A semiconductor manufacturing apparatus according to an embodiment includes a reactor, a mover, and a controller. The reactor houses an outer edge portion of a semiconductor substrate in inside thereof through a gap portion and scrapes the outer edge portion. The mover moves at least either the semiconductor substrate or end faces of the gap portion in a thickness direction of the semiconductor substrate to change distances in the thickness direction between the semiconductor substrate and the end faces of the gap portion. The controller controls a movement amount in the thickness direction of at least either the semiconductor substrate or the end faces of the gap portion according to a warp amount of the outer edge portion in the thickness direction.

An ion generator includes an arc chamber defining a plasma generation space, and a cathode which emits thermoelectrons toward the plasma generation space. The arc chamber includes a box-shaped main body having an opening, and a slit member mounted to cover the opening and provided with a front slit. An inner surface of the main body is exposed to the plasma generation space made of a refractory metal material. The slit member includes an inner member made of graphite and an outer member made of another refractory metal material. The outer member includes an outer surface exposed to an outside of the arc chamber. The inner member includes an inner surface exposed to the plasma generation space, and an opening portion which forms the front slit extending from the inner surface of the inner member to the outer surface of the outer member.

A semiconductor manufacturing apparatus according to an embodiment includes a reactor, a mover, and a controller. The reactor houses an outer edge portion of a semiconductor substrate in inside thereof through a gap portion and scrapes the outer edge portion. The mover moves at least either the semiconductor substrate or end faces of the gap portion in a thickness direction of the semiconductor substrate to change distances in the thickness direction between the semiconductor substrate and the end faces of the gap portion. The controller controls a movement amount in the thickness direction of at least either the semiconductor substrate or the end faces of the gap portion according to a warp amount of the outer edge portion in the thickness direction.

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.

A plasma processing system having at least a plasma processing chamber for performing plasma processing of a substrate and utilizing at least a first processing state and a second processing state. Plasma is present above the center region of the substrate during the first processing stale to perform plasma processing of at least the center region during the first processing state. Plasma is absent above the center region of the substrate but present adjacent to the bevel edge region during the second processing state to at least perform plasma processing of the bevel edge region during the second processing state. During the second processing state, the upper electrode is in an RF floating state and the substrate is disposed on the lower electrode surface.

Systems and device for removing edge bead accumulated on an edge of a wafer includes a first electrode disposed in a center of a nozzle used within a process chamber and a second electrode embedded within a dielectric material that surrounds the first electrode. A first channel is defined between the first electrode and the dielectric material and is used to receive a first gas from a first gas source. A second channel is defined between the dielectric material and an outer wall of the nozzle and is used to receive a second gas. RF power source is coupled to the nozzle so as to provide RF power to the electrodes to generate plasma radicals of the first gas. An opening at a bottom of the nozzle is used to provide pressurized flow of plasma radicals toward an edge of the wafer positioned below the nozzle.

An ion generator includes an arc chamber defining a plasma generation space, and a cathode which emits thermoelectrons toward the plasma generation space. The arc chamber includes a box-shaped main body having an opening, and a slit member mounted to cover the opening and provided with a front slit. An inner surface of the main body is exposed to the plasma generation space made of a refractory metal material. The slit member includes an inner member made of graphite and an outer member made of another refractory metal material. The outer member includes an outer surface exposed to an outside of the arc chamber. The inner member includes an inner surface exposed to the plasma generation space, and an opening portion which forms the front slit extending from the inner surface of the inner member to the outer surface of the outer member.

The present invention provides a support unit included in an apparatus for treating a substrate by using plasma. The support unit may include: a chuck configured to support a lower surface of the substrate; a moving plate provided to surround the chuck when viewed from above; and a lifting member configured to change an exposed area of an edge region of the substrate supported by the chuck for the treating space by relatively moving the moving plate in an upper or lower direction with respect to the chuck.

To make an improvement in the shape accuracy of a wafer shaped in the grinding operation after pretreatment and make an improvement in the efficiency of grinding operation of a wafer. A grinding apparatus includes at least one plasma generator configured to irradiate, before an outer circumferential edge of a wafer is ground, at least part of the outer circumferential edge with plasma.

Embodiments described herein relate to a method of treatment for substrate edge profiles. The method including generating a plasma in a plasma processing region of a processing volume of a processing chamber where the processing volume includes a first volume disposed above a grid assembly to receive a plasma and a second volume containing a substrate support assembly disposed below the grid assembly for processing a substrate. The grid assembly includes one or more grid plates; each grid plate including a plurality of perforations of two or more perforations arranged along a circular path disposed over a peripheral region of a substrate support surface. The method includes exposing the peripheral region of the substrate support surface to a plasma species generated in the first volume by focusing the plasma species through the perforations onto the peripheral region of the substrate support surface in the second volume.