Multivariate Synthesis of Tin Phosphide Nanoparticles: Temperature, Time, and Ligand Control of Size, Shape, and Crystal Structure

Tin phosphides make up a class of materials that have received a noteworthy amount of interest in photocatalysis, charge storage, and thermoelectric devices. Dual stable oxidation states of tin (Sn2+ and Sn4+) allow tin phosphides to exhibit different stoichiometries and crystal phases. However, the synthesis of such nanostructures with control over morphology and crystal structure has proven to be a challenging task. Herein, we report the first colloidal synthesis of size-, shape-, and phase-controlled, narrowly disperse rhombohedral Sn4P3, hexagonal SnP, and trigonal Sn3P4 nanoparticles (NPs) displaying tunable morphologies and size dependent physical properties. The control over NP morphology and crystal phase was achieved by tuning the nucleation/growth temperature, Sn/P molar ratio, and incorporation of additional coordinating solvents (alkylphosphines). The absorption spectra of Sn3P4 NPs (3.0 +/- 0.4 to 8.6 +/- 1.8 nm) exhibit size-dependent blue shifts in energy gaps (1.38-0.88 eV) compared to the theoretical value of bulk Sn3P4 (0.83 eV), consistent with quantum confinement effects. The trigonal Sn3P4 NPs adopt rhombohedral Sn4P3 and hexagonal SnP crystal structures at 180 and 250 degrees C, respectively. Structural and surface analysis indicates consistent bond energies for phosphorus across different crystal phases, whereas the rhombohedral Sn4P3 NPs demonstrate Sn oxidation states distinctive from those of the hexagonal and trigonal phases because of the complex chemical structure. All phases exhibit N(1s) and nu((N-H)) energies suggestive of alkylamine surface functionalization and are devoid of tetragonal Sn impurities.