Tin Oxide (SnO 2 ) Nanoparticles: Facile Fabrication, Characterization, and Application in UV Photodetectors.
Zhenping HuangJun ZhuYi HuYueping ZhuGuanghua ZhuLanping HuYou ZiWeichun HuangPublished in: Nanomaterials (Basel, Switzerland) (2022)
Tin oxide (SnO 2 ) nanomaterials are of great interest in many fields such as catalytic, electrochemical, and biomedical applications, due to their low cost, suitable stability characteristics, high photosensitivity, etc. In this contribution, SnO 2 NPs were facilely fabricated by calcination of tin (II) oxalate in air, followed by a liquid-phase exfoliation (LPE) method. Size-selected SnO 2 NPs were easily obtained using a liquid cascade centrifugation (LCC) technique. The as-obtained SnO 2 NPs displayed strong absorption in the UV region (~300 nm) and exhibited narrower absorption characteristics with a decrease in NP size. The as-fabricated SnO 2 NPs were, for the first time, directly deposited onto a poly(ethylene terephthalate) (PET) film with a regular Ag lattice to fabricate a flexible working electrode for a photoelectrochemical (PEC)-type photodetector. The results demonstrated that the SnO 2 -NP-based electrode showed the strongest photoresponse signal in an alkaline electrolyte compared with those in neutral and acidic electrolytes. The maximum photocurrent density reached 14.0 μA cm -2 , significantly outperforming black phosphorus nanosheets and black phosphorus analogue nanomaterials such as tin (II) sulfide nanosheets and tellurene. The as-fabricated SnO 2 NPs with relatively larger size had better self-powered photoresponse performance. In addition, the as-fabricated SnO 2 -NP-based PEC photodetector exhibited strong cycling stability for on/off switching behavior under ambient conditions. It is anticipated that SnO 2 nanostructures, as building blocks, can offer diverse availabilities for high-performance self-powered optoelectronic devices to realize a carbon-neutral or carbon-free environment.