xO thin films are free from pinholes and cracks. Compositional analysis shows the deficiency in Cd content after annealing. Optical properties evaluated from UV–Vis spectroscopy shows red shift in the band gap for Cd x Zn1−xO thin films. Electrical property measured using two probe method shows a decrease in the resistance after Cd incorporation. The results indicate that cadmium can be successfully incorporated in zinc oxide thin films to achieve structural changes in the properties of films.
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Introduction
Exploration of wide band gap compound semiconductor material produced lot of benefits to human life. Materials like Al x Ga1−xN, BN and ZnO attracted the interest for device applications like UV-LEDs (Kinoshita et al. 2000), lasers (Watanabe et al. 2004) and thin-film transistors (Xu et al. 2016). Among different wide band gap materials, earth-abundant ZnO is a very important material, which finds application in solar cells (Bi et al. 2013). Large exciton binding energy of 60 meV, which can be increased up to 100 meV in superlattices, makes it an important candidate for lasers and LEDs (Tsukazaki et al. 2005). ZnO reflects the thermal infrared heat and can be exploited to prepare EMI shielding coatings, and heat/microwave reflecting coatings for windows (Miao et al. 2014). To develop ZnO-based opto-electronic devices, it is an important requirement to alter the electrical and optical properties. ZnO is a well known n-type semiconductor material, this n-type conductivity further increased by dopants like In (Pati et al. 2015), Ga (Chin et al. 2016), Al (Kumar et al. 2014), etc. It is also possible to produce p-type ZnO by doping Bi (Sadananda et al. 2013), As (Ryu et al. 2000), P (Kim et al. 2003), etc. Optical band gap of ZnO can be widened by alloying with Mg, which can reach up to 4.5 eV (Takagi et al. 2003). In addition, band gap can be engineered to lower values using Cd (Ma et al. 2011). The ZnO (hexagonal) and CdO (cubic) have very different crystal structure, and also, low thermodynamic solubility (~ 2 mol.%) of CdO in CdO–ZnO system make it very difficult to grow single-phase hexagonal Cd x Zn1−xO thin films with high Cd concentration (Ishihara et al. 2006). Different methods can be employed to grow mixed Cd x Zn1−xO thin films, such as molecular beam epitaxy (Wang et al. 2006), sputtering (Ma et al. 2011), pulsed laser deposition (Makino et al. 2013) and spray pyrolysis (Vijayalakshmi et al. 2008). Compared to different methods, the spray pyrolysis method is simplest industrially applicable method to produce metal oxide thin films. Using spray pyrolysis technique, very large area thin film can be grown with very high growth rate. Until now, very limited number of work is done on preparation of [Cd x Zn1−xO (0 ≤ x ≤ 0.20)] thin film using spray pyrolysis technique. Thus, the present work focuses on the deposition of Cd x Zn1−xO thin films using spray pyrolysis technique and annealing effect on the properties of Cd x Zn1−xO thin films. Further, both as-deposited and annealed Cd x Zn1−xO thin films are characterized to check phase purity, surface morphology, optical and electrical properties.
Experimental details
Cd x Zn1−xO thin films are deposited on top of the well-cleaned soda lime glass using spray pyrolysis technique. The precursor materials zinc diacetate dihydrate (Zn(CH3COO)2·2H2O) and cadmium chloride (CdCl2·21/2H2O) are dissolved in distilled water at different molar ratio to get Cd x Zn1−xO (0 ≤ x ≤ 0.20) thin films. The precursor solution atomized using spray nozzle was sprayed at a rate of 2 ml/min on preheated glass substrate held at optimized temperature of ~ 400 °C. The distance between the spray nozzle and glass substrate is fixed as 30 cm and air is used as carrier gas at the pressure of 2 bar. The atomized droplets reach the hot glass substrate and oxidizes on glass substrate to form highly adherent Cd x Zn1−xO thin films.
