Optimizing the Optical Properties on Tin Oxide Aerogels through Defect Passivation

John F. Hardy II, Madison King, Stephanie Hurst, Carlo R. daCunha

Tin oxide aerogels were synthesized using an epoxide-assisted technique and characterized with Fourier transform infrared, X-ray diffraction, and UV-Vis to study the effects of post-synthesis annealing and peroxide treatment. While bulk tin oxide exhibits an optical bandgap of 3.6 eV, its aerogel form often displays a larger apparent bandgap around 4.6 eV due to defects. Our study reveals that annealing induces a partial phase change from SnO2 to SnO, but is ineffective in removing defects. Conversely, peroxide passivation effectively lowers the bandgap and disorder levels, suggesting that dangling bonds are the primary cause of the increased bandgap in tin oxide aerogels. These findings offer insights for optimizing the optical properties of tin oxide aerogels for applications like solar cells.

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Stephanie Hurst
Associate Professor and Interim Chair, Inorganic Chemistry

Northern Arizona University, Chemistry and Biochemistry