The invention relates to a holding system (1) for holding substrates (12) for use in a surface processing system having a covering area (20), comprising a plurality of fixing elements (2), a body (24) arranged within the covering area (20) for receiving the fixing elements (2), and a positioning element (26) for adjusting the covering and a machining area (20, 22), wherein a plurality of substrates (12) can be fixed by the fixing elements (2) and processed within the machining area (22).

A deposition system is provided capable of cleaning itself by removing a target material deposited on a surface of a collimator. The deposition system in accordance with the present disclosure includes a substrate process chamber. The deposition includes a substrate pedestal in the substrate process chamber, the substrate pedestal configured to support a substrate, a target enclosing the substrate process chamber, and a collimator having a plurality of hollow structures disposed between the target and the substrate, a vibration generating unit, and cleaning gas outlet.

Exemplary semiconductor processing systems may include a remote plasma source. The remote plasma source may include a first plasma block segment defining an inlet to an internal channel of the first plasma block segment. The first plasma block segment may also define a cooling channel between the internal channel of the first plasma block segment and a first exterior surface of the first plasma block segment. The remote plasma source may include a second plasma block segment defining an outlet from an internal channel of the second plasma block segment. The second plasma block segment may also define a cooling channel between the internal channel of the second plasma block segment and a first exterior surface of the second plasma block segment. The systems may include a semiconductor processing chamber defining an inlet fluidly coupled with the outlet from the remote plasma source.

Exemplary semiconductor processing systems may include a remote plasma source. The remote plasma source may include a first plasma block segment defining an inlet to an internal channel of the first plasma block segment. The first plasma block segment may also define a cooling channel between the internal channel of the first plasma block segment and a first exterior surface of the first plasma block segment. The remote plasma source may include a second plasma block segment defining an outlet from an internal channel of the second plasma block segment. The second plasma block segment may also define a cooling channel between the internal channel of the second plasma block segment and a first exterior surface of the second plasma block segment. The systems may include a semiconductor processing chamber defining an inlet fluidly coupled with the outlet from the remote plasma source.

An embodiment of a line-of-sight coating fixture includes a support structure, a spindle, and a shadow structure. The support structure includes a plurality of compartments disposed below a platter, each compartment having an opening on a periphery of the support structure. Each compartment is adapted to receive and secure a base of a workpiece such that a body of each workpiece to be coated is disposed about a periphery of the support structure and extends above the platter. The spindle is disposed through a center of the platter or support structure for rotating the workpieces thereabout. The shadow structure is disposed about the spindle, inside of the periphery, the shadow structure sized and adapted to shield a portion of each workpiece from line-of-sight coating material.

An embodiment of a line-of-sight coating fixture includes a support structure, a spindle, and a shadow structure. The support structure includes a plurality of compartments disposed below a platter, each compartment having an opening on a periphery of the support structure. Each compartment is adapted to receive and secure a base of a workpiece such that a body of each workpiece to be coated is disposed about a periphery of the support structure and extends above the platter. The spindle is disposed through a center of the platter or support structure for rotating the workpieces thereabout. The shadow structure is disposed about the spindle, inside of the periphery, the shadow structure sized and adapted to shield a portion of each workpiece from line-of-sight coating material.

A method of manufacturing an electronic component including a substrate is provided. The method includes generating a plasma remote from a sputter target, generating sputtered material from the sputter target using the plasma, and depositing the sputtered material on a substrate as a crystalline layer.

One or more embodiments described herein generally relate to methods and systems for monitoring film thickness using a sensor assembly. In embodiments described herein, a process chamber having a chamber body, a substrate support disposed in the chamber body, a lid disposed over the chamber body, and a sensor assembly coupled to the chamber body at a lower portion of the sensor assembly. The sensor assembly is coupled to the lid at an upper portion of the sensor assembly. The sensor assembly includes one or more apertures disposed through one or more sides of the sensor assembly, and the one or more sensors are disposed in the sensor assembly through the one or more of the apertures.

Exemplary methods of treating a chamber may include delivering a cleaning precursor to a remote plasma unit. The methods may include forming a plasma of the cleaning precursor. The methods may include delivering plasma effluents of the cleaning precursor to a processing region of a semiconductor processing chamber. The processing region may be defined by one or more chamber components. The one or more chamber components may include an oxide coating. The methods may include halting delivery of the plasma effluents. The methods may include treating the oxide coating with a hydrogen-containing material delivered to the processing region subsequent halting delivery of the plasma effluents.

Embodiments disclosed herein generally relate to a system and, more specifically, a substrate processing system. The substrate processing system includes one or more cooling systems. The cooling systems are configured to lower and/or control the temperature of a body of the substrate processing system. The cooling systems include features to cool the body disposed in the substrate processing system using gas and/or liquid cooling systems. The cooling systems disclosed herein can be used when the body is disposed at any height.