Improvement of front-junction GaInP by point-defect injection and annealing

Traditional front junction GaInP solar cells are radiation tolerant and can have good diffusion length, but have limited voltage and thus efficiency. Here, we investigate the impact of annealing on GaInP device performance. First, Zn-doped GaInP/AlGaInP double heterojunction structures are studied in order to investigate the impact of annealing in a simple structure. While standard anneals lower diffusion length and lifetime, annealing after injecting point-defects improves material quality, presumably by eliminating sources of non-radiative recombination. Atomic ordering is reduced by the anneal, which raises the device bandgap and requires consideration. These results can be used to improve front junction device performance while controlling the bandgap. Then, GaInP front-junction devices are created using anneals with and without point-defect injection. Voc and EQE trends follow the diffusion length and lifetime trends from the DH structures. Baseline devices have Woc of 0.484 V, raising to 0.504 V after a high temperature anneal. However, injecting point defects prior to the anneal results in a front junction device with Woc of 0.405 V and a diffusion length greater than 8 mu m. Optimized front-junction GaInP devices with an ARC have similar to 20% efficiency without a rear reflector.

Automated summary

Traditional front junction GaInP solar cells are radiation tolerant but have limited voltage and efficiency. The impact of annealing on GaInP device performance was investigated, showing that injecting point defects before annealing can improve material quality and device performance. Annealing also affects diffusion length and lifetime of the material.