Disclosed are chalcogenide nanomaterials, preferably metal chalcogenide nanomaterials, for example, copper, lead and/or silver chalcogenide nanomaterials. Also provided is a method or process of synthesizing or preparing a chalcogenide nanomaterial, preferably a metal chalcogenide nanomaterial. In an example, a wet-chemical method is used to prepare metal chalcogenide nanomaterials, preferably in a solvent and in the presence of one or more organic ligands. Another example method involves producing metal chalcogenide nanomaterial and includes the steps of forming a mixture of a metal precursor, a chalcogen-based ligand, a solvent and a chalcogen precursor, heating the mixture at a reaction temperature for a duration of reaction time, and separating a produced metal chalcogenide nanomaterial.

A nanomaterial includes quantum dots having a crystal structure, wherein the quantum dots include an exposed surface in a specific direction, and the exposed surface has a ligand bound thereto.

A nanomaterial includes quantum dots having a crystal structure, wherein the quantum dots include an exposed surface in a specific direction, and the exposed surface has a ligand bound thereto.

There is provided a quantum dot solar cell having a high optical absorption coefficient. The quantum dot solar cell includes a quantum dot layer 3 including a plurality of quantum dots 1, wherein the quantum dot layer 3 includes a first quantum dot layer 3A having an index /x of 5% or more, wherein x is an average particle size, and is a standard deviation. The quantum dot layer 3 also includes a second quantum dot layer 3B that is provided on the light entrance surface 3b and/or the light exit surface 3c of the first quantum dot layer 3A and has an average particle size and an index /x smaller than those of the first quantum dot layer 3A.

There is provided a quantum dot solar cell having a high optical absorption coefficient. The quantum dot solar cell includes a quantum dot layer 3 including a plurality of quantum dots 1, wherein the quantum dot layer 3 includes a first quantum dot layer 3A having an index /x of 5% or more, wherein x is an average particle size, and is a standard deviation. The quantum dot layer 3 also includes a second quantum dot layer 3B that is provided on the light entrance surface 3b and/or the light exit surface 3c of the first quantum dot layer 3A and has an average particle size and an index /x smaller than those of the first quantum dot layer 3A.

A continuous flow reactor for the efficient synthesis of nanoparticles with a high degree of crystallinity, uniform particle size, and homogenous stoichiometry throughout the crystal is described. Disclosed embodiments include a flow reactor with an energy source for rapid nucleation of the procurors following by a separate heating source for growing the nucleates. Segmented flow may be provided to facilitate mixing and uniform energy absorption of the precursors, and post production quality testing in communication with a control system allow automatic real-time adjustment of the production parameters. The nucleation energy source can be monomodal, multimodal, or multivariable frequency microwave energy and tuned to allow different precursors to nucleate at substantially the same time thereby resulting in a substantially homogenous nanoparticle. A shell application system may also be provided to allow one or more shell layers to be formed onto each nanoparticle.

A continuous flow reactor for the efficient synthesis of nanoparticles with a high degree of crystallinity, uniform particle size, and homogenous stoichiometry throughout the crystal is described. Disclosed embodiments include a flow reactor with an energy source for rapid nucleation of the procurors following by a separate heating source for growing the nucleates. Segmented flow may be provided to facilitate mixing and uniform energy absorption of the precursors, and post production quality testing in communication with a control system allow automatic real-time adjustment of the production parameters. The nucleation energy source can be monomodal, multimodal, or multivariable frequency microwave energy and tuned to allow different precursors to nucleate at substantially the same time thereby resulting in a substantially homogenous nanoparticle. A shell application system may also be provided to allow one or more shell layers to be formed onto each nanoparticle.

Ligand-capped inorganic particles, films composed of the ligand-capped inorganic particles, and methods of patterning the films are provided. Also provided are electronic, photonic, and optoelectronic devices that incorporate the films. The ligands that are bound to the inorganic particles are composed of a cation/anion pair. The anion of the pair is bound to the surface of the particle and at least one of the anion and the cation is photosensitive.

The present disclosure provides a precursor composition and a method for preparing inorganic nanocrystals. The precursor composition is used to prepare inorganic nanocrystals and is in the form of a gel, the precursor composition includes a precursor and an organogel medium for dispersing the precursor, and the precursor is one or more of a cationic precursor, an anionic precursor. The precursor composition not only greatly expands the selection range of potential precursors and their concentration range, but also simplifies the synthesis system of the nanocrystals and minimizes the impact on the environment, and improves the stability or repeatability of the method of preparing the inorganic nanocrystals.

The present disclosure provides a precursor composition and a method for preparing inorganic nanocrystals. The precursor composition is used to prepare inorganic nanocrystals and is in the form of a gel, the precursor composition includes a precursor and an organogel medium for dispersing the precursor, and the precursor is one or more of a cationic precursor, an anionic precursor. The precursor composition not only greatly expands the selection range of potential precursors and their concentration range, but also simplifies the synthesis system of the nanocrystals and minimizes the impact on the environment, and improves the stability or repeatability of the method of preparing the inorganic nanocrystals.