Abstract
Heteroepitaxial, single-crystal-like Cu2O films on inexpensive, flexible, metallic substrates can potentially be used as absorber layers for fabrication of low-cost, high-performance, non-toxic, earth-abundant solar cells. Here, we report epitaxial growth of Cu2O films on low cost, flexible, textured metallic substrates. Cu2O films were deposited on the metallic templates via pulsed laser deposition under various processing conditions to study the influence of processing parameters on the structural and electronic properties of the films. It is found that pure, epitaxial Cu2O phase without any trace of CuO phase is only formed in a limited deposition window of P(O2) - temperature. The (00l) single-oriented, highly textured, Cu2O films deposited under optimum P(O2) - temperature conditions exhibit excellent electronic properties with carrier mobility in the range of 40–60 cm2 V−1 s−1 and carrier concentration over 1016 cm−3. The power conversion efficiency of 1.65% is demonstrated from a proof-of-concept Cu2O solar cell based on epitaxial Cu2O film prepared on the textured metal substrate.
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Introduction
Copper (I) oxide (Cuprous oxide, Cu2O) has a cubic structure with a lattice constant (a0) of 4.27 Å and is a native p-type semiconducting oxide due to negatively charged Cu vacancies that create an acceptor level ~0.16 eV above the valence band maximum1,2. It was the first semiconducting material discovered and rectifier diodes based on this material were demonstrated as early as 1920s3. Cu2O has been regarded as one of the most promising semiconducting oxides available for photovoltaic (PV) application because it has several important characteristics such as a good absorption coefficient for visible light, a high mobility for the majority carriers (~100 cm2 V−1 s−1 at room temperature for a single crystal Cu2O) and a large minority carrier diffusion length (2–12 μm)1,4. More importantly, Cu2O is an earth abundant and non-toxic material5,6. For these reasons, even if its bandgap (Eg ~ 1.9–2.1 eV) at room temperature is relatively higher than the optimum value (Eg ~ 1.4–1.5 eV) for AM1.5 solar spectrum, Cu2O has been considered a material suitable for the realization of low cost and large scale PV devices production for several decades.
In Cu2O heterojunction cells, the majority of photons are absorbed by Cu2O layer and photo-generated holes are transported through Cu2O layer to a back electrode directly in contact with Cu2O layer and electrons are transported through Cu2O layer to an n-type layer as minority and majority carriers, respectively. In order to fabricate high-performance Cu2O solar cells, it is vital to have excellent transport properties (carrier density and mobility and minority carrier life time) inside Cu2O layer and at the junction interface. However, most Cu2O films have been prepared on un-textured or polycrystalline substrates by thermal oxidation, electro-deposition and sputtering methods1,4,7,8,9,10,11,12,13,14,15,16,17,18,19,20. As a result, the films have a polycrystalline nature and rough surface morphologies, resulting in very defective films as well as poor interfaces at junctions and/or metal contacts comprising the cells. These defects act as sites for trapping, scattering and recombination of the carriers, which decrease PV parameters including power conversion efficiency. Unlike defective polycrystalline films, single-crystal-like, epitaxial Cu2O films are expected to greatly reduce the defects by eliminating high angle grain boundaries which are major sources for defects generation and as a result, to have much better electronic and optical properties of the films. Several groups have reported epitaxial growth of Cu2O films with improved electronic properties via several deposition methods such as pulsed laser deposition (PLD), molecular beam epitaxy and sputtering21,22,23,24,25. Matsuzaki et al.22 reported the improved majority carrier (hole) mobility from epitaxial Cu2O films grown via PLD. The mobility of 90 cm2 V−1 s−1 measured from the epitaxial Cu2O films is comparable to those of single crystals (~100 cm2 V−1 s−1) but is larger than the highest value (~60 cm2 V−1 s−1) reported from polycrystalline Cu2O films. However, epitaxial Cu2O films on rigid, size limited, expensive single crystal substrates are not practical for large-area, low-cost, Cu2O thin film based solar cells.
In this work, we report the first fabrication of heteroepitaxial Cu2O film solar cells on the textured, metallic foils. The Cu2O films prepared in optimum conditions exhibit exceptional transport properties, suitable for use as a p-type absorber layer of thin-film solar cells. Fabrication of high quality, epitaxial absorber layers on inexpensive, flexible, textured, metallic templates is potentially a very promising route to obtaining inexpensive, high-performance, non-toxic, earth-abundant solar cells26.
