A reactor includes a plasma duct; a gas inlet, at a distal end of the plasma duct, for receiving a gas; a gas outlet at a proximal end of the plasma duct for removing a portion of the gas to generate a gas flow through the plasma duct; a separating baffle positioned between the plasma duct and the gas outlet for restricting gas flow to maintain high pressure in the plasma duct; a shielded cathodic arc source positioned in a cathode chamber at the proximal end; a remote anode, positioned in the plasma duct, for holding a substrate and cooperating with the cathodic arc source to generate an electron flow opposite the gas flow, to initiate a plasma discharge perpendicular to the remote anode at least in vicinity of the remote anode and deposit ions of the plasma discharge on the substrate to form a diamond coating.

Techniques that facilitate physical vapor deposition with a dual-shutter are provided. In one example, a system includes a target plate, a first shutter plate and a second shutter plate. The target plate is associated with a voltage for physical vapor deposition. The first shutter plate comprises a first set of openings. The second shutter plate comprises a second set of openings. The first shutter plate and the second shutter plate are located between the target plate and a substrate. Furthermore, the first shutter and the second shutter rotate.

A plasma deposition apparatus includes a first plasma source that can produce a plasma confined in a magnetic field. The first plasma source includes a closed-loop electrode defining a center region therein and a central axis through the central region, and one or more magnets that are outside an inner surface of the closed-loop electrode. The magnets can produce a magnetic field in the center region. The one or more magnets can be at least partially embedded in the closed-loop electrode. The closed-loop electrode and the magnets can produce a plasma of ions to sputter atoms off a sputtering target or a backing plate.

Methods for depositing a low resistivity nickel silicide layer used in forming an interconnect and electronic devices formed using the methods are described herein. In one embodiment, a method for depositing a layer includes positioning a substrate on a substrate support in a processing chamber, the processing chamber having a nickel target and a silicon target disposed therein, the substrate facing portions of the nickel target and the silicon target each having an angle of between about 10 degrees and about 50 degrees from the target facing surface of the substrate, flowing a gas into the processing chamber, applying an RF power to the nickel target and concurrently applying a DC power to the silicon target, concurrently sputtering silicon and nickel from the silicon and nickel targets, respectively, and depositing a Ni.sub.xSi.sub.1-x layer on the substrate, where x is between about 0.01 and about 0.99.

A magnetoresistance device has an MgO (magnesium oxide) layer provided between a first ferromagnetic layer and a second ferromagnetic layer. The device is manufactured by forming a film of the MgO layer in a film forming chamber. A substance whose getter effect with respect to an oxidizing gas is large is adhered to surfaces of components provided in the chamber for forming the MgO layer. The substance having a large getter effect is a substance whose value of oxygen gas adsorption energy is 145 kcal/mol or higher. Ta (tantalum), in particular, is preferable as a substance which constitutes the magnetoresistance device.

According to one embodiment, a film formation apparatus includes a chamber having an interior to be vacuumed, a carrying unit which is provided in the chamber, and which carries a workpiece that has a processing target surface in a solid shape along a circular carrying path, a film formation unit that causes a film formation material to be deposited by sputtering on the workpiece that is being carried by the carrying unit to form a film thereon, and a shielding member which has an opening located at a side where the workpiece passes through, and which forms a film formation chamber where the film formation by the film formation unit is performed. A compensation plate that protrudes in the film formation chamber is provided, and the compensation plate has a solid shape along a shape of the processing target surface of the workpiece, and is provided at a position facing the workpiece.

A sputtering apparatus includes a shutter unit, a plurality of target holders, and a substrate holder which can rotate about an axis perpendicular to a surface on which a substrate is held. The shutter unit includes a first shutter having first and second apertures and a second shutter having third and fourth apertures. The plurality of target holders are arranged on a first virtual circle centered on the axis, with the arrangement intervals between the plurality of target holders on the first virtual circle including at least two types of arrangement intervals.

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.

Systems and methods for growing hexagonal crystal structure piezoelectric material with a c-axis that is tilted (e.g., 25 to 50 degrees) relative to normal of a face of a substrate are provided. A deposition system includes a linear sputtering apparatus, a translatable multi-aperture collimator, and a translatable substrate table arranged to hold multiple substrates, with the substrate table and/or the collimator being electrically biased to a nonzero potential. An enclosure includes first and second deposition stations each including a linear sputtering apparatus, a collimator, and a deposition aperture.

A film-forming apparatus comprises: a processing chamber defining a processing space, a first sputter-particle emitter and a second sputter-particle emitter having targets, respectively, from which sputter-particles are emitted in different oblique directions in the processing space, a sputter-particle blocking plate having a passage hole through which the sputter particles emitted from the first sputter-particle emitter and the second sputter-particle emitter pass, a substrate support configured to support a substrate and provided at a side opposite the first sputter-particle emitter and the second sputter-particle emitter with respect to the sputter-particle blocking plate in the processing space, a substrate moving mechanism configured to linearly move the substrate supported on the substrate support, and a controller configured to control the emission of sputter-particles from the first sputter-particle emitter and the second sputter-particle emitter while controlling the substrate moving mechanism to move the substrate linearly.