An electrochemical reactor system includes: an electrochemical cell, having: an anode; a cathode; an electrolyte stream including an electrolyte and an iron-containing feedstock containing feedstock particles; and a channel that contains the electrolyte stream; and a magnetic field source positioned to provide a magnetic field at the surface of the cathode. The electrochemical cell electrochemically reduces the iron-containing feedstock to form iron particles at a surface of the cathode and in the magnetic field. The feedstock particles have an average particle size in at least one dimension of 10 micrometers or less, and the iron particles have an average particle size in at least one dimension of 50 to 1,000 micrometers, or the feedstock particles have an average particle size in at least one dimension of 25 micrometers or greater, and the iron particles have an average particle size in at least one dimension of 0.1 to 20 micrometers.

The present invention concerns methods of forming metal-containing nanoparticles or oxide thereof, especially metal alloy nanoparticles. The method the steps of providing at least two different kinds of transition metal ion by providing at least two kinds of metal ion-containing compound; a heating step in which the at least two metal ion-containing compounds are subjected to a temperature of at least 300 C. to form the metal alloy nanoparticles; a cooling step comprising cooling the product of step b; and each metal ion-containing compound is a transition metal complex having ligands coordinated to a transition metal ion, the ligands being selected from the group consisting of glyoxime; a glyoxime derivative; salicylaldimine; and a salicylaldimine derivative. The preferred methods are solution-based methods. Products of the methods are also described, as are their uses as electrocatalysts, as well as uses of the metal ion-containing compounds for making nanoparticles.

Provided is a spherical silver powder that can bring about excellent fine line printability when used in a conductive paste or the like. The spherical silver powder has a diameter D.sub.10 at a volume-based cumulative value of 10%, a diameter D.sub.50 at a volume-based cumulative value of 50%, and a diameter D.sub.90 at a volume-based cumulative value of 90% according to laser diffraction that satisfy a formula: (D.sub.90D.sub.10)/D.sub.50<1, and has a ratio D.sub.50/D.sub.BET of the D.sub.50 relative to a BET diameter D.sub.BET of not less than 0.90 and not more than 1.20.

A concentrated dispersion of nanometric silver particles, and a method of producing the dispersion, the dispersion including a first solvent; a plurality of nanometric silver particles, in which a majority are single-crystal silver particles, the plurality of nanometric silver particles having an average secondary particle size (d.sub.50) within a range of 30 to 300 nanometers, the particles disposed within the solvent; and at least one dispersant; wherein a concentration of the silver particles within the dispersion is within a range of 30% to 75%, by weight, and wherein a concentration of the dispersant is within a range of 0.2% to 30% of the concentration of the silver particles, by weight.

A new seedless synthesis of anisotropic nanoscale gold nanoflower (AuNF) particles uses bidentate thiolate ligands to protect the nanoparticle surface and a combination of reagents (for example, ligand, ascorbic acid, and hydroxide) to synthesis AuNF with controlled size and anisotropic properties. Compared to prior art gold nanospheres, AuNF produced approximately a 15-fold improvement in a drug delivery assay.

The present disclosure relates to a method of synthesizing metal nanoparticles, where the method includes mixing a metal precursor with a stabilizing ligand in a first zone of a first fluidic device to form a first mixture and mixing the first mixture with a reductant in a second zone of the first fluidic device to form a second mixture, such that the metal nanoparticles form in the second zone.