Results
Considering a phase equilibrium diagram of copper-oxygen system27, Cu2O phase is thermodynamically stable only in limited oxygen partial pressure (P(O2)) - temperature range. Hence, it is vital to study the influence of P(O2) and deposition temperature (Ts) on the phase, structural and electronic properties of Cu2O films. Figure 1 summarizes the phase and carrier mobility of the films deposited in a wide range of P(O2) - Ts space. The samples deposited in P(O2) ~ 10 mTorr and Ts = 700–750 °C were confirmed to be bright-brown colored, single phase Cu2O films with the carrier mobility of 40–60 cm2 V−1 s−1. In addition to having such high carrier mobility, these films were measured to have high carrier concentrations of 1016–1017 cm−3 which consequently, lead to low resistivity (ρ) of ~10 Ω · cm, as shown in Fig. 2. It is also confirmed that the single phase Cu2O films have the bandgap (Eg) of ~2.0 eV, close to Eg of 1.9–2.1 eV typically reported from Cu2O1,4, as shown in the inset of Fig. 2. Since the Cu2O is a direct band-gap semiconductor, the optical band gap (Eg) was obtained from the plot of the optical absorption coefficient as a function of photon energy (=hv) as in equation, αhv = (hv − Eg)1/2. When the films were deposited outside this optimum P(O2) - Ts range but still in P(O2) - Ts range where Cu2O phase is thermodynamically stable, the samples exhibit either (or both) degraded structural or (and) electronic properties. For instance, the films deposited at 600 °C in P(O2) = 0.01–0.1 mTorr were observed to have dark-brown color due to the presence of small amount of black-colored CuO phase with Cu2O phase in the films which was also confirmed by X-ray diffraction (XRD) analysis. The films deposited in P(O2) - Ts regions near Cu2O/CuO phase boundary line also have dark-brown or black color due to CuO phase formed partially or mostly in the films. Formation of CuO phase in these films, because of its poor conductivity28, is a primary reason that these films exhibit an insulating behavior or poor electronic performance with low carrier mobility (4.8–5.5 cm2 V−1 s−1) and concentration less than 1 × 1014 cm−3. On the other hand, the films grown in low P(O2) = 0.1–1 mTorr at 700 °C also exhibit an insulating behavior with extremely high resistivity even though XRD results confirm that the films are highly epitaxial and composed of single Cu2O phase with no 2nd phases including CuO phase. In this case, poor conductivity for the films should be caused by charge compensation of negatively charged copper vacancies via positively charged oxygen vacancies that should form and increase in their density when the films were deposited in lower P(O2) and thereby, both concentration and mobility of holes were substantially suppressed29.
Figure 3 summarizes XRD results of a Cu2O film grown on the NiW template with the developed oxide buffer architecture as illustrated in the inset of Fig. 3a in an optimized condition of P(O2) = 10 mTorr and Ts = 750 °C. The θ–2θ scan XRD result shown in Fig. 3a shows strong (00l) peak intensities from buffer layers and Cu2O film, indicating that all the layers are highly out-of-plane textured. Although no peaks related to CuO phase or other Cu2O orientations are visible, small NiO (111) peak at 2θ ~37.5° can be seen due to the oxidation of NiW metallic substrate during Cu2O growth. The self-limiting oxidation of NiW substrate forming a very thin, continuous, smooth NiO layer between NiW substrate and Y2O3 seed layer was commonly observed during film deposition in oxygen atmosphere30,31. Figure 3b–d show (002) ω- and (111) φ-scans as well as (111) pole figure for Cu2O layer. Small full-width-half-maximum values (Δω and Δφ) of ω- and φ-scans around 2.4° and 4.9° as well as a clear four-fold symmetry with 94% of cube texture suggest that the Cu2O film has excellent cube-on-cube epitaxy with the buffer layers and the substrate. Table 1 shows a summary of Δω, Δφ and %cube texture for all layers from the starting Ni-W substrate up to Cu2O layer. The oxide buffer layers have better out-of-plane texture with smaller Δω values in both rolling (φ = 0°) and transverse (φ = 90°) directions than the Ni-W substrate, while they have similar in-plane texture determined by the Δφ value. Improving the out-of-plane texture by the deposition of an initial oxide seed layer (e.g. Y2O3) layer on the Ni-W substrate has been reported and was explained on the basis of crystallographic tilting of the epitaxial film32. It is also observed that the in-plane and out-of-plane textures of oxide buffer layers are further improved by PLD of SrTiO3 (STO) top layer which exhibits ~0.8–1.4° smaller Δω and Δφ values than the underneath CeO2 layer. Such improved textures of the top layer lead Cu2O films to have smaller Δω and Δφ values and thereby, smaller angles of grain boundaries in the layer, as compared to the bare Ni-W substrate. It is noted that the basal planes of Y2O3, YSZ and CeO2 are 45° rotated relative to the basal planes of CuO2, STO and Ni-W because of the smaller lattice mismatches between [110]Y2O3,YSZ,CeO2 and [100]Cu2O,STO,Ni−W.
