Core-shell nanostructures with platinum overlayers conformally coating palladium nano-substrate cores and facile solution-based methods for the preparation of such core-shell nanostructures are described herein. The obtained Pd@Pt core-shell nanocatalysts showed enhanced specific and mass activities towards oxygen reduction, compared to a commercial Pt/C catalyst.

The passivation of a nonlinear optical crystal for use in an inspection tool includes growing a nonlinear optical crystal in the presence of at least one of fluorine, a fluoride ion and a fluoride-containing compound, mechanically preparing the nonlinear optical crystal, performing an annealing process on the nonlinear optical crystal and exposing the nonlinear optical crystal to a hydrogen-containing or deuterium-containing passivating gas.

The passivation of a nonlinear optical crystal for use in an inspection tool includes growing a nonlinear optical crystal in the presence of at least one of fluorine, a fluoride ion and a fluoride-containing compound, mechanically preparing the nonlinear optical crystal, performing an annealing process on the nonlinear optical crystal and exposing the nonlinear optical crystal to a hydrogen-containing or deuterium-containing passivating gas.

A method for manufacturing a single crystal may be by solution growth from a seed crystal, in a unit including a tank and a growth platform having a lower plate. The method may include: fastening the seed to the lower plate; introducing a crystallization solution of density d.sub.S into the tank; treating the solution in order to render it supersaturated; bringing the seed into contact with the supersaturated solution; rotating the platform until the single crystal is obtained. Before bringing the seed into contact with the supersaturated solution, the method may include forming, in the tank, of a zone for trapping parasitic crystals of density d.sub.C by introducing, into the tank, a liquid, immiscible with the growth solution, of density d>d.sub.S and d<d.sub.c, which forms with the growth solution an interface located below the lower plate.

A method for manufacturing a single crystal may be by solution growth from a seed crystal, in a unit including a tank and a growth platform having a lower plate. The method may include: fastening the seed to the lower plate; introducing a crystallization solution of density d.sub.S into the tank; treating the solution in order to render it supersaturated; bringing the seed into contact with the supersaturated solution; rotating the platform until the single crystal is obtained. Before bringing the seed into contact with the supersaturated solution, the method may include forming, in the tank, of a zone for trapping parasitic crystals of density d.sub.C by introducing, into the tank, a liquid, immiscible with the growth solution, of density d>d.sub.S and d<d.sub.c, which forms with the growth solution an interface located below the lower plate.

Methods for producing silver nanostructures with improved dimensional control, yield, purity, monodispersed, and scale of synthesis.

Methods for producing silver nanostructures with improved dimensional control, yield, purity, monodispersed, and scale of synthesis.

Core-shell nanostructures with platinum overlayers conformally coating palladium nano-substrate cores and facile solution-based methods for the preparation of such core-shell nanostructures are described herein. The obtained Pd@Pt core-shell nanocatalysts showed enhanced specific and mass activities towards oxygen reduction, compared to a commercial Pt/C catalyst.

Embodiments of the present disclosure include techniques related to techniques for processing materials for manufacture of group-III metal nitride and gallium based substrates. More specifically, embodiments of the disclosure include techniques for growing large area substrates using a combination of processing techniques. Merely by way of example, the disclosure can be applied to growing crystals of GaN, AlN, InN, InGaN, AlGaN, and AlInGaN, and others for manufacture of bulk or patterned substrates. Such bulk or patterned substrates can be used for a variety of applications including optoelectronic and electronic devices, lasers, light emitting diodes, solar cells, photo electrochemical water splitting and hydrogen generation, photodetectors, integrated circuits, and transistors, and others.

In various examples, an anode, which may be for a metal ion-conducting electrochemical device, comprises a metal member; and a metal conducting coating, which may be an epitaxial (e.g., a homoepitaxial) metal conducing coating, disposed on at least a portion of the metal member (e.g., all portions of the metal member that would be or are in contact with the electrolyte of the metal ion-conducting electrochemical device). A metal conducting coating or an anode may be formed by electrodeposition in the presence of a field.