Microstructure, optical and magnetic properties of Zr-doped SnO synthesized by the hydrothermal method

“…It has been proved that the undercoordinated metal atoms could serve as Lewis acid to absorb water molecules and these dissociated to form the hydroxyl groups. [ 32 ] The F atom could bond with the undercoordinated Sn to form chemical doping and thus reduce the formation of hydroxyl; and 2) The F atom could bond/substitute the as‐formed hydroxyl to decrease the inferior effects. The schematic illustration of the interaction between F atom and SnO 2 is shown in Figure 2D.…”

Reduced Surface Hydroxyl and Released Interfacial Strain by Inserting CsF Anchor Interlayer for High‐Performance Perovskite Solar Cells

“…It has been proved that the undercoordinated metal atoms could serve as Lewis acid to absorb water molecules and these dissociated to form the hydroxyl groups. [ 32 ] The F atom could bond with the undercoordinated Sn to form chemical doping and thus reduce the formation of hydroxyl; and 2) The F atom could bond/substitute the as‐formed hydroxyl to decrease the inferior effects. The schematic illustration of the interaction between F atom and SnO 2 is shown in Figure 2D.…”

Reduced Surface Hydroxyl and Released Interfacial Strain by Inserting CsF Anchor Interlayer for High‐Performance Perovskite Solar Cells

Effect of Li-doping on the optoelectronic properties and stability of tin(II) oxide (SnO) nanostructures

First principles investigation of 3d transition metal doped SnO monolayer based diluted magnetic semiconductors