Methods and apparatus for processing a substrate are provided herein. For example, a method includes supplying a first gas at a first flow rate to a substrate support disposed within an interior volume of a deposition chamber and at a second flow rate into the interior volume of the deposition chamber; decreasing the first flow rate of the first gas to a third flow rate; supplying DC power or DC power and an AC power for inducing an AC bias therebetween; supplying a second gas into the deposition chamber in a switching mode while supplying the first gas at the second flow rate and the third flow rate and increasing at least one of the DC power or AC power to increase the AC bias; and while supplying the second gas in the switching mode, depositing material from the target onto a substrate to form a barrier layer.

Systems and methods that enable printing of conformal materials and other waterproof coating materials at high resolution. An initial printing of a material on edges of a component is performed at high resolution in a first printing step, and a subsequent printing of the material on remaining surfaces of the component is applied in a second printing step, with or without curing of the material printed on the edges between the two printing steps. The printing of the material may be performed by a laser-assisted deposition or using another dispensing system to achieve a high resolution printing of the material and a high printing speed.

A physical vapor deposition (PVD) chamber and a method of operation thereof are disclosed. Chambers and methods are described that provide a chamber comprising an upper shield with two holes that are positioned to permit alternate sputtering from two targets.

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.

Methods and apparatus for method for filling a feature with copper. In some embodiments, the methods include: (a) depositing a first cobalt layer via a physical vapor deposition (PVD) process atop a substrate field and atop a sidewall and a bottom surface of a feature disposed in a substrate to form a first cobalt portion atop the substrate field and a second cobalt portion atop the sidewall; (b) depositing copper atop the first cobalt portion atop the substrate field; and (c) flowing the copper disposed atop the first cobalt portion atop the substrate field over the second cobalt portion and into the feature, wherein the first cobalt portion atop the substrate field reduces the mobility of copper compared to the mobility of copper over the second cobalt portion.

A plasma film forming apparatus 1 includes: a vacuum chamber 2 in which a film forming process is performed to a substrate 4; a substrate holder 3 provided so as to be rotatable along a film forming surface 4a of the substrate 4; a rotating shaft 5 connected to the substrate holder 3; and a plasma generation unit 10 configured to generate a plasma 6 and provided such that an irradiation angle of the plasma 6 with respect to the rotating shaft 5 forms an acute angle. The apparatus further includes: a first driving unit 7 configured to move the substrate holder 3 in a vertical direction 11 parallel to the rotating shaft 5; a second driving unit 8 configured to move the substrate holder 3 in a horizontal direction 12 orthogonal to the rotating shaft 5; and a third driving unit 9 configured to rotate the rotating shaft 5, and the substrate holder 3 is moved independently in the vertical direction 11 and the horizontal direction 12.

A photovoltaic cell device and a manufacturing method of a template thereof are provided. The manufacturing method of the template of the photovoltaic cell device includes the steps of providing a substrate and a target disposed opposite to each other in a chamber, applying an unbalanced magnetic field, and generating a plasma in the chamber to form a sputtered layer on the substrate. The plasma extends to an area proximate to the substrate due to the unbalanced magnetic field to assist the crystallization of the sputtered layer, so that the sputtered layer has a single crystalline or a single crystalline-like structure.

A deposition apparatus for coating a flexible substrate is described. The deposition apparatus comprises a first spool chamber housing a storage spool for providing the flexible substrate, a deposition chamber arranged downstream from the first spool chamber, and a second spool chamber arranged downstream from the deposition chamber and housing a wind-up spool for winding the flexible substrate thereon after deposition. The deposition chamber comprises a coating drum for guiding the flexible substrate past a plurality of deposition units including at least one deposition unit having a graphite target. The coating drum is connected to a device for applying an electrical potential to the coating drum.

The present invention provides a film formation method and a film formation apparatus which can fabricate an epitaxial film with +c polarity by a sputtering method. In one embodiment of the present invention, the film formation method of epitaxially growing a semiconductor thin film with a wurtzite structure by the sputtering method on an epitaxial growth substrate heated to a predetermined temperature by a heater includes the following steps. First, the substrate is disposed on a substrate holding portion including the heater to be located at a predetermined distance away from the heater. Then, the epitaxial film of the semiconductor film with the wurtzite structure is formed on the substrate with the impedance of the substrate holding portion being adjusted.

A method of applying a homogenous film coating to a constituent particle of component includes setting up a target element in a sputtering chamber. The method also includes arranging a receptacle in the sputtering chamber. The method additionally includes arranging the constituent particle on the receptacle. The method also includes bombarding the target element via energetic particles to eject material from the target element and deposit the material onto the constituent particle. The method further includes agitating the receptacle during the bombarding to apply the material to the constituent particle as the homogenous film coating. The method may be used to apply a homogenous thin film coating to a sulfur-infused constituent particle for a sulfur cathode in a lithium-sulfur battery.