A method for manufacturing a multilayer electronic component having an element body in which a functional part and a conductor part are laminated. The green multilayer body 11 is formed on the temporary holding film 62 formed on the release substrate. The green multilayer body 11 is formed by repeating the first step forming a green functional part using the first ink containing the functional particles and the second step forming the green conductor part using the second ink containing the conductive particles. The temporary holding film 62 has conductivity.

A multi-layered ceramic electronic component has a ceramic body including a dielectric layer and an internal electrode, and an external electrode formed outside of the ceramic body and electrically connected to the internal electrode. The internal electrode includes a conductive metal and a fiber-shaped ceramic additive. For example, the fiber-shaped ceramic additive can include barium titanate (BaTiO.sub.3) and, optionally, dysprosium (Dy) and/or barium (Ba). The fiber-shaped ceramic additive may have a diameter of 10 to 200 nm, and a ratio of length to diameter of 10 to 100.

A method of producing an enhanced ceramic matrix composite includes applying a tackifier compound to a fiber preform. The tackifier compound includes inorganic filler particles. The method further includes modifying the tackifier compound such that the inorganic filler particles remain interspersed throughout the fiber preform, and occupy pores of fiber preform.

Described herein are composite materials composed of ceramic particles coated with a surfactant incorporated within a polymer matrix, methods of making same, filaments composed of the same, and articles printed using the filaments. The composite materials and articles described herein have desirable electronic and thermal properties for use in radio frequency (RF) and millimeter wave devices and demonstrate reliable performance at elevated humidity levels.

Powder particles for forming a homogeneous green body having a sufficient strength and a process for producing a green body by using the powder particles. A green body is shaped by using powder particles of composite particles in which thermoplastic resin particles are scattered on surfaces of large particles in an amount within a predetermined volume ratio range with respect to the large particles, and loaded to form resin pools in contact point peripheral areas of adjoining ones of the large particles and form voids in areas other than the contact point peripheral areas when the thermoplastic resin particles are melted. A green body packed with the powder particles each having a small amount of the thermoplastic resin particles attached thereon is placed under a melting condition of the thermoplastic resin particles, the thermoplastic resin is melted and gathers around contact points (or proximal points) of the adjoining powder particles.

A method of producing an enhanced ceramic matrix composite includes applying a tackifier compound to a fiber preform. The tackifier compound includes inorganic filler particles. The method further includes modifying the tackifier compound such that the inorganic filler particles remain interspersed throughout the fiber preform, and occupy pores of fiber preform.

A method of producing an enhanced ceramic matrix composite includes applying a tackifier compound to a fiber preform. The tackifier compound includes inorganic filler particles. The method further includes modifying the tackifier compound such that the inorganic filler particles remain interspersed throughout the fiber preform, and occupy pores of fiber preform.

Hexagonal Boron Nitride (hBN) is a synthetic material that may be used in several applications due to its chemical inertness, thermal stability, and other beneficial properties. hBN composite materials and method for making such composites are described here. In particular composite materials including both functionalized hBN and cement or cementitious materials and methods for making the same are discussed. Such materials may be useful for construction, well cementing (both primary and remedial cementing), nuclear industry, 3D printing of advanced multifunctional composites, and refractory materials.

A cathode material for a solid oxide fuel cell comprises a perovskite type complex oxide which is represented by Formula 1: Gd.sub.1-xM.sub.xCoO.sub.3-.In Formula 1, M represents an alkali metal, x is larger than 0 and not more than 0.75, and ranges from 0 to 2.

A multi-layered ceramic electronic component has a ceramic body including a dielectric layer and an internal electrode, and an external electrode formed outside of the ceramic body and electrically connected to the internal electrode. The internal electrode includes a conductive metal and a fiber-shaped ceramic additive. For example, the fiber-shaped ceramic additive can include barium titanate (BaTiO.sub.3) and, optionally, dysprosium (Dy) and/or barium (Ba). The fiber-shaped ceramic additive may have a diameter of 10 to 200 nm, and a ratio of length to diameter of 10 to 100.