The thin film thickness is measured using gravimetric method and is maintained ~ 600 nm. The phase and crystallinity of the Cd x Zn1−xO thin films are analysed using X-ray diffractometer (Rigaku Miniflex 600). The surface morphology and chemical composition of the grown film are analysed using field-emission scanning electron microscope (Carl-Zeiss FE-SEM). The optical transmittance of Cd x Zn1−xO thin films is measured using UV–Vis spectrophotometer (Princeton SpectraPro-2300i). The electrical measurements are carried out using computer-interfaced Keithley source meter.
Results and discussion
X-ray diffraction
The XRD studies reveal that prepared Cd x Zn1−xO thin films are polycrystalline in nature. It is observed that films have hexagonal wurtzite structure with preferred orientation along c-axis. Sharper peak along (002) plane indicates the good crystallinity of the thin film. The absence of CdO peak confirms the proper distribution of Cd throughout the thin film without forming any separate impurity phase. The Cd content dependence of the (002) peak positions of Cd x Zn1−xO thin films are listed in Table 1. Peak position of pure ZnO thin film is matching with the standard JCPDS file [Card No. 01-079-020]. With addition of Cd, the (002) peak slightly shifts towards a lower angle, proves the substitution of Zn2+ by Cd2+ atoms. The interplanar distance ‘d’ is tabulated in the table, which is calculated from the Bragg’s equation (Santhosh et al. 2017):
where n is the order of diffraction, hkl the Miller indices of the plane of diffraction. The cell volume (\(v\)) and lattice parameter’s ‘a’ and ‘c’ for hexagonal structure can be calculated from relations (Makino et al. 2013), (Santhosh et al. 2017):
The estimated cell volume, a- and c-lattice parameters using XRD data are plotted as function of Cd concentration, shown in the Fig. 1. When the Cd content increases, a slight increase in interplanar distance, cell volume, a- and c-lattice parameter can be observed. Since the cationic radii of Cd2+ (0.97 Å) is different from that of Zn2+ (0.74 Å), the crystal show a change. The calculated average grain size is tabulated in Table 1, which shows that the average grain size increases when Cd concentration increases.
Further, to check thermal stability, all the deposited thin films are subjected to air annealing for 4 h at 400 °C. Fig. 2 shows the XRD spectrum of annealed thin films with various Cd concentration. The XRD patterns reveal that the annealed films are also hexagonal in crystal structure with polycrystalline nature. It also shows that preferred orientation of deposited Cd x Zn1−xO thin films is unaffected by annealing. From Table 1, it can be observed that the shift in the peak position of (002) plane is less for annealed Cd x Zn1−xO thin films than as-deposited thin films. Figure 1 also shows that the cell volume, a- and c-lattice parameters of annealed thin films are reduced as compared with the as-deposited Cd x Zn1−xO thin films. This may be because of reduction in the Cd concentration, due to re-evaporation during annealing treatment. For all the composition of Cd x Zn1−xO thin films, grain size increases after annealing, which may be because of recrystallization process taking place during annealing.
Scanning electron microscope
Fig. 3 shows the high-resolution SEM images of the as-deposited Cd x Zn1−xO thin films. It shows that all the thin films are free from pinhole and cracks. It also shows that the films are composed of tightly packed and randomly arranged nanostructures. The as-deposited pure ZnO thin films consists of arbitrarily arranged nanostructures, which seems like randomly arranged hexagonal platelets, as shown in Fig. 3a. With addition of 5 at.% Cd, the surface morphology changes to the tightly packed granular structure, which is visible in Fig. 3b. As the Cd concentration is further increased to 10 and 20 at.%, discrete structure of smaller and larger tightly packed nanostructure can be observed as shown in Fig. 3c, d.
Annealing process changes the microstructure and nature of distribution of the crystallites in the thin films. It also helps proper oxidation of the unreacted metal ions and desorption of gaseous impurities. Fig. 4 shows the SEM images of annealed Cd x Zn1−xO thin films. The plate-like structure of pure ZnO modifies to randomly shaped granular structure after annealing. In all the remaining samples, recrystallization can be observed clearly, in which smaller clusters are agglomerated to form bigger clusters as shown in Fig. 4.
