A system for creating targeted vanadium oxide (VO.sub.2) nanoparticle compositions comprising a stock reaction mixture that is a fluid combination of at least one vanadium source combined with at least one dopant source. Each dopant source contains at least one target dopant element. The ratio of the number of vanadium atoms in the vanadium source to the number of target dopant element atoms in the dopant source is less than or equal to 10:1. A solvent that is compatible with said stock reaction mixture is selected. A pressure regulator increases the pressure of the solvent and the stock reaction mixture to between 0 and 5,000 psi. A heating element increases the temperature of the solvent to between 50 and 500 C. A mixing unit receives and mixes a continuous flow of stock reaction mixture with solvent to heat the stock reaction mixture and initiate formation of the targeted vanadium oxide (VO.sub.2) nanoparticle composition.

A system for creating targeted vanadium oxide (VO.sub.2) nanoparticle compositions comprising a stock reaction mixture that is a fluid combination of at least one vanadium source combined with at least one dopant source. Each dopant source contains at least one target dopant element. The ratio of the number of vanadium atoms in the vanadium source to the number of target dopant element atoms in the dopant source is less than or equal to 10:1. A solvent that is compatible with said stock reaction mixture is selected. A pressure regulator increases the pressure of the solvent and the stock reaction mixture to between 0 and 5,000 psi. A heating element increases the temperature of the solvent to between 50 and 500 C. A mixing unit receives and mixes a continuous flow of stock reaction mixture with solvent to heat the stock reaction mixture and initiate formation of the targeted vanadium oxide (VO.sub.2) nanoparticle composition.

The invention relates to a marking composition, by means of which better protection of goods than hitherto available can be achieved independently of the coloring of the goods. The marking composition comprises an infrared-absorbing particulate component and carbon derivative, wherein the weight ratio of infrared-absorbing component to carbon derivative is in the range of approx.. 10:1 to approx.. 10,000:1.

The invention relates to a marking composition, by means of which better protection of goods than hitherto available can be achieved independently of the coloring of the goods. The marking composition comprises an infrared-absorbing particulate component and carbon derivative, wherein the weight ratio of infrared-absorbing component to carbon derivative is in the range of approx.. 10:1 to approx.. 10,000:1.

The invention relates to a marking composition, by means of which better protection of goods than hitherto available can be achieved independently of the coloring of the goods. The marking composition comprises an infrared-absorbing particulate component and a carbon derivative, wherein the weight ratio of infrared-absorbing component to carbon derivative is in the range of approx. 10:1 to approx. 10,000:1.

Disclosed are nanostructured materials that reflect light in selected spectra incorporated in dark colored textiles or substrates. In one aspect, a light reflecting material includes a textile exhibiting a dark color and formed of a plurality of fibers, and nanostructures arranged on the fibers and formed of a plurality of nanoparticles, the nanostructures having a dimension size of substantially less than of a visible light wavelength, in which the nanostructures reflect light from the textile or substrate in at least one of infrared, near-infrared, or red visible light spectra.

Disclosed are nanostructured materials that reflect light in selected spectra incorporated in dark colored textiles or substrates. In one aspect, a light reflecting material includes a textile exhibiting a dark color and formed of a plurality of fibers, and nanostructures arranged on the fibers and formed of a plurality of nanoparticles, the nanostructures having a dimension size of substantially less than of a visible light wavelength, in which the nanostructures reflect light from the textile or substrate in at least one of infrared, near-infrared, or red visible light spectra.

High performance polyethylene (HPPE) members include at least 5 wt-% of a radiopaque component. The HPPE members are biocompatible and the radiopaque component is a particulate at least partially arranged inside a HPPE filament of the HPPE members. The radiopaque component may have a particle size of at most 1 m, preferably at most 0.5 m. Methods of making the HPPE members and various medical devices and repair products which include the HPPE members are also provided.

Disclosed is a multi nanolayer interface coating for a fiber of a composite including a first interface coating nanolayer deposited onto the fiber of the ceramic matrix composite, and a second interface coating nanolayer deposited onto the first interface coating nanolayer.

A flame-retardant fabric may include a cellulosic fiber and a modacrylic fiber, the cellulosic fiber being a natural cellulose fiber containing a phosphorus compound, the modacrylic fiber containing an antimony compound, the flame-retardant fabric including the modacrylic fiber containing the antimony compound in an amount of 14 to 54 wt %, antimony in an amount of not less than 1.7 wt %, and phosphorus in an amount of 0.3 to 1.5 wt % with respect to the total weight of the flame-retardant fabric, and the flame-retardant fabric having a weight per unit area of not less than 160 g/m.sup.2. The flame-retardant fabric can be produced by subjecting a fabric including a natural cellulose fiber and a modacrylic fiber containing an antimony compound to flame-retardant treatment with a phosphorus compound.