Embodiments of process kits for use in plasma process chambers are provided herein. In some embodiments, a process kit for use in a process chamber includes an annular body having an upper portion and a lower portion extending downward and radially inward from the upper portion, wherein the annular body includes an inner surface having a first segment that extends downward, a second segment that extends radially outward from the first segment, a third segment that extends downward from the second segment, a fourth segment that extends radially outward from the third segment, a fifth segment that extends downward from the fourth segment, a sixth segment that extends radially inward from the fifth segment, a seventh segment that extends downward from the sixth segment, and an eighth segment that extends radially inward from the seventh segment.

An apparatus with a deposition source and a substrate holder having a source mounting portion, which is rotatable about a first axis, a shielding element, which is disposed between the deposition source and the substrate holder, and a drive arrangement. The deposition source has a material outlet opening from which material is emitted. A longitudinal axis of an elongate central region of the material outlet opening extends parallel and centrally between the edges of the material outlet opening. The deposition source is mounted to the source mounting portion such that the longitudinal axis of the central region is parallel to the first axis. The shielding element has an aperture. The drive arrangement controls rotation of the source mounting portion, adjustment of a width of the aperture, and relative movement between the substrate holder and both the source mounting portion and the shielding element.

A deposition apparatus includes a shield member having a lattice shape in a plan view, the lattice shape including short side edges extending along a first direction and long side edges extending along a second direction, the short side edges including first and second short side edges, a bracket member including a first bracket member coupled to the first short side edge, and a second bracket member coupled to the second short side edge, a plurality of anode bars extending along the second direction and stably placed on each of the first bracket member and the second bracket member, and a target member covering the plurality of anode bars. An anode bar of the plurality of anode bars protrudes outward beyond at least one of the first bracket member and the second bracket member, and the anode bar is physically separated from the shield member by the bracket member.

Embodiments of process shield for use in process chambers are provided herein. In some embodiments, a process shield for use in a process chamber includes: an annular body having an upper portion and a lower portion extending downward and radially inward from the upper portion, wherein the upper portion includes a plurality of annular trenches on an upper surface thereof and having a plurality of slots disposed therebetween to fluidly couple the plurality of annular trenches, wherein one or more inlets extend from an outer surface of the annular body to an outermost trench of the plurality of annular trenches.

A high throughput deposition apparatus includes a process chamber, a plurality of targets that form a first closed loop in the process chamber, wherein the first closed loop includes a long dimension defined by at least a first pair of targets and a short dimension defined by at least a second pair of targets, a first substrate carrier assembly that can hold one or more substrates and configured to receive a deposition material from the plurality of targets in the first closed loop, and a transport mechanism that can move the first substrate carrier assembly along an axial direction through the first closed loop in the first process chamber.

Embodiments of a process kits for use in a process chamber are provided herein. In some embodiments, a process kit for use in a multi-cathode processing chamber includes: a first rotatable shield coupled to a first shaft, wherein the first rotatable shield includes a base, a conical portion extending downward and radially outward from the base, and one or more holes formed through the conical portion, wherein no two holes of the one or more holes are diametrically opposed; and a second rotatable shield coupled to a second shaft concentric with the first shaft, wherein the second rotatable shield is disposed in the first rotatable shield, and wherein the first rotatable shield is configured to rotate independent of the first rotatable shield.

The present invention relates to a slit diaphragm, a slit diaphragm system comprising at least two slit diaphragms arranged adjacent to each other and to a coating module and coating facility comprising a slit diaphragm.

A sputtering apparatus includes a first target and a second target that emit sputter particles, a substrate support configured to support a substrate, and a slit plate disposed between the first and the second targets and the substrate and having a slit unit through which the sputter particles pass. The slit unit includes a first slit to the first and the second target side and a second slit to the substrate side. The second slit has a first protrusion and a second protrusion protruding toward the center of the second slit. When the slit unit is viewed from the first target, the first protrusion is hidden. When the slit unit is viewed from the second target, the second protrusion is hidden.

A system and a method for detecting abnormality of a thin-film deposition process are provided. In the method, a thin-film is deposited on a substrate in a thin-film deposition chamber by using a target, a dimension of a collimator mounted between the target and the substrate is scanned by using at least one sensor disposed in the thin-film deposition chamber to derive an erosion profile of the target, and abnormality of the thin-film deposition process is detected by analyzing the erosion profile with an analysis model trained with data of a plurality of erosion profiles derived under a plurality of deposition conditions.

A deposition system is disclosed that allows for growth of inclined c-axis piezoelectric material structures. The system integrates various sputtering modules to yield high quality films and is designed to optimize throughput lending it to a high-volume in manufacturing environment. The system includes two or more process modules including an off-axis module constructed to deposit material at an inclined c-axis and a longitudinal module constructed to deposit material at normal incidence; a central wafer transfer unit including a load lock, a vacuum chamber, and a robot disposed within the vacuum chamber and constructed to transfer a wafer substrate between the central wafer transfer unit and the two or more process modules; and a control unit operatively connected to the robot.