Elemental analysis
The compositional studies of prepared Cd x Zn1−xO thin films are carried out using EDX, spectra are shown in Fig. 5. The EDX spectra confirms the presence of Cd, Zn and oxygen. Impurities like sodium and silicon, which is from glass substrate also can be observed. It can be observed that the amount of Cd in prepared Cd x Zn1−xO thin film is less than that in the starting solution. Compositional information of as-deposited thin films are tabulated in Table 2. It is observed that the atomic concentration of Cd further reduces after annealing because of evaporation of Cd on annealing. This result is in agreement with XRD analysis.
Optical properties
The optical transmittance for all the as-deposited Cd x Zn1−xO thin film at room temperature is shown in Fig. 6a. The as-deposited pure ZnO samples are highly transparent in visible region with transmittance of > 95%. As the Cd concentration increases, the transmittance value decreases and reaches ~ 60% at 20 at.%. The decrease in transmittance may be because of increase in surface roughness, which causes the scattering of light and it also may be because of increase in free electron absorption, which is consistent with the decrease in resistivity. The band gap values are determined from plots of (αhν)2 vs. (hν). The band gap value is determined from extrapolation of linear portion of (αhν)2 to the (hν) axis. It is observed that the band gap value decreases as Cd increases. The obtained band gap values are tabulated in Table 3. The decrease in band gap values is because of substitution of Zn2+ ions by Cd2+ ions in ZnO lattice. After annealing, the transmittance value remains almost constant, but slight increase in the band gap is observed. The tauc’s plot for annealed Cd x Zn1−xO is shown in Fig. 6b. The slight increase in band gap may be because of evaporation of Cd from ZnO lattice, as observed from XRD and EDX analysis.
Electrical properties
All the as-deposited thin films show n-type conductivity, which is tested using hot-probe experiment. The I–V measurement of thin films with aluminium co-planar contacts shows the linear ohmic nature of the thin film (shown in Fig. 7). The measured resistance, calculated conductivity of the Cd x Zn1−xO thin film is tabulated in Table 4. Conductivity of Cd x Zn1−xO thin film increases with increase in Cd concentration up to 10 at.%. The Cd atom may occupy interstitial position in ZnO lattice and donates two electrons to conduction band, which is responsible for increase in conductivity. With 20 at.% Cd concentration, the conductivity decreases, which may be because of decrease in crystallinity, as observed from XRD. After annealing, decrease in the conductivity is observed for all the Cd x Zn1−xO thin films. The decrease in the conductivity is because of evaporation of Cd, as observed from EDX analysis.
Conclusion
Thin film of Cd x Zn1−xO (0 ≤ x ≤ 0.20) are deposited on soda lime glass substrates. The deposited films were wurtzite in structure with orientation along (002) direction. The shift in the (002) peak position confirms the incorporation of Cd in ZnO lattice. Annealing process does not affect the preferred orientation of the Cd x Zn1−xO thin film. After annealing, slight change in the surface morphology and reduction in Cd content was observed. Red shift in the band gap values was observed with increase in Cd concentration. It is particularly interesting to note that the electrical conductivity of as-deposited ZnO thin films increases after Cd incorporation.
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Acknowledgements
One of the author Bharath S.P. is grateful to National Institute of Technology, Karnataka and MHRD for financial support throughout research work. Authors are also grateful to DST-PURSE, Mangalore University for providing SEM and EDAX facility.
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Bharath, S.P., Bangera, K.V. & Shivakumar, G.K. Effect of cadmium incorporation on the properties of zinc oxide thin films. Appl Nanosci 8, 187–193 (2018). https://doi.org/10.1007/s13204-018-0661-8
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DOI: https://doi.org/10.1007/s13204-018-0661-8