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Se-loss-induced CIS Thin Films in RTA Process after Co-sputtering Using CuSe2 and InSe2 Targets

  • Kim, Nam-Hoon (Dept. of Electrical Engineering, Chosun University) ;
  • Jun, Young-Kil (Dept. of Electrical Engineering, Chosun University) ;
  • Cho, Geum-Bae (Dept. of Electrical Engineering, Chosun University)
  • Received : 2013.12.03
  • Accepted : 2014.03.19
  • Published : 2014.05.01

Abstract

Chalcopyrite $CuInSe_2$ (CIS) thin films were prepared without Se- / S-containing gas by co-sputtering using $CuSe_2$ and $InSe_2$ selenide-targets and rapid thermal annealing. The grain size increased to a maximum of 54.68 nm with a predominant (112) plane. The tetragonal distortion parameter ${\eta}$ decreased and the inter-planar spacing $d_{(112)}$ increased in the RTA-treated CIS thin films annealed at a $400^{\circ}C$, which indicates better crystal quality. The increased carrier concentration of RTA-treated p-type CIS thin films led to a decrease in resistivity due to an increase in Cu composition at annealing temperatures ${\geq}350^{\circ}C$. The optical band gap energy ($E_g$) of CIS thin films decreased to 1.127 eV in RTA-treated CIS thin films annealed at $400^{\circ}C$ due to the improved crystallinity, elevated carrier concentration and decreased In composition.

Keywords

1. Introduction

Copper Indium Diselenide (CIS) is an I-III-IV2 chalcopyrite semiconductor that is used as an absorber layer in heterostructured thin film photovoltaic devices. The material has a high absorption coefficient (α > 105 cm−1) and direct band gap energy (Eg ~ 1.04 eV) [1], which makes it suitable for high-efficiency thin film solar cell applications. Several methods have been used and developed to prepare CIS thin films. A co-evaporation method followed by post-selenization process is used widely to achieve high-level conversion efficiency [2, 3]. Selenization / sulfurization of the sputtered Cu-In precursors using Se- / S-containing vapor is a suitable method for preparing CIS thin films at low cost [4]. On the other hand, these methods have several critical disadvantages in selenization / sulfurization processes for industrial production. The major drawbacks were highly toxic gas, process complexity with expensive equipment, slow reaction rate and poor adhesion to the back contact and poor reproducibility[5-7]. An eco-friendly, simple and cheap method for fabricating CIS thin films without additional selenization / sulfurization process using Se- / S-containing vapor needs to be developed, but few studies have been performed. Several efforts have been made to develop this method for preparing CIS thin films, such as Cu2Se + In2Se3 by Chen and CuSe2+In in a previous study [8]. However, the loss of Se in thin films due to volatilization in heat treatment at higher temperatures for longer times could not be suppressed [9, 10]. In this study, CuSe2 and InSe2 selenides as the starting targets for cosputtering were used to prepare CIS thin films by adjusting the chemical composition ratio of Se in the thin films. Rapid thermal annealing (RTA) is a powerful annealing method with a short cycle time and reduced thermal exposure [11]. The RTA was used in N2 gas ambient to form polycrystalline chalcopyrite phases and control Seloss from the Se-rich thin films with changes in the annealing temperature. This study examined the microstructure, electrical and optical properties of the Se-lossinduced near-stoichiometric CIS thin films from Se-rich thin films.

