A method of synthesizing an electrode material for lithium ion batteries from Fe.sub.3O.sub.4 nanoparticles and multiwalled carbon nanotubes (MWNTs) to yield (Fe.sub.3O.sub.4-NWNTs) composite heterostructures. The method includes linking the Fe.sub.3O.sub.4 nanoparticles and multiwalled carbon nanotubes using a π-π interaction synthesis process to yield the composite heterostructure electrode material. Since Fe.sub.3O.sub.4 has an intermediate voltage, it can be considered an anode (when paired with a higher voltage material) or a cathode (when paired with a lower voltage material).

The present invention is related to effect pigments exhibiting a deep black body color as well as a blue interference color, to a process for the production of such pigments as well as to the use thereof, especially in coating compositions.

The present invention is related to effect pigments exhibiting a deep black body color as well as a blue interference color, to a process for the production of such pigments as well as to the use thereof, especially in coating compositions.

The present invention provides an EMI shielding device including a flame retarding, thermal interface material composite with a through plane thermal conductivity of no less than 30 W/mK and a dielectric withstanding voltage of no less than 1 kV/mm, where the composite includes at least one dielectric layer of self-aligned, carbon-based materials associated with superparamagnetic particles and at least one layer of fillers including a blend of dielectric heat transfer materials with a thermal or UV curable polymer or phase change polymer. The anisotropic heat transfer carbon-based materials associated with superparamagnetic materials are aligned under a low magnetic field strength of less than 1 Tesla to an orientation that results in a high thermal conductivity direction which can conduct the maximum heat from the adjacent device of the present composite. The present invention also provides a method for preparing the composite.

Systems and methods for sequestering carbon, evolving hydrogen gas, producing iron oxide as magnetite, and producing magnesium carbonate as magnesite through sequential carbonation and serpentinization/hydration reactions involving processed olivine- and/or pyroxene-rich ores, as typically found in mafic and ultramafic igneous rock. Precious or scarce metals, such nickel, cobalt, chromium, rare earth elements, and others, may be concentrated in the remaining ore to facilitate their recovery from any gangue material.

Systems and methods for sequestering carbon, evolving hydrogen gas, producing iron oxide as magnetite, and producing magnesium carbonate as magnesite through sequential carbonation and serpentinization/hydration reactions involving processed olivine- and/or pyroxene-rich ores, as typically found in mafic and ultramafic igneous rock. Precious or scarce metals, such nickel, cobalt, chromium, rare earth elements, and others, may be concentrated in the remaining ore to facilitate their recovery from any gangue material.

This disclosure provides methods of making functionalized PEG iron oxide nanoparticles.

This disclosure provides methods of making functionalized PEG iron oxide nanoparticles.

A method for producing high purity iron oxide nanoparticles using nanoparticle-producing cells, including: a) a pre-growth step that includes amplifying the nanoparticle-producing cell(s) in a pre-growth and/or fed-batch medium/media, and b) a growth step that includes amplifying the nanoparticle-producing cell(s) originating from the pre-growth step in a growth and/or fed-batch medium/media, wherein the pre-growth and/or growth and/or fed-batch medium/media comprise(s), per kilogram or liter of pre-growth and/or growth and/or fed-batch medium/media: i) no more than 0.005 gram of yeast extract, and ii) no more than 0.001 gram of CMR agent selected from boric acid and nitrilotriacetic acid, wherein the fed-batch medium when it is present is a medium that supplements the pre-growth and/or growth medium/media, and wherein more nanoparticles are produced in the growth step than in the pre-growth step.

A method for producing high purity iron oxide nanoparticles using nanoparticle-producing cells, including: a) a pre-growth step that includes amplifying the nanoparticle-producing cell(s) in a pre-growth and/or fed-batch medium/media, and b) a growth step that includes amplifying the nanoparticle-producing cell(s) originating from the pre-growth step in a growth and/or fed-batch medium/media, wherein the pre-growth and/or growth and/or fed-batch medium/media comprise(s), per kilogram or liter of pre-growth and/or growth and/or fed-batch medium/media: i) no more than 0.005 gram of yeast extract, and ii) no more than 0.001 gram of CMR agent selected from boric acid and nitrilotriacetic acid, wherein the fed-batch medium when it is present is a medium that supplements the pre-growth and/or growth medium/media, and wherein more nanoparticles are produced in the growth step than in the pre-growth step.