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Controlling the Photocatalytic Activity and Benzylamine Photooxidation Selectivity of Bi 2 WO 6 via Ion Substitution: Effects of Electronegativity.

Anurak WaehayeeChuthamat DuangkamolManeerat ChotsawatTharit LerdwiriyanupapThitima PewklangHideki NakajimaTeera ButbureeAnyanee KamkaewSuwit SuthirakunTheeranun Siritanon
Published in: Inorganic chemistry (2023)
Doping or ion substitution is often used as an effective strategy to improve photocatalytic activities of several semiconductors. Most frequently, the dopants provide extra states to increase light absorption, alter the electronic structure, or lower the carrier recombination. This work focuses on ion substitution in Bi 2 WO 6 , where the dopants modify band-edge potentials of the catalysts. Specifically, we investigate how the electronegativity (EN) of the dopant could be used to tune the band-edge potentials and how such changes influence the photocatalytic mechanism. Compared to Te that has a lower EN, I lowers the band-edge potentials. While substitutions with both ions enhance Rh B photodegradation and benzylamine photooxidation, the modified band potentials of I-doped Bi 2 WO 6 influence the benzylamine photooxidation pathway, resulting in higher selectivity. Additionally, substitution of I 7+ in the Bi 2 WO 6 lattice improves the morphologies, decreases the band-gap energy, and reduces the carrier recombination. As a result, I-doped Bi 2 WO 6 shows almost 3 times higher %conversion while maintaining 100% selectivity in the oxidative coupling of benzylamine. The findings here signify the importance of the choices of dopants on the photocatalytic reactions and would benefit the design of other related materials for such applications.
Keyphrases
  • visible light
  • highly efficient
  • dna damage
  • dna repair
  • quantum dots
  • gold nanoparticles