One aspect of the invention requires an apparatus for forming core-shell magnetic nanoparticles comprising: a magnetic nanoparticle source operable to generate a beam of nanoparticles; at least one shell material source comprising a bore through which the beam of nanoparticles may pass; and at least one controllable magnetic field generator, operable to generate a magnetic field which at least partially surrounds the at least one shell material source, wherein nanoparticles may be received at one end of the shell material source and the movement of the nanoparticles within the bore may be controlled by the controllable magnetic field to be coated by the shell material to specified dimensions, and nanoparticles may leave the other end of the shell material source. Another aspect of the in invention is a method of manufacturing core-shell magnetic nanoparticles, wherein: a beam of magnetic nanoparticles is generated by the nanoparticles source (34); and at least one vapour of at least one shell material is generated by at least one shell material source (36, 38, 50), wherein the at least one vapour of at least one shell material is located within the field generated by a controllable magnetic field generator (80); wherein the beam of nanoparticles enter the vapour of at least one shell material source (36, 38, 50) and the movement of the magnetic nanoparticles is controlled to coat the nanoparticles with the at least one shell material to specified dimensions and subsequently the coated nanoparticles are directed from the at least one shell material source to exit the at least one shell material source.

Example nanoparticles may include an iron-based core, and a shell. The shell may include a non-magnetic, anti-ferromagnetic, or ferrimagnetic material. Example alloy compositions may include an iron-based grain, and a grain boundary. The grain boundary may include a non-magnetic, anti-ferromagnetic, or ferrimagnetic material. Example techniques for forming iron-based core-shell nanoparticles may include depositing a shell on an iron-based core. The depositing may include immersing the iron-based core in a salt composition for a predetermined period of time. The depositing may include milling the iron-based core with a salt composition for a predetermined period of time. Example techniques for treating a composition comprising core-shell nanoparticles may include nitriding the composition.

A lead-free solder alloy composition includes a lead-free solder alloy; and a flower-shaped metal nano-particle including a metal core and protrusion portions extending from a surface of the metal core, wherein the metal core and the protrusion portions of the metal nano-particle include only one metal element.

The present invention provides a composition for antifreezing including a gold (Au) nanostructure in which at least a portion thereof is concave, thereby it is possible to increase a survival rate of cells due to having excellent effect of inhibiting ice recrystallization when cryopreservation of the cells, and maintain a texture of food even when using in the freezing of food.

Example nanoparticles may include an iron-based core, and a shell. The shell may include a non-magnetic, anti-ferromagnetic, or ferrimagnetic material. Example alloy compositions may include an iron-based grain, and a grain boundary. The grain boundary may include a non-magnetic, anti-ferromagnetic, or ferrimagnetic material. Example techniques for forming iron-based core-shell nanoparticles may include depositing a shell on an iron-based core. The depositing may include immersing the iron-based core in a salt composition for a predetermined period of time. The depositing may include milling the iron-based core with a salt composition for a predetermined period of time. Example techniques for treating a composition comprising core-shell nanoparticles may include nitriding the composition.

Methods of forming metal multipod nanostructures. The methods may include providing a mixture that includes a metal acetylacetonate, a reducing agent, and a carboxylic acid. The mixture may be contacted with microwaves to form the metal multipod nanostructures. The methods may offer control over the structure and/or morphology of the metal multipod nanostructures.

Methods of forming metal multipod nanostructures. The methods may include providing a mixture that includes a metal acetylacetonate, a reducing agent, and a carboxylic acid. The mixture may be contacted with microwaves to form the metal multipod nanostructures. The methods may offer control over the structure and/or morphology of the metal multipod nanostructures.

The present specification relates to a method for preparing a metal nanoparticle.

Different AuPd nanoparticles, ranging from sharp-branched octopods to core@shell octahedra, can be achieved by inline manipulation of reagent flowrates in a microreactor for seeded growth. Significantly, these structures represent different kinetic products, demonstrating an inline control strategy toward kinetic nanoparticle products that should be generally applicable.

Discrete magnetic nanoparticles synthesized using a layer-by-layer technique are disclosed. The nanoparticles contain a magnetic core having a large magnetic moment, a plurality of layers and an exterior coating. The nanoparticles have utility in a wide range of biological and bioanalytical applications.