Field-emission scanning electron microscope (FE-SEM) images in Fig. 4 show microstructural features of highly textured Cu2O films deposited on the metallic templates. Low magnification plan-view image in Fig. 4a shows that the Cu2O layer is very dense and replicates the grain structures with grain sizes of 50–100 μm, initially developed from biaxially-textured, cube-oriented NiW substrates33,34. The high magnification image in Fig. 4b shows that the film has a smooth surface morphology, but there are a few of surface pores. The dominant growth mechanism of Cu2O films on STO should be either three-dimensional (3D) island (Volmer-Weber, V-W)24,35 or two-dimensional layer-by-layer followed by 3D island (Stranski-Krastanov, S-K) growth modes considering their surface energy (γSTO ~ 0.8 ~ 1.6 J/m2, γCu2O ~ 0.8–1.7 J/m2)36,37 and lattice mismatch (~8.6%). So, the surface pores could be caused by incomplete coalescence during film growth via V-W or S-K growth mechanism with increasing the film thickness.
Figure 5 shows a schematic of the solar cell structure with ~0.5 μm thick, epitaxial Cu2O absorber layer on NiW foil with the developed buffer architecture and the results of current-voltage (I-V) measurement under simulated AM1.5 illumination. For the fabrication of p-n junction devices with epitaxial Cu2O films, additional layers that act as a bottom electrode, an n-type layer and a top electrode were deposited underneath and on top of Cu2O p-type absorber layer, as illustrated in Fig. 5a. As a bottom electrode, we employ SrRuO3 (SRO) conductive oxide because of its low resistivity (ρ = ~2 × 10−4 Ω · cm) and a suitable work function (φSRO ~ 5.2 eV) to make Ohmic contact with Cu2O layer4. Moreover, SRO has good structural compatibility with STO and CuO2 that enables epitaxial growth of both Cu2O and SRO films on STO underlayer. We also experimentally confirm that insertion of SRO electrode between Cu2O films and STO layer does not change the epitaxial quality and microstructure of Cu2O films using XRD and SEM characterizations. As an n-type layer, ZnO layer is selected since the layer has been considered the best n-type layer currently available8,9,10,14,15,18,19. Finally, as a top electrode layer, Al-doped ZnO, transparent conductive oxide (TCO) layer was deposited on top of n-type ZnO layer due to its excellent structural and chemical compatibility with n-type ZnO layer compared to ITO layer, another popular TCO layer for Cu2O solar cells7. The device shows power conversion efficiency of 1.65%, with an open circuit voltage (VOC) of 0.64 V, a short circuit current (JSC) of 5.7 mA cm−2 and a fill factor (FF) of 45%.
Discussion
It is essential for the samples to have both high carrier mobility and concentration to be used as an absorber layer. The samples with high carrier concentration but low mobility are most likely to be very defective with a high density of chemical imperfections or defects that act as recombination centers. On the other hand, the samples with high carrier mobility but low carrier concentration are typically too resistive and their Fermi energy level is not suitable for building a high built-in potential at the interface of p-n junctions. Both cases should limit significantly physical properties related to solar power conversion efficiency. Although some previous efforts have demonstrated Cu2O films with either high carrier mobility (over 50 cm2 V−1 s−1) or high carrier concentration (over 1016 cm−3), deposition of Cu2O films having both high carrier mobility and concentration without using single crystalline substrates has been considered very challenging in the field. To our best knowledge, a recent work only reported high carrier mobility of 50–70 cm2 V−1 s−1 as well as high concentration of ~1 × 1016 cm−3 from very thin (70 nm thick) epitaxial Cu2O films on (100) MgO single crystal substrates23, similar to the values reported in this study on technical substrates that can be scaled to very large-areas at low-cost.
