Bismuth Hexagons: Facile Mass Synthesis, Stability and Applications

A unique direct electrodeposition technique involving very high current densities, high voltages and high electrolyte concentrations is applied for highly selective mass synthesis of stable, isolable, surfactant‐free, single‐crystalline Bi hexagons on a Cu wire at room temperature. A formation mechanism of the hexagons is proposed. The morphology, phase purity, and crystallinity of the material are well characterized by FESEM, AFM, TEM, SAED, EDX, XRD, and Raman spectroscopy. The thermal stability of the material under intense electron beam and intense laser light irradiation is studied. The chemical stability of elemental Bi in nitric acid shows different dissolution rates for different morphologies. This effect enables a second way for the selective fabrication of Bi hexagons. Bi hexagons can be oxidized exclusively to α‐Bi2O3 hexagons. The Bi hexagons are found to be promising for thermoelectric applications. They are also catalytically active, inducing the reduction of 4‐nitrophenol to 4‐aminophenol. This electrodeposition methodology has also been demonstrated to be applicable for synthesis of bismuth‐based bimetallic hybrid composites for advanced applications. Picky: The selective mass synthesis of stable, isolable, surfactant‐free, single‐crystalline Bi hexagons (see picture) is demonstrated by forceful electrodeposition on a Cu wire at room temperature by applying high current densities, high voltages and high electrolyte concentrations quite contrary to the usual electrodeposition methodologies. The material is promising for thermoelectric and catalytic applications.