Synthesizing Janus nanoparticles including forming a lamellar phase having water layers, organic layers, and a surfactant, and reacting chemical precursors in the lamellar phase to form the Janus nanoparticles at interfaces of the water layers with the organic layers.

Provided is a method and system for making powdered Fe.sub.16N.sub.2. The method can include sealing iron powder and a fixed amount of ammonia (NH.sub.3) gas within a pressure vessel. The pressure of the fixed amount of ammonia gas in the pressure vessel can be elevated so that Fe.sub.16N.sub.2 can be formed from the iron powder. Use of a pressure vessel and a fixed amount of ammonia gas can provide economic and environmental benefits such as higher conversion rates of iron powder into Fe.sub.16N.sub.2, reduced ammonia gas use, and reclamation of used ammonia gas.

There is provided a method for manufacturing a plurality of nanostructures comprising the steps of providing a plurality of spherical Zn structures and oxidizing the spherical structures in ambient atmosphere at a temperature in the range of 350° C. to 600° C. for a time period in the range of h to 172 h, such that ZnO nanowires protruding from the spherical structures are formed. There is also provided a field emission arrangement comprising a cathode having the aforementioned ZnO nanowire structures arranged thereon.

Nanowire synthesis and one dimensional nanowire synthesis of titanates and cobaltates. Exemplary titanates and cobaltates that are fabricated and discussed include, without limitation, strontium titanate (SrTiO.sub.3), barium titanate (BaTiO.sub.3), lead titanate (PbTiO.sub.3), calcium cobaltate (Ca.sub.3Co.sub.4O.sub.9) and sodium cobaltate (NaCo.sub.2O.sub.4).

A radio wave absorber provided with a radio wave absorbing film formed on a substrate, the radio wave absorber being capable of absorbing radio waves over a broad frequency band and exhibiting superior radio wave absorbing properties even with a radio wave absorbing film thinner than 1 mm. A film forming paste suitable for forming a radio wave absorbing film that is provided in the radio wave absorber. In a radio wave absorber provided with a radio wave absorbing film formed on a substrate, a particular epsilon-type iron oxide is employed in the radio wave absorbing film and relative permittivity of the radio wave absorbing film is set to 6.5 to 65.

There is provided a radio wave absorber including a powder of a hexagonal ferrite; and a binder, in which the radio wave absorber has a squareness ratio in a range of 0.40 to 0.60.

There is provided a radio wave absorber including a magnetic powder and a binder, in which a volume filling rate of the magnetic powder in the radio wave absorber is 35% by volume or less, a transmission attenuation amount is 8.0 dB or more, and a reflection attenuation amount is 8.0 dB or more.

There is provided a radio wave absorber including a magnetic powder and a binder, in which a volume filling rate of the magnetic powder in the radio wave absorber is 35% by volume or less, and a volume filling rate of a carbon component in the radio wave absorber is 0% by volume or more and 2.0% by volume or less.

According to embodiments of the present invention, a method of forming an indium oxide nanowire including copper-based dopants is provided. The method includes providing an indium-based precursor material and a copper-based dopant precursor material, and performing a thermal evaporation process to vapourise the indium-based precursor material and the copper-based dopant precursor material to form an indium oxide nanowire comprising copper-based dopants on a substrate. According to further embodiments of the present invention, an indium oxide nanowire including copper-based dopants and a gas sensor are also provided. According to further embodiments of the present invention, a method of forming a plurality of nanowires including metal phthalocyanine, a nanowire arrangement and a gas sensor are also provided.

Provided is a manufacturing method of indium oxide nanorods, including the following steps: providing a temperature furnace divided into a first zone and a second zone; putting an indium metal source in the first zone and putting a substrate in the second zone; modulating a temperature of the first zone to a first temperature and modulating a temperature of the second zone to a second temperature, wherein the first temperature is higher than the second temperature; and inputting argon and oxygen into the temperature furnace when the temperature of the first zone reaches the first temperature and the temperature of the second zone reaches the second temperature, wherein a ratio of argon and oxygen is in a range of 30:1 to 70:1 such that a plurality of indium oxide nanorods are formed on the substrate. An indium oxide nanorod is also provided.