The power conversion efficiency of 1.65% achieved in this study is comparable to most Cu2O solar cells (0.1–2%) prepared by thermal oxidation of Cu foils and thin film deposition techniques such as electrodeposition and sputtering4,7,8,9,10,11,15,18. We fitted J-V curve of the solar cell using a well-known equivalent circuit model where series resistance (RS) and shunt resistance (RSH) are connected to the solar cell composed of an electric current source and a p-n junction diode. Fitting results show that RS and RSH are 5 Ω · cm−2 and 600 Ω · cm−2, respectively. This indicates that Cu2O solar cell in this study does not follow an ideal behavior of solar cells composed of an electric current source and a diode. The carrier recombination in Cu2O film and at Cu2O/ZnO interface and the series resistance of PLD grown films are responsible for a gap between the theoretical behavior and real behavior of Cu2O solar cell. Although the power conversion efficiencies of 4–6.1% were recently reported from the solar cell fabricated on thermally oxidized, thick Cu2O sheets14,20, our results indicate that thin film Cu2O solar cells can be successfully implemented onto NiW foil templates. Higher efficiency of the cell would be expected with further optimization of Cu2O absorber layer thickness and cell fabrication process to improve light absorption. In addition, we will also explore ways, such as hydrogenating thin ZnO layer to passivate Cu2O/ZnO interface and finding more appropriate n-type oxide materials having better structural and chemical compatibility with Cu2O, to minimize the carrier recombination at Cu2O/ZnO interface and ultimately improve the power conversion efficiency of the solar cells.
In conclusion, we demonstrate heteroepitaxial thin film Cu2O solar cells on low-cost, flexible, NiW foil templates. The study reveals an optimum P(O2) - temperature region where the films have only single oriented, pure Cu2O phase without the presence of high resistive CuO phase and as a result, excellent electronic properties with high carrier mobility in the range of 40–60 cm2 V−1 s−1 and concentration over 1016 cm−3. Detailed XRD analysis confirms that the films have excellent cube-on-cube epitaxy with over 98% cube texture and much smaller Δω and Δφ values than those of buffers and NiW metallic substrate. As a proof of concept, the power conversion efficiency of 1.65% is achieved for a cell fabricated on 0.5 μm thick, epitaxial Cu2O absorber layer on the buffered NiW template.
Methods
Biaxially-textured Ni-W foils with three heteroepitaxial oxide buffers comprised of CeO2 cap (60 nm)/YSZ barrier (100 nm)/Y2O3 seed (80 nm) grown by reactive sputtering were used32,33. This specific template architecture was developed for epitaxial growth of YBa2Cu3O7−x superconducting films capable of carrying high critical currents and such templates are routinely fabricated in lengths of 100’s of meters in a roll-to-roll configuration33,34. To complete the buffer stack for epitaxial Cu2O films, ~100 nm thick, (100) oriented, epitaxial STO layer was then grown via PLD using a KrF excimer laser (248 nm) at Ts of 700 °C and P(O2) of 10 mTorr. Our preliminary study confirmed that STO layer was required for epitaxial growth of Cu2O films because of poor chemical compatibility between CeO2 and Cu2O layers. All Cu2O films with ~0.5 μm thickness were deposited in a wide P(O2) - Ts range by PLD at optimized laser energy density and target-substrate distance which were ~3 J cm−2 and 5 cm, respectively. To fabricate a solar cell structure with an epitaxial Cu2O absorber layer, we additionally introduced ~100 nm thick epitaxial SRO conductive oxide layer between Cu2O and STO layers as well as n-type ZnO and Al-doped ZnO TCO layer on top of Cu2O layer. The crystalline phase, texture and microstructural properties of the samples were characterized by using XRD and FE-SEM. Electronic properties (resistivity, carrier mobility and concentration) of Cu2O films were characterized at Van der Pauw geometry using Hall effect measurement. Optical properties of the films were measured by a UV/Vis spectrophotometer. Photovoltaic properties were measured under AM 1.5 G simulated sunlight (PV Measurements, Inc.) with the aid of an electrochemical workstation (CH Instruments, CHI 660C). The active cell size was 6 mm2 and we used a mask during illumination to minimize the effect of the peripheral illumination on energy conversion efficiency measurements.
Additional Information
How to cite this article: Wee, S. H. et al. Heteroepitaxial Cu2O thin film solar cell on metallic substrates. Sci. Rep. 5, 16272; doi: 10.1038/srep16272 (2015).
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Acknowledgements
Research partially sponsored by the Laboratory Directed Research & Development (LDRD) funds, Oak Ridge National Laboratory and the RENEW(Research and Education in Energy; Environment & Water) Institute at SUNY-Buffalo. Jung-Kun Lee acknowledges the support from National Science Foundation (Grant No. CMMI-1333182).
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S.H.W. co-conceived the project, designed experiments, prepared the samples by PLD, characterized structural properties of the samples by XRD and SEM and wrote the manuscript. P.-S.H and J.-K.L. measured electronic and photovoltaic properties of the samples. J.-K.L. contributed to the scientific discussions. A. G. co-conceived the work and contributed to the scientific discussions. All authors reviewed and edited the manuscript.
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Wee, S., Huang, PS., Lee, JK. et al. Heteroepitaxial Cu2O thin film solar cell on metallic substrates. Sci Rep 5, 16272 (2015). https://doi.org/10.1038/srep16272
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