Abstract: Embodiments of the invention relate generally to creating semiconductor junctions with reduced contact resistance. In one embodiment, the invention provides a method of forming a composition of material, the method comprising: providing at least two populations of semiconducting materials; layering the at least two populations of semiconducting materials to form at least two layers; and consolidating the at least two populations of semiconducting materials, wherein the consolidating creates an electrical connection between the at least two layers.

Abstract: Embodiments of the invention relate generally to creating semiconductor junctions with reduced contact resistance. In one embodiment, the invention provides a method of forming a composition of material, the method comprising: providing at least two populations of semiconducting materials; layering the at least two populations of semiconducting materials to form at least two layers; and consolidating the at least two populations of semiconducting materials, wherein the consolidating creates an electrical connection between the at least two layers.

Abstract: Disclosed herein is a method of purifying and doping a population of semiconductor nanocrystals. The method includes mixing the population of semiconductor nanocrystals having a first material system and a first ligand with a set of particles in the presence of a first solvent, the set of particles having a second material system which is different from the first material system and a second ligand which is different from the first ligand, to form a mixture. The method also includes facilitating a ligand exchange and an ionic exchange in the mixture, altering the first material system of the population of semiconductor nanocrystals to a third material system, different from the first material system and the second material system. The method includes sonicating the mixture and isolating the population of semiconductor nanocrystals having the third material system and the second ligand from the mixture.

Abstract: Embodiments of the invention relate generally to increasing the thermoelectric performance of a material.

Abstract: A method for producing a high yield of high quality, low size distribution, and size tunable semiconductor nanocrystals. The method produces III-V, II-VI, II-V, IV-VI, IV, ternary, quarternary, and quinary semiconductor nanocrystals (quantum dots) using a catalyst assisted two-phase reaction.

Abstract: Embodiments of the invention relate generally to creating semiconductor junctions with reduced contact resistance. In one embodiment, the invention provides a method of forming a composition of material, the method comprising: providing at least two populations of semiconducting materials; layering the at least two populations of semiconducting materials to form at least two layers; and consolidating the at least two populations of semiconducting materials, wherein the consolidating creates an electrical connection between the at least two layers.

Abstract: Embodiments of the invention relate generally to nanocrystal compositions of matter. In one embodiment, the invention provides a composition comprising: a matrix material; and a plurality of quantum confined semiconductor nanocrystals embedded in the matrix material, wherein the composition has a first grain size of less than approximately 500 nm.

Abstract: Embodiments of the invention relate generally to methods of consolidating semiconductor nanomaterials.

Abstract: Embodiments of the invention provide methods of forming photovoltaic or thermoelectric materials, including photovoltaic or thermoelectric films. In one embodiment, the invention provides a method of forming a photovoltaic material, the method comprising: depositing an inorganic capped nanoparticle solution onto a substrate; and heating the substrate.

Abstract: A semiconductor nanocrystal composition comprising a Group V to VI semiconductor material and a method of making same. The method includes synthesizing a semiconductor nanocrystal core, where the synthesizing includes dissolving a Group V to VI anion gas in a first solvent to produce a Group V to VI anion precursor, preparing a cation precursor, and reacting the Group V to VI anion precursor with the cation precursor in the presence of a second solvent. The reacting may occur in a high pressure vessel.

Abstract: Embodiments of the invention provide methods of forming photovoltaic or thermoelectric materials, including photovoltaic or thermoelectric films. In one embodiment, the invention provides a method of forming a photovoltaic material, the method comprising: depositing an inorganic capped nanoparticle solution onto a substrate; and heating the substrate.

Abstract: A water based colorant that includes a polymer emulsion and semiconductor crystals capable of emitting light. The colorants include paints, inks and/or dyes can be applied to various substrates.

Abstract: A method for producing a high yield of high quality, low size distribution, and size tunable semiconductor nanocrystals. The method produces III-V, II-VI, II-V, IV-VI, IV, ternary, quarternary, and quinary semiconductor nanocrystals (quantum dots) using a catalyst assisted two-phase reaction.

Abstract: A shaped article comprising a plurality of semiconductor nanocrystals. Devices incorporating shaped articles are also provided. Methods of manufacturing shaped articles by various molding processes are also provided.

Abstract: A semiconductor nanocrystal complex including a metal layer formed on the outer surface of a semiconductor nanocrystal core after synthesis of the semiconductor nanocrystal core and a method for preparing a nanocrystal complex comprising forming a metal layer on a semiconductor nanocrystal core after synthesis of the semiconductor nanocrystal core. The metal layer may passivate the surface of the semiconductor nanocrystal core and protect the semiconductor nanocrystal core from the effects of oxidation. Also provided is a semiconductor nanocrystal complex with a shell grown onto the metal layer formed on the semiconductor nanocrystal core. In this embodiment, the metal layer may prevent lattice mismatch between the semiconductor shell and the semiconductor nanocrystal core.

Abstract: Light-emitting devices are provided that incorporate one or more underlying LED chips or other light sources and a layer having one or more populations of nanoparticles disposed over the light source. The nanoparticles may absorb some light emitted by the underlying source, and re-emit light at a different level. By varying the type and relative concentration of nanoparticles, different emission spectra may be achieved. White light and specialty-color emission may be achieved. Devices also may include multiple LED chips, with nanoparticles disposed over one or more underlying chips in an array.

Abstract: A semiconductor nanocrystal composite comprising a semiconductor nanocrystal composition dispersed in an inorganic matrix material and a method of making same are provided. The method includes providing a semiconductor nanocrystal composition having a semiconductor nanocrystal core, providing a surfactant formed on the outer surface of the composition, and replacing the surfactant with an inorganic matrix material. The semiconductor nanocrystal composite emits light having wavelengths between about 1 and about 10 microns.

Abstract: A method and system of retro-emission include a microlens array to focus light of a first wavelength on a layer of luminescent material configured to emit light of a second wavelength when excited by a light of the first wavelength.

Abstract: A system and method for distinguishing a first light source from other light sources utilizes an image receiver that can selectively engage and disengage a filter. The filter can be configured to either block bands of light corresponding to the light being emitted by either the first source or the other sources. By sequentially engaging and disengaging the filter from the image receiver, the first light source may be distinguished from other light sources.

Abstract: A personal care composition that includes a personal care ingredient and semiconductor nanocrystals. A method of protecting at least a portion of a body against ultraviolet radiation by applying a personal care composition is also provided.