Optical and Electrical Properties of (SnO 2 ) X (In 2 O 3 ) 1-X thin Films Prepared by Pulse Laser Deposition Technique

In this work, fundamental wavelength (1064 nm) Q- switched Nd:YAG laser with 800 mJ peak energy on SnO 2 :In 2 O 3 target to produce ITO thin films. Thin films characterized by UV-visible absorbance, DC conductivity, Hall effect measurements and X-ray diffraction. It was found that the transmission increase with increasing In 2 O 3 ratio from 0 to 0.5 reaching about 88% in visible range. It can be seen that the conductivity increase with increasing ratio from 0 to 0.3 then decrease at 0.5 ratio. It can be found from Hall effect measurement that the mobility μ H increase at 0.1 ratio then decrease with more In 2 O 3 content.


Introduction
Conducting oxide thin films are being an important component in different optoelectronic devices such as solar cells [1], light emitting diodes [2] and photodiodes devices [3] in which they are used as transparent electrodes. The resistivity of these electrodes should be minimized as much as possible with keeping its high optical transparency particularly over the visible region of the solar spectrum. Indium Tin oxide ITO is a promising material due to its exclusive properties such as high electrical conductivity, high optical transparency for light [4,5].
A transparent electrode is needed in manufacturing of solar cells on the side where light enters. Normally, transparent conductive oxides (TCO) like indium tin oxide (ITO) or zinc oxide (ZnO) are commonly used for such purpose [6].
We need to study the optical and electrical properties for used to reach optimum conditions for preparation ITO films. The unique properties of ITO come from its structure and composition.
One unit cell contains16 units of In 2 O 3 . Therefore, for defect free In 2 O 3 crystal, there are 80 atoms in one unit cell. The lattice constant is reported to be 10.118Å [7]. When tin atoms substitute for indium atoms, it forms either SnO or SnO 2 If SnO is formed, tin acts as an acceptor since it accepts an electron. Otherwise, when SnO 2 is formed, it acts as donor. The material retains its bixbyite structure. However, if the doping level is extremely high, the tin atoms may enter interstitially and distort the lattice structure. The high transparency in the visible wavelength range of 400 -800 nm was explained by a low concentration of mid-gap states, typically responsible for absorption of photons with energies below the band-gap energy [8].
As the tin concentration increases, the carrier concentration increases until a saturation level is reached. An increase in the tin concentration above this saturation level causes a decrease in the free carrier concentration. ITO has metal like electrical properties because the carrier concentration is typically around 10 20 to 10 21 cm -3 .
X-ray diffraction Bragg's law was used to calculate inter-plane distance for crystals (d hkl ) from the condition of X-ray diffracted interference from parallel planes [9] hkl n 2 d sin where Ө is diffraction angle and λ is the used XRD wavelength.
The x-ray diffraction peaks broadening is used to calculate crystalline size by Scherrer equation formula [10].
Where λ is the used x-ray wavelength, FWHM is full width at half maximum (in radians) and θ is diffraction angle.

Experimental Part
Stannic oxide (SnO 2 ) purity (99.98 %) powder by FERAK, England Company and Indium (III) oxide (In 2 O 3 ), with purity (99.9 %) by Hi Media Laboratories Pvt.Ltd. (India) of these materials were mixed, with different In 2 O 3 :SnO 2 ratio (0, 10, 30 and 50) % in gate mortar to use it to make target as a disk of 1.5cm diameter and 0.3cm thickness using hydraulic piston type (SPECAC), under pressure of 6 tons for 10 minutes SnO 2 , In 2 O 3 and SnO 2 : In 2 O 3 thin films were prepared by Q switched pulsed laser laser (Huafei Tongda Technology-DIAMOND-288 pattern EPLS) λ = 1064 nm with 800 mJ peak power inside a vacuum chamber at vacuum (10 -3 Torr) using double stage rotary pump. Pulsed laser used to growth thin film by interaction of the pulsed laser beam with a target formed laser-induced plasma used to deposit thin films on glass substrates at low pressure. The set-up of laser deposition chamber photograph is given in Figure 1. The focused Nd:YAG SHG Q-switching laser incident beam coming through a window is making an angle of 45° with the target surface. The substrate is placed parallel in front of the surface of the target.
The produced films were characterized by X-ray diffraction (XRD), Dc conductivity, Hall effect measurements and UV-visible absorption to study the effect of In 2 O 3 :SnO 2 ratio on produced thin films properties.  Table 1 shows all peaks observed in XRD and a comparison with standard peaks.     The variation of logarithm of DC conductivity with reciprocal temperature for pure SnO 2 films and its composite with In 2 O 3 at different ratio (0.1, 0.3 and 0.5) annealed at 773K were carried out in the temperature range (303-473)K as shown in Figure 5.

Results and Discussion
This figure shows that all films have two activation energies and these activation energies decrease with increasing of In 2 O 3 content. All activation energies and their ranges values have been listed in Table 2. Also it can be seen that the conductivity increase from 0.9046 to 14.8478 Ω -1 .cm -1 with increasing ratio from o to 0.3 then decrease to 12.0992 at 0.5. The DC conductivity increase with increasing In 2 O 3 :SnO 2 ratio due to that (In) ion will act as the donor impurities may occupy shallow donor levels in the film, resulting in the reduction of conduction activation energy [11].   The results obtained from Hall effect show that all films were (n-type). By using of Hall coefficient and films conductivity the charge carrier (n H ) and mobility (μ H ) have been calculated. The variation of n H and μ H with In 2 O 3 : SnO 2 ratio (x) are shown in Figure 6. It is seen that (n) increases with increasing of In 2 O 3 content to 0.5. Such behavior is expected as a result of the substitution doping of In 3 + creating one extra free carrier in the process. As the doping level is increased, more dopant atoms occupy lattice sites of Sn atoms resulting in more charge carriers. while the mobility μ H increase at 0.1 ratio then decrease with more In 2 O 3 content.

Conclusions
Transparent, electrically conductive films were obtained with good specifications, with a maximum transmission value of 88% at the visible spectrum. The best samples with In 2 O 3 : SnO 2 ratio equal 0.3, with an electric conductivity of 14.84 Ω -1 .cm -1 and with optical transmission up to 80%, while samples with lower or higher ratio in both measurements have lacking in specification.