 

2. Experimental Details

Corning glass (20×20 mm2) was used as a substrate for deposition of 530-nm thin films by RF magnetron cosputtering (IDT Engineering Co.). Commercial CuSe2 (TASCO, 99.99% purity, 2 inches-diameter) and InSe2 (LTS Chemical Inc., 99.99% purity, 2 inches-diameter) targets were used at RF sputtering powers of 80 W and 50 W, respectively. The fixed set of process parameters was followed: pre-sputtering for 3 minutes, Ar gas flux of 50 sccm, base pressure of 1.0×10−6 Torr, 5.0 cm distance from the substrate to targets and vacuum pressure of 7.5×10−3 Torr during the sputtering process for 23 minutes at room temperature. The total thickness of the co-sputtered CuSe2 and InSe2 thin films was approximately 530 nm, which had the same deposition rate of 11.5 nm/min for each target. The RTA (Modular Process Technology Co., RTP- 600S) treatment of the 530-nm-thick thin films was performed to improve the temperature uniformity over the conventional furnace for 1 minute in N2 gas ambient at various temperatures ranging from 250℃ to 400℃ with an interval of 50℃ [9, 10]. A non-selenization / non-sulfurization process was performed during the RTA treatment for preparing CIS thin films without additional Se- / S-containing gas. The microstructure of the thin films was analyzed by X-ray diffraction (XRD, Philips, X’pert- PRO-MRD, Cu Kα = 0.15405 nm, 40 kV, 30 mA) over the scan range, 2θ = 10–80°. Energy-dispersive X-ray (EDX, Oxford Instruments, INCA) installed in the field emission scanning electron microscope (FESEM, JEOL, JSM-7500F) and X-ray photoelectron spectroscopy (XPS, VG Microtech, ESCA2000) were used to characterize the chemical composition ratio of Se in the as-deposited and RTA-treated thin films. XPS was equipped with a monochromatic Al Kα X-ray source (1486.6 eV). A take-off angle of 90° was used for all analyses. For the highresolution spectra, all binding energies were referenced to the C 1s peak at 285.0 eV. The optical properties of the as-deposited and RTA-treated thin films were measured using an ultraviolet-visible spectrophotometer (Varian Techtron, Cary500scan) in the range, 400–1500 nm. The electrical properties of the thin films, including the carrier concentration, resistivity and mobility were characterized using a Hall Effect measurement system (Accent Optical Technologies, HL5500PC) at room temperature.

 

3. Results and Discussion

Fig. 1 shows the XRD patterns of the (a) as-deposited and RTA-treated CIS thin films at various annealing temperatures including (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃. The XRD pattern of the as-deposited CIS thin film showed a broad and weak peak at approximately 2θ = 27° corresponding to the position of the (112) peak of CIS, confirming the almost amorphous nature. No notable changes in spectra except for the broad and weak peaks were detected in the RTA-treated CIS thin films at the relatively lower temperatures ≤ 300℃. This means that the microstructure was amorphous. The XRD patterns became sharper / stronger after annealing at ≥ 350℃, indicating enhanced crystalline quality in CIS thin films. The RTAtreated CIS thin films at both 350℃ and 400℃ showed the major XRD peaks with preferred orientations of (112), (220) / (204) and (312) / (116) at 2θ = 26.59°, 44.33° and 52.61°, respectively, corresponding to the crystallographic planes in the CIS chalcopyrite phase [6, 12]. The peak intensity of (112) was stronger than the other peaks in the RTA-treated CIS thin films at annealing temperatures ≥ 350℃. This indicates that the preferential orientation of the crystallites was the (112) direction with the perpendicularity to the surface [13].

The inset in Fig. 1 shows the mean grain sizes (D) and full width at half maximum (FWHM) of the predominant (112) diffraction peak. The mean grain sizes of the crystallites in each CIS thin film were estimated from the FWHM of the (112) diffraction peak using the Debye- Scherrer formula, D = 0.94λ / ωcosθ, where λ is the wavelength of Kα radiation of Cu (λ = 0.15406 nm), ω is the FWHM of the (112) diffraction peak and θ is the angle corresponding to the (112) reflection [14-16]. The FWHM of the (112) peak decreased at annealing temperatures ≥ 350℃, as shown in the inset in Fig. 1. This indicates that an increase in crystal quality in the CIS thin films as well as an increase in the grain size of CIS thin films along the (112) plane at an annealing temperature of approximately 350℃. The mean grain size of the as-deposited CIS thin films was approximately 8.16 nm, which increased to a maximum of 54.68 nm for the RTA-treated CIS thin films at an annealing temperature of 400℃ with rapid grain growth along the (112) plane observed above 350℃ [17]. Williamson and Smallman developed equations for calculating the dislocation density (δ), as shown in equation of δ = 1 / D2 [18], indicating that the dislocation in the CIS thin films was reduced significantly at annealing temperatures ~ 350℃.

