A an apparatus includes a processing chamber configured to house a workpiece, a target holder in the processing chamber, a first magnetic element positioned over a backside of the target holder, a first arm assembly connected to the first magnetic element, a rotational shaft, and a first hinge mechanism connecting the rotational shaft and the first arm assembly.

An apparatus has a cathode target with a cathode target outer perimeter. An inner magnet array with an inner magnet array inner perimeter is within the cathode target outer perimeter. The inner magnet array includes an inner magnet array base portion and an inner magnet array upper portion. A keeper plate assembly is connected to the inner magnet array upper portion and isolates the inner magnet array upper portion from the inner magnet array base portion. An outer magnet array is connected to a bottom surface of the keeper plate. The outer magnet array has an outer magnet array outer perimeter larger than the inner magnet array inner perimeter. The inner magnet array upper portion has a first magnetic orientation and the outer magnet array and the inner magnet array base portion have a second magnetic orientation opposite the first magnetic orientation.

A magnetron sputtering electrode for use in a rotatable cylindrical magnetron sputtering device, the electrode including a cathode body defining a magnet receiving chamber and a cylindrical target surrounding the cathode body. The target is rotatable about the cathode body. A magnet arrangement is received within the magnet receiving chamber, the magnet arrangement including a plurality of magnets. A shunt is secured to the cathode body and proximate to a side of the magnet arrangement, the shunt extending in a plane substantially parallel to the side of the magnet arrangement. A method of fine-tuning a magnetron sputtering electrode in a rotatable cylindrical magnetron sputtering device is also disclosed.

Methods and apparatus for a magnetron assembly are provided herein. In some embodiments, a magnetron assembly includes a first base plate; a second base plate movable with respect to the first base plate between a first position and a second position; an outer magnetic pole in the shape of a loop and comprising an outer magnetic pole section coupled to the first base plate and an outer magnetic pole section coupled to the second base plate; and an inner magnetic pole disposed within the outer magnetic pole, wherein the outer and inner magnetic poles define a closed loop magnetic field, and wherein the closed loop magnetic field is maintained when the second base plate is disposed in both the first position and a second position.

A sputtering apparatus comprises: a target holder; and a magnet unit of a rectangular shape having long and short sides. The magnet unit includes: a first magnet; a second magnet disposed surrounding the first magnet and magnetized in a different and opposite direction from a direction of magnetization of the first magnet, and a third magnet located at part between the first magnet and the second magnet in the short-side direction and at least at a center position between the first magnet and the second magnet, the third magnet being magnetized in the short-side direction. In the third magnet, a surface facing the second magnet has the same polarity as that of a surface of the second magnet on the target holder side, and a surface facing the first magnet has the same polarity as that of a surface of the first magnet on the target holder side.

A film forming apparatus for forming a film on a substrate by using a magnetron sputtering method. The film forming apparatus includes: a substrate holder configured to hold a substrate; a target holder configured to hold a target made of a ferromagnetic material to face the substrate holder; a magnet provided on a surface of the target holder opposite to the substrate holder, and configured to leak a magnetic field to a front surface of the target held by the target holder that is a surface close to the substrate holder; and a magnetic field strength measurement device configured to measure a strength of the magnetic field.

A method includes loading a wafer into a sputtering chamber, followed by depositing a film over the wafer by performing a sputtering process in the sputtering chamber. In the sputtering process, a target is bombarded by ions that are applied with a magnetic field using a magnetron. The magnetron includes a magnetic element over the target, an arm assembly connected to the magnetic element, a hinge mechanism connecting the arm assembly and a rotational shaft. The arm assembly includes a first prong and a second prong at opposite sides of the hinge mechanism. The magnetron further includes a controller that controls motion of the first arm assembly, enabling the first prong to revolve in an orbital motion path about the first hinge mechanism while the second prong remains stationary.

A sputtering magnetron apparatus is provided. Another aspect employs a set of magnet assembly that forms a magnetic field over the target surface to confine electrons. A further aspect of a sputtering magnetron includes a side dark space shield that is made of magnetic metal which shunts the magnetic flux leaking from the side to prevent the formation of a secondary plasma around the dark space shield when it operates simultaneously with another plasma source.

An apparatus has a keeper plate with a keeper plate outer perimeter. An annular magnet array with an annular magnet array outer perimeter is coincident with the keeper plater outer perimeter. An inner top magnet is positioned on a centerline of a first side of the keeper plate and an inner bottom magnet is positioned on the centerline of a second side of the keeper plate. The inner top magnet is of a first magnetic orientation and the annular magnet array and the inner bottom magnet have a second magnetic orientation opposite the first magnetic orientation to form a magnetic field environment that provides plasma confinement of ionizing electrons which causes a gas operative as a reactive gas and sputter gas to become ionized and subsequently be directed to a target cathode while simultaneously causing the ionization of sputtered species which are dispersed across a substrate.

Apparatus for sputter deposition of target material to a substrate is disclosed. In one form, the apparatus includes a substrate guide arranged to guide a substrate along a curved path and a target portion spaced from the substrate guide and arranged to support target material. The target portion and the substrate guide define between them a deposition zone. The apparatus includes biasing element for applying electrical bias to the target material. The apparatus also includes a confining arrangement including one or more magnetic elements arranged to provide a confining magnetic field to confine plasma in the deposition zone thereby to provide for sputter deposition of target material to the web of substrate in use. The confining magnetic field having magnetic field lines arranged to, at least in the deposition zone, substantially follow a curve of the curved path so as to confine said plasma around said curve of the curved path.