Abstract
Thin film solar cells based on cadmium telluride (CdTe) are complex devices which have great potential for achieving high conversion efficiencies. Lack of understanding in materials issues and device physics slows down the rapid progress of these devices. This paper combines relevant results from the literature with new results from a research programme based on electro-plated CdS and CdTe. A wide range of analytical techniques was used to investigate the materials and device structures. It has been experimentally found that n-, i- and p-type CdTe can be grown easily by electroplating. These material layers consist of nano- and micro-rod type or columnar type grains, growing normal to the substrate. Stoichiometric materials exhibit the highest crystallinity and resistivity, and layers grown closer to these conditions show n → p or p → n conversion upon heat treatment. The general trend of CdCl2 treatment is to gradually change the CdTe material’s n-type electrical property towards i-type or p-type conduction. This work also identifies a rapid structural transition of CdTe layer at 385 ± 5 °C and a slow structural transition at higher temperatures when annealed or grown at high temperature. The second transition occurs after 430 °C and requires more work to understand this gradual transition. This work also identifies the existence of two different solar cell configurations for CdS/CdTe which creates a complex situation. Finally, the paper presents the way forward with next generation CdTe-based solar cells utilising low-cost materials in their columnar nature in graded bandgap structures. These devices could absorb UV, visible and IR radiation from the solar spectrum and combine impact ionisation and impurity photovoltaic (PV) effect as well as making use of IR photons from the surroundings when fully optimised.
Highlights
Photovoltaic (PV) solar energy conversion is an attractive method for clean energy generation
The electric current passing through the aqueous electrolyte as a function of the voltage applied between the anode and the cathode provides guidance for selecting the material deposition voltage
When the two solutions are mixed (Figure 1c), the voltammogram indicates the growth of Te-rich cadmium telluride (CdTe) starting from ~1200 mV, and the formation of CdTe layers with varying stoichiometry
Summary
Photovoltaic (PV) solar energy conversion is an attractive method for clean energy generation. The CdS/CdTe-based thin film solar cell is progressing forward, entering into large scale manufacturing by the First Solar Company. Scaling up and manufacturing have been successfully established in industry [1,2], the scientific understanding of material issues and device physics need drastic improvements for further development of the device. Due to involvement of industry, lab-scale efficiency rapidly improved from 16.5% in 2001 to 20.4% [5] within a few years (2010–2014). The growth techniques are very different, but the CdS/CdTe thin film solar cell is capable of producing efficiencies over 10% after heat treatment with CdCl2. CdCl2 treatment has been known to scientists since 1976 [7] and used widely to produce devices, the effects of this processing step are not fully understood to date. Various complexities arising from materials issues and device configurations are discussed and presented
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