Fig. 1.XRD patterns of the (a) as-deposited and the RTAtreated CIS thin films at the annealing temperatures of (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃. The inset shows the FWHM of the predominant (112) diffraction peak and the grain size of the CIS thin films under the same conditions

The lattice constants, a and c, of the tetragonal structure were calculated using the equation, 1/d2 = (h2+k2)/a2 + l2/c2, combined with the Bragg’s law, d = λ/2sinθ, where d is the spacing between the planes in the atomic lattice (inter-planar spacing), hkl are Miller indices, λ is the wavelength of CuKα radiation (λ = 0.15406 nm) and θ is the angle between the incident ray and the scattering planes [19]. For a particular incident X-ray wavelength, λ, and the angle, θ from XRD, the d spacing can be determined from Bragg’s law. The lattice constants, a and c, can also be calculated using the (112), (220) / (204) and (312) / (116) peaks, and are represented in Fig. 2. The lattice constants, a and c, were 0.268 nm and 0.728 nm, respectively, in the asdeposited CIS thin films. These are smaller values than those of the previously published values of 0.578 nm and 1.172 nm, respectively [6, 20]. The lattice constant, a, increased slightly in the RTA-treated CIS thin films at annealing temperatures ≥ 350℃ and reached a maximum of 0.288 nm at 400℃, whereas the lattice constant, c, increased with the RTA treatment and showed a maximum of 0.776 nm at 400℃. The tetragonal distortion parameter, η = c/2a, was in the range of 1.354–1.400. This range is larger than the value of 1.003–1.008 reported for most chalcopyrite tetragonal crystals [21, 22]. A higher distortion parameter was shown in the Se-rich CIS thin films [6]. The inter-planar spacing of the (112) peak (d(112)) was also calculated using Bragg’s law and is shown in Fig. 2. The d(112) increased rapidly at annealing temperatures ≥ 300℃. The better crystallinity was obtained by a decrease in the number of crystallographic-rearrangement-induced structural defects and internal stresses [23]. This is in agreement with the grain sizes of the RTA-treated CIS thin films in the inset in Fig. 1.

Fig. 2.Lattice constants (a and c), distortion parameter η and inter-planar spacing d(112) of the (a) as-deposited and RTA-treated CIS thin films at annealing temperatures of (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃.

Fig. 3 shows the chemical compositions of the asdeposited and RTA-treated CIS thin films with various annealing temperatures. The specimens were taken from a depth of 30 nm on each surface to obtain the atomic percentages of CIS thin films. The deviation from the chemical composition was used with the two parameters from the intrinsic defect model, Δm = [Cu] / [In] -1 and Δs = 2[Se]/([Cu]+3[In]) -1 [6]. The parameters, Δm and Δs, refer to the deviations from molecularity and valance stoichiometry, respectively. The material is stoichiometric when both parameters show no deviation. The chemical composition of the as-deposited and RTA-treated CIS thin films with various annealing temperatures was analyzed by extracting the atomic percentage of them with EDX and XPS detector units. The as-deposited CIS thin films had Δm = - 0.431 and Δs = 0.550. The Cu-poor (Δm < 0) and Se-excess (Δs > 0) composition was obtained in the asdeposited specimen. Although the deposition rates of the CuSe2 and InSe2 targets were similar, the Cu and In compositions were not identical. All specimens in this study showed a Cu-poor and Se-excess composition, but both deviations became close to ‘0’, indicating an approach to a near-stoichiometric composition at 400℃ in the RTA-treated CIS thin films. If the annealing temperature increased to more than 400℃, the Se-loss might be activated to be nearer-stoichiometric composition.

