Abstract: A doping method using a three-step synthesis to make high-quality doped nanocrystals is provided. The first step includes synthesizing starting host particles. The second step includes dopant growth on the starting host particles. The third step includes final shell growth. In one embodiment, this method can be used to form Mn-doped CdS/ZnS core/shell nanocrystals. The Mn dopant can be formed inside the CdS core, at the core/shell interface, and/or in the ZnS shell. The subject method allows precisely controlling the impurity radial position and doping level in the nanocrystals.

Abstract: A doping method using a three-step synthesis to make high-quality doped nanocrystals is provided. The first step includes synthesizing starting host particles. The second step includes dopant growth on the starting host particles. The third step includes final shell growth. In one embodiment, this method can be used to form Mn-doped CdS/ZnS core/shell nanocrystals. The Mn dopant can be formed inside the CdS core, at the core/shell interface, and/or in the ZnS shell. The subject method allows precisely controlling the impurity radial position and doping level in the nanocrystals.

Abstract: The present invention concerns size- and shape-controlled, colloidal superparticles (SPs) and methods for synthesizing the same. Ligand-functionalized nanoparticles such as nonpolar-solvent-dispersible nanoparticles, are used, and the solvophobic interactions can be controlled. Advantageously, supercrystalline SPs having a superlattice structure, such as a face-centered cubic structure, can be produced. Further, the methods of the invention can provide SPs that self-assemble and are monodisperse. The SPs can be doped with organic dyes and further assembled into more complex structures.

Abstract: A dual-interaction ligand for rendering otherwise hydrophobic nanoparticles water soluble or suspendable has a hydrophilic base with a plurality of hydrophilic segments extending from a core of the base, where at least one segment or the core contains a hydrophobic groups capable of forming van der Waal interaction between hydrophobic groups of the dual-interaction ligand and other hydrophobic ligands, and at least one complexing functionality to complex a metal atom or ion of a nanoparticle. The dual-interaction ligands can be combined with hydrophobic nanoparticles, where the dual-interaction ligands can displace some or all of the hydrophobic ligands of the hydrophobic nanoparticles, to form a nanoparticle-dual interaction ligand complex that can be dissolved or dispersed readily in an aqueous solution. The dual interaction ligand can be functionalized to attach an antibody or other biomolecules such that the nanoparticle dual-interaction ligands complexes can contain biomolecules.

Abstract: An embodiment of the invention is a device for photo-stimulated color emission having at least one plurally doped semiconducting nanoparticle comprising at least one semiconducting material and a plurality of at least one dopant coupled with an irradiation source such that the plurally doped semiconducting nanoparticle emit electromagnetic radiation at two or more wavelengths where the intensities of the emissions depend on the intensity of the irradiation. In an embodiment of the invention, the plurally doped semiconducting nanoparticle can be a doped core/shell nanoparticle where the plurality of dopants can reside in exclusively the core, exclusively the shell, or in both the core and shell.

Abstract: The present invention concerns size- and shape-controlled, colloidal superparticles (SPs) and methods for synthesizing the same. Ligand-functionalized nanoparticles such as nonpolar-solvent-dispersible nanoparticles, are used, and the solvophobic interactions can be controlled. Advantageously, supercrystalline SPs having a superlattice structure, such as a face-centered cubic structure, can be produced. Further, the methods of the invention can provide SPs that self-assemble and are monodisperse. The SPs can be doped with organic dyes and further assembled into more complex structures.

Abstract: Novel water soluble paramagnetic organic nanoparticles are formed by a novel method where an organic solution of an organic compound is injected into water under agitation that is maintained for a desired period of time for nanoparticle growth followed by termination of the growth by the addition of an aqueous surfactant solution. The size of the nanoparticles depends on the time between injection and addition of the surfactant solution. In embodiments of the invention, the water soluble paramagnetic organic nanoparticles can be DPPH nanoparticles, DPPH nanoparticles doped with DPPH-H, or core/shell nanoparticles where a DPPH core is covered by a DPPH-H shell.

Abstract: A dual-interaction ligand for rendering otherwise hydrophobic nanoparticles water soluble or suspendable has a hydrophilic base with a plurality of hydrophilic segments extending from a core of the base, where at least one segment or the core contains a hydrophobic groups capable of forming van der Waal interaction between hydrophobic groups of the dual-interaction ligand and other hydrophobic ligands, and at least one complexing functionality to complex a metal atom or ion of a nanoparticle. The dual-interaction ligands can be combined with hydrophobic nanoparticles, where the dual-interaction ligands can displace some or all of the hydrophobic ligands of the hydrophobic nanoparticles, to form a nanoparticle-dual interaction ligand complex that can be dissolved or dispersed readily in an aqueous solution. The dual interaction ligand can be functionalized to attach an antibody or other biomolecules such that the nanoparticle dual-interaction ligands complexes can contain biomolecules.

Abstract: An embodiment of the invention is a device for photo-stimulated color emission having at least one plurally doped semiconducting nanoparticle comprising at least one semiconducting material and a plurality of at least one dopant coupled with an irradiation source such that the plurally doped semiconducting nanoparticle emit electromagnetic radiation at two or more wavelengths where the intensities of the emissions depend on the intensity of the irradiation. In an embodiment of the invention, the plurally doped semiconducting nanoparticle can be a doped core/shell nanoparticle where the plurality of dopants can reside in exclusively the core, exclusively the shell, or in both the core and shell.

Abstract: A doping method using a three-step synthesis to make high-quality doped nanocrystals is provided. The first step includes synthesizing starting host particles. The second step includes dopant growth on the starting host particles. The third step includes final shell growth. In one embodiment, this method can be used to form Mn-doped CdS/ZnS core/shell nanocrystals. The Mn dopant can be formed inside the CdS core, at the core/shell interface, and/or in the ZnS shell. The subject method allows precisely controlling the impurity radial position and doping level in the nanocrystals.