Embodiments of a tantalum (Ta) target pasting process for deposition chambers using RF powered processes include pasting at least a portion of the inner surfaces of the process chamber with Ta after using RF sputtering to deposit dielectric material on a wafer. Pressure levels within the process chamber are adjusted to maximize coverage of the Ta pasting layer. The Ta pasting encapsulates the dielectric material that has been inadvertently sputtered on the process chamber inner surfaces such as the shield. Oxygen is then flowed into the process chamber to form a tantalum oxide layer on the Ta pasting layer to further reduce contamination and particle generation.

A first memory device includes a first magnetoresistive cell having a plurality of deposition layers. A second memory device includes a second magnetoresistive cell having a plurality of deposition layers. Each of the plurality of deposition layers of the second magnetoresistive cell corresponds to one of the plurality of deposition layers of the first magnetoresistive cell. One of the plurality of deposition layers of the second magnetoresistive cell is thinner than a corresponding deposition layer of the plurality of deposition layers of the first magnetoresistive cell.

A substrate having a surface coated with a piezoelectric coating I, the coating including A-xMexN, wherein A is at least one of B, Al, Ga, In, Tl, and Me is at least one metallic element Me from the transition metal groups 3b, 4b, 5b 6b the lanthanides, and Mg the coating I having a thickness d, and further including a transition layer wherein the ratio of atomic percentage of Me to atomic percentage of Al steadily rises along a thickness extent δ3 of said coating for which there is valid:

δ3≤d.

A cutting tool comprises a coating on a substrate. The coating comprises a first layer element having an overall composition comprising the metal or metalloid elements aluminum, chromium, titanium, and silicon. The first layer element comprises at least 2 N.sub.lay first layer element layers. Each of the first layer element layers comprises a nitride layer comprising the metal or metalloid elements aluminum, chromium, titanium and silicon. The N.sub.lay first layer element layers comprise at least two different types of layers that at least differ in a silicon content. A first type of the layers has a highest silicon content C.sub.Si,H, (in at. %) and a second type of the layers has a lowest silicon content C.sub.Si,L (in at. %), both relative to a total of the metal and metalloid elements, and with a ratio of the lowest silicon content C.sub.Si,L to the highest silicon content C.sub.Si,H in the range of 0.25≤C.sub.Si,L/C.sub.Si,H≤0.9.

A thin film capacitor comprises a first electrode, a second electrode, and a dielectric substance disposed between the first electrode 10 and the second electrode. The second electrode has a first metallic layer, an intermediate layer, and a second metallic layer in sequence in this order from the side of the dielectric substance. The first metallic layer contains a metal element M1 as a main component, and the second metallic layer contains a metal element M2 different from the metal element M1 as a main component. The intermediate layer has one or more laminate structures each having a second metal sublayer containing the metal element M2 as a main component and a first metal sublayer containing the metal element M1 as a main component in sequence from the side of the first metallic layer toward the side of the second metallic layer.

A physical vapor deposition system includes a chamber, three target supports to targets, a movable shield positioned having an opening therethrough, a workpiece support to hold a workpiece in the chamber, a gas supply to deliver nitrogen gas and an inert gas to the chamber, a power source, and a controller. The controller is configured to move the shield to position the opening adjacent each target in turn, and at each target cause the power source to apply power sufficient to ignite a plasma in the chamber to cause deposition of a buffer layer, a device layer of a first material that is a metal nitride suitable for use as a superconductor at temperatures above 8° K on the buffer layer, and a capping layer, respectively.

A film-forming device according to one embodiment includes a chamber body, a support, a moving device, a shielding member, a first holder and a second holder, in the film-forming device, a substrate supported by the support is linearly moved. The shielding member is disposed above an area where the substrate is moved, and includes a slit extending in a direction perpendicular to a movement direction of the substrate. The first holder and the second holder hold a first target and a second target, respectively, above the shielding member. The first target and the second target are arranged symmetrically with respect to a vertical plane including a linear path on which the center of the substrate is moved.

A sputtering apparatus including a chamber, a stage inside the chamber and configured to receive a substrate thereon, a first sputter gun configured to provide a sputtering source to an inside of the chamber, a first RF source configured to provide a first power having a first frequency to the first sputter gun, and a second RF source configured to provide a second power having a second frequency to the first sputter gun, the second frequency being lower than the first frequency may be provided.

A film forming apparatus includes a base material support mechanism configured to rotate a base material supported by the base material support mechanism about a first axis, and a first cathode portion on which a target in a cylindrical shape containing a film forming material is mounted and configured to rotate the target about a second axis, in a chamber. The second axis is disposed at a position skewed with respect to the first axis.

A method of forming a piezoelectric thin film can be provided by heating a substrate in a process chamber to a temperature between about 350 degrees Centigrade and about 850 degrees Centigrade to provide a sputtering temperature of the substrate and sputtering a Group III element from a target in the process chamber onto the substrate at the sputtering temperature to provide the piezoelectric thin film including a nitride of the Group III element on the substrate to have a crystallinity of less than about 1.0 degree at Full Width Half Maximum (FWHM) to about 10 arcseconds at FWHM measured using X-ray diffraction (XRD).