Fig. 3.Deviation parameters of Δm = [Cu]/[In] -1 and Δs = 2[Se] / ([Cu] + 3[In]) -1 from the chemical compositions of the (a) as-deposited and RTAtreated CIS thin films at annealing temperatures of (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃ [6].

The conductivity type was determined by the deviations (Δm and Δs) [24], which has been verified and developed the relationship further [6]. The conductivity of the CIS thin films in this study with Δm < 0 and Δs > 0 should have n-type conductivity, but the Hall Effect measurements showed p-type conductivity in all specimens. This was attributed to the large deviation from stoichiometry. Ptype conductivity induces better electrical conductivity and higher efficiency in solar cells compared to n-type conductivity [25]. Hall Effect measurements were performed to examine the electrical properties of the asdeposited and RTA-treated CIS thin films, such as the conductivity type, carrier mobility, resistivity, and carrier concentration, as a function of the annealing temperature, as shown in Fig. 4. The carrier concentration of the asdeposited CIS thin films was in the order of 1010 cm−3 excessive holes due to p-type conductivity. This is similar or inferior to the free carrier concentration reported in intrinsic p-type CIS thin films (1010 – 1021 cm−3) [26, 27]. The carrier concentration of the RTA-treated CIS thin films increased significantly to 1013cm-3 at annealing temperatures ≥ 350℃. Twelve possible intrinsic defects can exist in CIS thin films; vacancies (VCu, VIn, VSe), interstitials (Cui, Ini, Sei) and anti-site defects (CuIn, InCu, InSe, SeIn, CuSe, SeCu) [28]. The increased carrier concentration in the CIS thin films was attributed to the reduction in VSe and/or increase in the acceptor centers including VCu, VIn, CuIn and Sei. Considering the increase in Cu composition at 400℃ in Fig. 3, the increase in VIn is believed to be the main contribution to the increase in carrier concentration. The increase in carrier concentration, acting as acceptors in p-type CIS thin films, can lead to a decrease in the band gap energy of CIS thin films. This would allow more efficient harvesting of the incident light at longer wavelengths. The resistivity of the as-deposited and RTA-treated CIS thin films was in the order of 105 Ω- cm. The values (103 – 104 Ω-cm) reported in the p-type CIS thin films were similar to these values [29]. The high resistivity of the CIS thin films was attributed to the In-rich composition of CIS thin films. Highly conducting and highly resistive properties were obtained with Cu-rich and Cu-poor compositions, respectively [30]. The increase in Cu composition (Fig. 3) and the carrier concentration caused a decrease in the resistivity of the RTA-treated CIS thin films at annealing temperatures ≥ 350℃.

Fig. 4.Hall Effect measurements (carrier concentration, resistivity and carrier mobility) of the (a) asdeposited and RTA-treated CIS thin films at annealing temperatures of (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃.

