The present disclosure provides an apparatus for treating a substrate. The apparatus includes a chuck supporting the substrate, a gas supply unit configured to supply a process gas to an edge region of the substrate, and an edge electrode provided to surround the substrate supported by the chuck when viewed from a top and configured to generate plasma from the gas, in which the edge electrode has a ring shape and a groove recessed from an inner circumference of the edge electrode to an outer circumference of the edge electrode when viewed from the top is formed in the edge electrode.

An apparatus for plasma processing includes a pedestal configured to support a substrate and a conductive structure disposed at the pedestal. The conductive structure is configured to generate a plasma localized at an edge region of the substrate. The conductive structure may be a resonant structure. The apparatus may include a focus ring that has an insulating material with an annular shape defining an interior opening. The conductive structure may be embedded within the insulating material and be configured to generate the plasma along the annular shape and surrounding the interior opening. Processing conditions at the edge region of the substrate may be controlled using the plasma localized at the edge region.

Methods and systems for processing a bevel edge of a wafer in a bevel plasma chamber. The method includes receiving a pulsed mode setting for a RF generator of the bevel plasma chamber. The method includes identifying a duty cycle for the pulsed mode, the duty cycle defining an ON time and an OFF time during each cycle of power delivered by the generator. The method includes calculating or accessing a compensation factor to an input RF power setting of the generator. The compensation factor is configured to add an incremental amount of power to the input power setting to account for a loss in power attributed to the duty cycle to be run in the pulsed mode. The method is configured to run the generator in the pulse mode with the duty cycle and the pulsing frequency. The generator is configured to generate the input power in pulsing mode that includes incremental amount of power to achieve an effective power in the bevel plasma chamber to achieve a target bevel processing throughput, while reducing charge build-up that causes arcing damage.

There is provided a focus ring that is capable of preventing deposits from adhering to a member having a lower temperature in a gap between two members having different temperatures. A focus ring 25 is disposed to surround a peripheral portion of a wafer W in a chamber 11 of a substrate processing apparatus 10. The focus ring 25 includes an inner focus ring 25a and an outer focus ring 25b. Here, the inner focus ring 25a is placed adjacent to the wafer W and configured to be cooled; and the outer focus ring 25b is placed so as to surround the inner focus ring 25a and configured not to be cooled. Further, a block member 25c is provided in a gap between the inner focus ring 25a and the outer focus ring 25b.

A focus ring includes an insulating material having an annular shape that defines an interior opening. The focus ring further includes a conductive structure embedded within the insulating material. The conductive structure is configured to generate a plasma localized along the annular shape and surrounding the interior opening. The conductive structure may be configured to generate the plasma using alternating current power indirectly coupled to the conductive structure through the insulating material. The conductive structure may include a capacitive structure and an inductive structure, which may both be fully encased in the insulating material. The capacitive structure and the inductive structure may together form a resonant inductor-capacitor circuit comprising a resonant frequency greater than 30 MHz.

An apparatus for treating a substrate includes a housing including an open top and a treatment space therein, a gas supply unit configured to supply gas to the treatment space, a support unit including a chuck configured to support the substrate in the treatment space and an upper electrode provided to surround the check when viewed from the top, a dielectric plate unit including a dielectric plate arranged to oppose the substrate supported by the support unit in the treatment space, an upper electrode unit coupled to the dielectric plate unit and including an upper electrode arranged to oppose the lower electrode, and an aligning unit configured to align a horizontal arrangement of the dielectric plate unit, in which a lid extending from the housing in the horizontal direction and coupled to the upper electrode unit is provided on the housing, and the aligning unit is coupled to the lid.