A substrate support plate includes a base plate; at least one spacer arranged on the base plate such that the at least one spacer is restrained from moving relative to the base plate without resort to an adhesive; and a top plate having an upper surface capable of holding a substrate thereon, the top plate being fixed to the base plate with the at least one spacer therebetween.

A physical vapor deposition (PVD) chamber and a method of operation thereof are disclosed. Chambers and methods are described that provide a chamber comprising a deposition ring assembly comprising an inner and outer deposition ring which reduces particle defects.

A coating carrier assembly for supporting a to-be-plated component includes at least one supporting unit. Each of the at least one supporting unit includes a first supporting portion, a second supporting portion, and at least two ribbed plates. An annular groove is defined between the first supporting portion and the second supporting portion. The at least two ribbed plates are formed in the annular groove and connected to the first supporting portion and the second supporting portion. Each of the at least two ribbed plates comprises an overflow plating groove facing the to-be-plated component. The overflow plating groove is connected to the annular groove. The disclosure also relates to a coating device. The coating carrier assembly and the coating device can obtain a coating without shielding traces.

Support plates and support structures for thermal processing systems to heat workpieces are provided. In one example, a thermal processing apparatus is provided that includes a plurality of heat sources, a rotatable support plate, and a support structure having a flexibility in the radial direction of the rotatable support plate that is greater than a flexibility in the azimuthal direction of the rotatable support plate. Also provided are support plates for supporting a workpiece in a thermal processing apparatus. The support plate can include a base defining a radial direction and an azimuthal direction and at least one support structure extending from the base having a flexibility in the radial direction of the base that is greater than a flexibility in the azimuthal direction of the base.

Support plates and support structures for thermal processing systems to heat workpieces are provided. In one example, a thermal processing apparatus is provided that includes a plurality of heat sources, a rotatable support plate, and a support structure having a flexibility in the radial direction of the rotatable support plate that is greater than a flexibility in the azimuthal direction of the rotatable support plate. Also provided are support plates for supporting a workpiece in a thermal processing apparatus. The support plate can include a base defining a radial direction and an azimuthal direction and at least one support structure extending from the base having a flexibility in the radial direction of the base that is greater than a flexibility in the azimuthal direction of the base.

Methods to improve front-side process uniformity by back-side metallization are disclosed. In some implementations, a metal layer is deposited on the back-side of a wafer prior to performing a plasma-based process on the front side of the wafer. Presence of the back-side metal layer reduces variations in, for example, thickness of a deposited and/or etched layer resulting from the plasma-based process.

Methods to improve front-side process uniformity by back-side metallization are disclosed. In some implementations, a metal layer is deposited on the back-side of a wafer prior to performing a plasma-based process on the front side of the wafer. Presence of the back-side metal layer reduces variations in, for example, thickness of a deposited and/or etched layer resulting from the plasma-based process.

A plasma processing apparatus includes a chamber (20) and a target (25) above the chamber (20). The surface of the target (25) contacts the processing area of the chamber (20). The chamber (20) includes an insulating sub-chamber (21) and a first conductive sub-chamber (22), which are superposed. The first conductive sub-chamber (22) is provided under the insulating sub-chamber (21). The insulating sub-chamber (21) is made of insulating material, and the first conductive sub-chamber (22) is made of metal material. A Faraday shield component (10) which is made of metal material or insulating material electroplated with conductive coatings and includes at least one slit is provided in the insulating sub-chamber (21). An inductance coil (13) surrounds the exterior of the insulating sub-chamber (21). The problem about the wafer contamination due to particles formed on the surface of the coil during the sputtering process can be solved by using the plasma processing apparatus.

A plasma processing apparatus includes a chamber (20) and a target (25) above the chamber (20). The surface of the target (25) contacts the processing area of the chamber (20). The chamber (20) includes an insulating sub-chamber (21) and a first conductive sub-chamber (22), which are superposed. The first conductive sub-chamber (22) is provided under the insulating sub-chamber (21). The insulating sub-chamber (21) is made of insulating material, and the first conductive sub-chamber (22) is made of metal material. A Faraday shield component (10) which is made of metal material or insulating material electroplated with conductive coatings and includes at least one slit is provided in the insulating sub-chamber (21). An inductance coil (13) surrounds the exterior of the insulating sub-chamber (21). The problem about the wafer contamination due to particles formed on the surface of the coil during the sputtering process can be solved by using the plasma processing apparatus.

A deposition apparatus comprises: an infeed chamber; a preheat chamber; a deposition chamber; and optionally at least one of a cooldown chamber and an outlet chamber. At least a first of the preheat chamber and the cooldown chamber contains a buffer system for buffering workpieces respectively passing to or from the deposition chamber.