Photoinjection and carrier recombination kinetics in photoanode based on (TM)FeO3 adsorbed TiO2 quantum dots

The work being reported was carried out with motivation to address the issues being faced by DSSC by designing organic dye attached to (TM)FeO3/TiO2 structures (where TM = Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn) using first principles methods. The structural and electronic properties of (TiO2)54 quantum dot (QD), clusters (TM)FeO3, adsorbed (TM)FeO3/(TiO2)54 and dye attached (TiO2)54/(TM)FeO3 structures are described in detail. The structural stability of the clusters exhibited consistent trend in such a way that the cluster CuFeO3 is most stable whereas ZnFeO3 is least stable structure. The band gap of the QD is reduced after adsorption of the clusters to make harvesting of solar light in visible region except (TiO2)54/Fe2O3 and (TiO2)54/ZnFeO3 which are found active in infrared region of electromagnetic spectrum. The value of recombination rate is decreased whereas the electron injection rate is increased after adsorption of (TM)FeO3 on the QD.

Automated summary

The research focuses on addressing issues faced by DSSC by designing organic dye attached to (TM)FeO3/TiO2 structures using first principles methods. The structural and electronic properties of different structures are described, with stable cluster trends and reduced band gap of QD after adsorption.