The development of non-equilibrium group IV nanoscale alloys is critical to achieving
new functionalities, such as the formation of a direct bandgap in a conventional
indirect bandgap elemental semiconductor. Here, we describe the fabrication of
uniform diameter, direct bandgap
Ge1−xSnx alloy nanowires, with a
Sn incorporation up to 9.2 at.%, far in excess of the
equilibrium solubility of Sn in bulk Ge, through a conventional catalytic bottom-up
growth paradigm using noble metal and metal alloy catalysts. Metal alloy catalysts
permitted a greater inclusion of Sn in Ge nanowires compared with conventional Au
catalysts, when used during vapour–liquid–solid growth. The
addition of an annealing step close to the Ge-Sn eutectic temperature
(230 °C) during cool-down, further facilitated the excessive
dissolution of Sn in the nanowires. Sn was distributed throughout the Ge nanowire
lattice with no metallic Sn segregation or precipitation at the surface or within
the bulk of the nanowires. The non-equilibrium incorporation of Sn into the Ge
nanowires can be understood in terms of a kinetic trapping model for impurity
incorporation at the triple-phase boundary during growth.
Ceria (CeO 2 ) has many important applications, notably in catalysis. Many of its uses rely on generating nanodimensioned particles. Ceria has important redox chemistry where Ce 4+ cations can be reversibly reduced to Ce 3+ cations and associated anion vacancies. The significantly larger size of Ce 3+ (compared with Ce 4+ ) has been shown to result in lattice expansion. Many authors have observed lattice expansion in nanodimensioned crystals (nanocrystals), and these have been attributed to the presence of stabilized Ce 3+ -anion vacancy combinations in these systems. Experimental results presented here show (i) that significant, but complex, changes in the lattice parameter with size can occur in 2-500 nm crystallites, (ii) that there is a definitive relationship between defect chemistry and the lattice parameter in ceria nanocrystals, and (iii) that the stabilizing mechanism for the Ce 3+ -anion vacancy defects at the surface of ceria nanocrystals is determined by the size, the surface status, and the analysis conditions. In this work, both lattice expansion and a more unusual lattice contraction in ultrafine nanocrystals are observed. The lattice deformations seen can be defined as a function of both the anion vacancy (hydroxyl) concentration in the nanocrystal and the intensity of the additional pressure imposed by the surface tension on the crystal. The expansion of lattice parameters in ceria nanocrystals is attributed to a number of factors, most notably, the presence of any hydroxyl moieties in the materials. Thus, a very careful understanding of the synthesis combined with characterization is required to understand the surface chemistry of ceria nanocrystals.
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