Fig. 5 shows the experimentally-measured optical transmittance in the visible to near-infrared (NIR) spectral region of the as-deposited and RTA-treated CIS thin films. All spectra were ≤ 42% in the visible spectral region (400 - 800 nm). The mean optical transmittance was also ≤ 8% over the same wavelength range. The mean optical transmittance of the RTA-treated CIS thin films was 4.89% and 5.01% at annealing temperatures of 350℃ and 400℃, respectively. These were somewhat lower than that of the as-deposited CIS thin film (7.72%). Throughout the visible spectral region (400 - 800 nm), both the asdeposited and RTA-treated CIS thin films revealed considerable absorption because all the spectra converged to the ‘0’ value regardless of the annealing treatment. The Burstein–Moss (B–M) shift was also observed after the RTA treatment at annealing temperatures < 350℃. This is the decrease in the range of spectral transmission to the shorter solar emission spectrum in the optical transmittance, highlighting the advantages of CIS thin films as the absorber layer in thin film photovoltaic devices due to the shift of the absorption edge to a larger wavelength in absorption coefficient (α) [31-33]. When the wavelength range was widened from visible spectral region to the NIR spectral region (400-1500 nm), the mean optical transmittance of the RTA-treated CIS thin films at the annealing temperatures of 350℃ and 400℃ increased gradually to 36.89% and 25.18%, respectively. That of the as-deposited and RTA-treated CIS thin films annealed at ≤ 250℃ increased rapidly to 43.09–43.80% over the same spectral range. The equation, Eg=hc/λ, was used to calculate the optical band gap energies of the CIS thin films with the same thickness (530 nm), where h is Planck’s constant (4.135667×10−15 eVs), c is the velocity of light (3×108 m/s) and λ is the wavelength (nm) of the absorption onset (1/e = 37%). The optical band gap energy (Eg) of the as-deposited and RTA-treated CIS thin films at annealing temperatures of 250℃, 300℃, 350℃ and 400℃ were 1.495 eV, 1.583 eV, 1.714 eV, 1.672 eV and 1.127 eV, respectively, as shown in the inset in Fig. 5. This is inversely proportional to the deviation parameter, Δm, in Fig. 3. The decreased optical band gap energy at annealing temperatures of 400℃ was attributed to the increased grain size (Fig. 1), decreased In composition (Fig. 2), increased spacing d (better crystallinity) (Fig. 3) and increased carrier concentration (Fig. 4). This is attributed to both crystallinity and intrinsic defects that cause a shift in the absorption edge followed by the RTA treatment [17, 34]. An increase in grain size leads to a decrease in the optical band gap energy due to the fewer free carrier concentrations and lower potential barriers originating from large particles with fewer grain boundaries and imperfections [35].

Fig. 5.Optical transmittance of the (a) as-deposited and the RTA-treated CIS thin films at annealing temperatures of (b) 250℃, (c) 300℃, (d) 350℃ and (e) 400℃. The inset shows the calculated optical band gap energy of the CIS thin films under the same conditions

 

4. Conclusion

A co-sputtering process for preparing CIS thin films was advanced by using a CuSe2 and InSe2 targets without a Se- / S-containing gas in the RTA treatment by a function of the annealing temperature. The grains grew along the predominant (112) plane in the RTA-treated CIS thin films at annealing temperatures ≥ 350℃. The mean grain size of approximately 8.16 nm for the as-deposited CIS thin films increased to a maximum of 54.68 nm for the RTA-treated CIS thin films at an annealing temperature of 400℃. This suggests that the dislocation was reduced noticeably after annealing at~350℃, which was confirmed by the distortion parameter η. The inter-planar spacing d(112) increased after annealing at ≥ 300℃. This means that the crystallinity became improved. Despite the same deposition rates of each target in the co-sputtering process, a Cu-poor (Δm < 0) and Se-excess (Δs > 0) composition was obtained in the as-deposited specimen. The RTAtreated CIS thin films approached to the nearstoichiometric composition at the temperature of 400℃. The carrier concentration of the RTA-treated CIS thin films increased significantly from 1010 cm−3 to 1013 cm−3 after annealing at ≥ 350℃. The resistivity of the as-deposited CIS thin films was in the order of 105 Ω-cm due to the In-rich composition. It decreased with increasing Cu composition and carrier concentration at annealing temperatures of ≥ 350℃. The mean optical transmittance of the RTA-treated CIS thin films at annealing temperature of 400℃ was 25.18%, whereas that of the as-deposited CIS thin films was 43.29% in the spectral range of 400 - 1500 nm. The optical band gap energy (Eg) of the CIS thin films showed an opposite tendency to the deviation parameter Δm. It decreased from 1.495 eV (as-deposited) to 1.127 eV (RTA-treated at 400℃) due to the increase in grain size, inter-planar spacing and carrier concentration as well as the decrease in In composition. The decreased optical band gap energy would allow the absorption of more incident-light at longer wavelengths.

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