Abstract
Stabilized un-doped Zinc Telluride (ZnTe) thin films were grown on glass substrates under vacuum using a closed space sublimation (CSS) technique. A dilute copper nitrate solution (0.1/100 mL) was prepared for copper doping, known as an ion exchange process, in the matrix of the ZnTe thin film. The reproducible polycrystalline cubic structure of undoped and the Cu doped ZnTe thin films with preferred orientation (111) was confirmed by X-rays diffraction (XRD) technique. Lattice parameter analyses verified the expansion of unit cell volume after incorporation of Cu species into ZnTe thin films samples. The micrographs of scanning electron microscopy (SEM) were used to measure the variation in crystal sizes of samples. The energy dispersive X-rays were used to validate the elemental composition of undoped and Cu-doped ZnTe thin films. The bandgap energy 2.24 eV of the ZnTe thin film decreased after doping Cu to 2.20 eV and may be due to the introduction of acceptors states near to valance band. Optical studies showed that refractive index was measured from 2.18 to 3.24, whereas thicknesses varied between 220 nm to 320 nm for un-doped and Cu doped ZnTe thin film, respectively, using the Swanepoel model. The oxidation states of Zn+2, Te+2, and Cu+1 through high resolution X-ray photoelectron spectroscopy (XPS) analyses was observed. The resistivity of thin films changed from ~107 Ω·cm or undoped ZnTe to ~1 Ω·cm for Cu-doped ZnTe thin film, whereas p-type carrier concentration increased from 4 × 109 cm−2 to 1.4 × 1011 cm−2, respectively. These results predicted that Cu-doped ZnTe thin film can be used as an ideal, efficient, and stable intermediate layer between metallic and absorber back contact for the heterojunction thin film solar cell technology.
Highlights
Cadmium telluride (CdTe) based heterojunction tandem solar cells require a heavily doped, p-type back contact material of low resistivity as a buffer layer capable of long term stability [1].Simultaneously both high efficiency and stability of low cost photovoltaic cells are a challenging issue in solar cell technology
X-rays diffraction (XRD) measurements were performed for un-doped Zinc Telluride (ZnTe) thin films and
The peaks related to secondary phases or clustering issues of Cu-doped ZnTe system were not observed, which confirmed the presence of a single system of polycrystalline nature
Summary
Cadmium telluride (CdTe) based heterojunction tandem solar cells require a heavily doped, p-type back contact material of low resistivity as a buffer layer capable of long term stability [1]. Both high efficiency and stability of low cost photovoltaic cells are a challenging issue in solar cell technology. ZnTe can play an ideal role as a stable and efficient intermediate layer with CdTe absorber and metallic back contact for heterojunction type solar cells technology. ZnTe semiconductor has proven itself as a low resistive, stable, and efficient back contact for polycrystalline ZnTe/CdTe/CdS/ITO solar cells [5]. The values of electron affinity and work function of p-type CdTe thin films has been reported as 4.28 eV and
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