Surface chemistry of thiol ligand passivation on perovskite quantum dots depends on the coordinating molecule structure, and essentially affects the bonding mechanism, ligand composition and their organization. Moreover
Surface chemistry of thiol ligand passivation on perovskite quantum dots depends on the coordinating molecule structure, and essentially affects the bonding mechanism, ligand composition and their organization. Moreover, silyl thiol, owing to the formation of hydrophilic and highly strained edge-shared tetrahedra hole surrounded by hydrophobic silicate rings, may catalyze the reaction for organic alkene species. This unique surface chemistry can be easily identified by the diagnostic vibrations
