A cathode assembly is provided in which, while preventing the occurrence of abnormal electric discharging between a projected portion of a backing plate and a side surface of a target, particles can be prevented from being generated. The cathode assembly for a sputtering apparatus of this invention has: a target made of an insulating material; a backing plate bonded to one surface of the target; and, where such a side of the backing plate as is on the side of the target is defined as a lower side, an annular shield plate disposed to lie opposite to the lower side of that projected portion of the backing plate which is projected outward beyond an outer peripheral end of the target. The cathode assembly has a bonding portion arranged to be protruded relative to the projected portion. An inner peripheral edge portion of the shield plate is positioned in a clearance between that extended portion of the target which is extended outward beyond the bonding portion in a state in which the target is kept bonded to the bonding portion, and the projected portion of the backing plate.

A method of discriminating a state of a sputtering apparatus in which, by sputtering a target (2), a film is formed on a substrate disposed to lie opposite to the target, the discrimination being made, prior to the film formation on the substrate, as to whether an atmosphere in the vacuum chamber is in a state fit for film formation. As the sputtering apparatus, use is made of one provided inside the vacuum chamber with an isolated space which is isolated from the vacuum chamber by an isolating means (6, 71˜73), the isolated space being for the target and the substrate to lie therein opposite to each other, the sputtering apparatus being so arranged that the isolated space is evacuated accompanied by the evacuation in the vacuum chamber. The vacuum chamber is evacuated to a predetermined set pressure and a gas is introduced therein in this state.

A method of discriminating a state of a sputtering apparatus in which, by sputtering a target (2), a film is formed on a substrate disposed to lie opposite to the target, the discrimination being made, prior to the film formation on the substrate, as to whether an atmosphere in the vacuum chamber is in a state fit for film formation. As the sputtering apparatus, use is made of one provided inside the vacuum chamber with an isolated space which is isolated from the vacuum chamber by an isolating means (6, 71˜73), the isolated space being for the target and the substrate to lie therein opposite to each other, the sputtering apparatus being so arranged that the isolated space is evacuated accompanied by the evacuation in the vacuum chamber. The vacuum chamber is evacuated to a predetermined set pressure and a gas is introduced therein in this state.

A piezoelectric ceramic sputtering target containing a perovskite type oxide represented by chemical formula (I) of ABO.sub.3 as a main component, wherein the component A of the chemical formula (I) contains at least K (potassium) and/or Na (sodium), the component B of the chemical formula (I) contains at least one selected from the group consisting of Nb (niobium), Ta (tantalum) and Zr (zirconium) with Nb (niobium) as a necessity, the piezoelectric ceramic sputtering target is composed of a plurality of crystal grains and grain boundaries existing among the crystal grains, and in the grain boundary, the molar ratio of at least one of Nb (niobium), Ta (tantalum), and Zr (zirconium) in the B components is higher than the molar ratio in the interior of the crystal grains by 30% or more.

The invention relates to a high-frequency-transparent component comprising: a main body (2) and a coating (3) consisting of metal-doped Al2O3 sputtered thereon, and to a method for producing said component.

The invention relates to a high-frequency-transparent component comprising: a main body (2) and a coating (3) consisting of metal-doped Al2O3 sputtered thereon, and to a method for producing said component.

A method is provided in which a lithium titanate precursor structure is subjected to element selective sputtering to form a lithium titanate structure including a lithium titanate core and a conformal layer on the lithium titanate core, wherein the conformal layer includes titanium oxide. A method of preparing an electrode for a lithium ion battery, wherein the electrode includes lithium titanate structures, is also provided.

A manufacturing method for a head slider coated with Diamond-like Carbon (DLC) includes: providing a substrate that is to be finally made into a head slider; depositing a DLC layer on a surface of the substrate, with carbon plasma source being sputtered in a direction that is vertical to the surface of the substrate; and doping a fluorine-doping (F-doping) layer on the DLC layer. Whereby the head slider has good film adhesion performance, higher hardness, better wear resistance, lower surface energy to obtain good hydrophobicity and oleophobicity, and lower fly height in HDD.

A manufacturing method for a head slider coated with Diamond-like Carbon (DLC) includes: providing a substrate that is to be finally made into a head slider; depositing a DLC layer on a surface of the substrate, with carbon plasma source being sputtered in a direction that is vertical to the surface of the substrate; and doping a fluorine-doping (F-doping) layer on the DLC layer. Whereby the head slider has good film adhesion performance, higher hardness, better wear resistance, lower surface energy to obtain good hydrophobicity and oleophobicity, and lower fly height in HDD.

Provided is a cylindrical sputtering target made of a metal material, which has reduced particles. The sputtering target includes at least a target material, wherein the target material includes one or more metal elements, and has a crystal grain size of 10 μm or less.