Elucidating the local structure of V substitutes in In2S3 as potential intermediate band material by X-ray absorption spectroscopy and first principles calculations
التفاصيل البيبلوغرافية
العنوان:
Elucidating the local structure of V substitutes in In2S3 as potential intermediate band material by X-ray absorption spectroscopy and first principles calculations
Vanadium doped indium sulfide, In2S3:V, is studied as a potential absorber material for intermediate band solar cells. Based on electronic considerations, it is usually assumed that V occupies octahedrally coordinated In sites, although geometrical considerations would favor tetrahedral In sites. In this study, we therefore combined experimental X-ray diffraction and X-ray absorption spectroscopy with ab initio theoretical calculations of both α and β phase to elucidate the incorporation of V in In2S3:V thin films grown with different V content and different growth temperatures. Comparing shape and position of the measured and calculated X-ray absorption edge of V, comparing experimentally determined and calculated V-S bond lengths, and evaluating the calculated heat of solution of V on different lattice sites all indicate that V is incorporated on octahedral rather than tetrahedral sites in the In2S3 matrix. For this material system, the electronic benefit of octahedral coordination thus outweighs the mechanical stress of the associated lattice relaxation. Finally, we studied the electronic structure of V-substituted α-In2S3 using hybrid density functional calculations and find that for a concentration of 1.9 at%, V on octahedrally coordinated In sites forms an empty intermediate band isolated from valence and conduction bands. By increasing the V content to 3.8 at%, however, the gap between intermediate band and conduction band closes, which results in a reduction of the band gap. This differs from the electronic structure calculated for β-In2S3:V and clearly demonstrates that both crystal structure and V incorporation site affect the resulting electronic material properties.
