Provided are a quantum dot-ligand composite which includes quantum dots including a semiconductor nanocrystalline core that includes Group III and V elements and a semiconductor nanocrystalline shell that is disposed on the semiconductor nanocrystalline core and includes Group II and VI elements; and organic ligands coordinated to the quantum dots. Additionally, a quantum dot-ligand composite with high luminescence properties and stability according to the electrostatic effective binding ratio between the quantum dots and the organic ligands bound to the surface of the quantum dots, and a photosensitive resin composition, optical film, electroluminescent diode, and electronic device including the same can be provided.

Quantum dots that are cadmium-free and/or stoichiometncally tuned are disclosed, as are methods of making them. Inclusion of the quantum dots and others in a stabilizing polymer matrix is also disclosed. The polymers are chosen for their strong binding affinity to the outer layers of the quantum dots such that the bond dissociation energy between the polymer material and the quantum dot is greater than the energy required to reach the melt temperature of the cross-linked polymer.

A quantum dot manufacturing method comprises (a) dispersing, in a solvent, nano-seed particles whose crystal planes are exposed, and (b) growing semiconductor layers on the exposed crystal planes of the nano-seed particles in the solvent.

The invention relates to a self-passivating quantum dot and a preparation method thereof. The quantum dot is doped with a self-passivating element M and the self-passivating element M ranges from 0.1 wt % to 40 wt % in content. The self-passivating element is selected from the group consisting of Al, Zr, Fe, Ti, Cr, Ta, Si, and Ni. The preparation method comprises the steps of: adding a quantum dot core and a solvent into a reaction vessel, controlling the temperature to be 100-120 DEG C. and vacuumizing the reaction vessel for 30-50 min; filling the reaction vessel with inert gas, and rising the temperature to 230-280 DEG C.; and injecting a coating material precursor solution into the reaction vessel for coating the quantum dot core according to the injection amount being 1 or 2 times by molar concentration of the quantum dot core element per hour to prepare the self-passivating quantum dot. The self-passivating element M is doped with the quantum dot core precursor solution in the form of an M precursor, or is doped with the coating material precursor solution. Compared with the prior art, the self-passivating quantum dot has better appearance and is significantly improved in photostability.

A quantum dot includes a nano-seed particle having a particular crystal plane exposed, and a first epitaxial layer formed on the particular crystal plane of the nano-seed particle.

In various embodiments the present disclosure provides a core/shell nanocrystal comprising a core and a shell formed on the core, wherein the core/shell nanocrystal is co-doped with at least one metal dopant and at least one trivalent cation. In some embodiments, the trivalent cation is a Group 13 element. Methods of making and using the core/shell nanocrystal are also described.

A quantum dot includes a nano-seed particle having a particular crystal plane exposed, and a first epitaxial layer formed on the particular crystal plane of the nano-seed particle.

A quantum dot manufacturing method comprises (a) dispersing, in a solvent, nano-seed particles whose crystal planes are exposed, and (b) growing semiconductor layers on the exposed crystal planes of the nano-seed particles in the solvent.

A composition can include a copper containing nanocrystal.

Quantum dots that are cadmium-free and/or stoichiometncally tuned are disclosed, as are methods of making them. Inclusion of the quantum dots and others in a stabilizing polymer matrix is also disclosed. The polymers are chosen for their strong binding affinity to the outer layers of the quantum dots such that the bond dissociation energy between the polymer material and the quantum dot is greater than the energy required to reach the melt temperature of the cross-linked polymer.