Arsenic Activation and Compensation in Single Crystal CdTe Bilayers: Article No. 115702

In state-of-the art polycrystalline CdTe photovoltaics, group-V dopant activation is about 2%. Low activation can create electronic defects and lead to recombination and band tail losses. To develop methods to overcome this limitation, dopant activation was systematically investigated using molecular beam epitaxy (MBE) grown single crystal bilayers of As-doped CdTe on undoped CdTe. Results suggest multiple paths for improved As-activation in polycrystalline CdTe-based devices. It was found that the carrier concentration in this MBE material saturated at ~3 x 1016 cm-3, with high levels (>50%) of As-activation possible. High activation could be achieved with a post-growth activation temperature of ~450 degrees C, when the initial doping level was below the saturation level. However, at typical polycrystalline As incorporation levels (>5 x 1016 cm-3), the excess As is inactive or compensating, requiring elevated temperatures (500-600 degrees C) to achieve high activation. Oxygen in the annealing ambient was detrimental, while the effect of CdCl2 in the ambient is more case-dependent. A 575 degrees C activation anneal was combined with a 450 degrees C CdCl2 treatment to better understand the implications for polycrystalline CdTe. Interestingly, on highly doped samples, processes ending with a high temperature step displayed high activation, while those ending at 450 degrees C significantly reduced the carrier concentration (with or without CdCl2 in the ambient). Low activation can be restored with another high temperature anneal, allowing reproducible toggling between high and low activation based on the final temperature. Photoluminescence revealed the presence of donor-acceptor pairs in the low activation state that appear to be associated with a compensating defect.