A multiple tool for a punching device, in particular for a turret punch press has a housing and a tool head interacting with the punching device. A thread cutter magazine including a plurality of thread cutters is connected to the tool head. A selection device is provided to select an active thread cutter which interacts with a workpiece for thread cutting. A thread cutter drive device is provided to drive the active thread cutter. As a result, a multiple tool is obtained which expands the range of applications of a punching device.

A plasma processing apparatus of processing a processing target object within a depressurized space is provided. The plasma processing apparatus includes a processing vessel that partitions a depressurizable space; a mounting table, provided within the processing vessel, having an electrostatic chuck which is for a focus ring and has three electrodes; a power supply configured to apply three AC voltages having different phases to the three electrodes, respectively, to adsorb a target object on the electrostatic chuck.

A plasma processing apparatus includes an electrostatic chuck and a lifter pin. The electrostatic chuck has a mounting surface on which a target object is mounted and a back surface opposite to the mounting surface, and a through hole formed through the mounting surface and the back surface. The lifter pin is at least partially formed of an insulating member and has a leading end accommodated in the through hole. The lifter pin vertically moves with respect to the mounting surface to vertically transfer the target object. A conductive material is provided at at least one of a leading end portion of the lifter pin which corresponds to the through hole and a wall surface of the through hole which faces the lifter pin.

An electrostatic chuck assembly with improved thermal uniformity and stability is disclosed herein. The electrostatic chuck assembly includes a puck having a chucking electrode disposed therein and a cooling base connected to the puck. The cooling base is formed a first material and includes a top surface, a first cooling channel, a second cooling channel configured to flow coolant therethrough independent of flow through the first cooling channel, and a first thermal spreading element aligned with the first cooling channel and disposed between the first cooling channel and the puck. The first thermal spreading element is formed from a second material that has a thermal conductivity higher than a thermal conductivity of the first material.

An electrostatic chuck includes a ceramic dielectric substrate having a first major surface on which an object to be processed is mounted, and a second major surface, the ceramic dielectric substrate being a polycrystalline ceramic sintered body, an electrode layer provided on the ceramic dielectric substrate, a base plate provided on a side of the second major surface and supporting the ceramic dielectric substrate, and a heater provided between the electrode layer and the base plate. The base plate includes a through hole piercing the base plate and a communication path passing a medium adjusting a temperature of the object to be processed, and when viewed in a direction perpendicular to the first major surface, at least a part of the heater exists on a side of the through hole as viewed from a first portion of the communication path which is closest to the through hole.

Process kit components for use with a substrate support of a process chamber are provided herein. In some embodiments, a process kit ring may include a ring shaped body having an outer edge, an inner edge, a top surface and a bottom, wherein the outer edge has a diameter of about 12.473 inches to about 12.479 inches and the inner edge has a diameter of about 11.726 inches to about 11.728 inches, and wherein the ring shaped body has a height of about 0.116 to about 0.118 inches; and a plurality of protrusions disposed on the top surface of the ring shaped body, each of the plurality of protrusions disposed symmetrically about the ring shaped body.

A mounting table includes an electrostatic chuck having a mounting surface and a backside opposite to the mounting surface, a first through hole being formed in the mounting table; a base joined to the backside of the electrostatic chuck and having a second through hole in communication with the first through hole; a lifter pin which is received in a pin hole formed by the first through hole and the second through hole, the lifter pin being movable up and down to protrude beyond and retract below the mounting surface. An upper end portion of the lifter pin has a shape in which a diameter decreases toward a lower end of the lifter pin to correspond to a shape of the upper end portion of the pin hole. The upper end portion of the lifter pin is in surface contact with the upper end portion of the pin hole.

An electrostatic chuck (ESC) with a cooling base for plasma processing chambers, such as a plasma etch chamber. In embodiments, a plasma processing chuck includes a plurality of independent edge zones. In embodiments, the edge zones are segments spanning different azimuth angles of the chuck to permit independent edge temperature tuning, which may be used to compensate for other chamber related non-uniformities or incoming wafer non-uniformities. In embodiments, the chuck includes a center zone having a first heat transfer fluid supply and control loop, and a plurality of edge zones, together covering the remainder of the chuck area, and each having separate heat transfer fluid supply and control loops. In embodiments, the base includes a diffuser, which may have hundreds of small holes over the chuck area to provide a uniform distribution of heat transfer fluid.

A method and apparatus for de-chucking a workpiece is described that uses a swing voltage sequence. One example pertains to a method that includes applying a mechanical force from an electrostatic chuck against the back side of a workpiece that is electrostatically clamped to the chuck, applying a sequence of voltage pulses with a same polarity to the electrodes, each pulse of the sequence having a lower voltage than the preceding pulse, each pulse of the sequence having a lower voltage than the preceding pulse, and determining whether the workpiece is released from the chuck after the sequence of additional voltage pulses and if the workpiece is not released then repeating applying the sequence of voltage pulses.

The present disclosure relates to an electrostatic chuck, including: a base having a dielectric first surface to support a substrate thereon during processing; and an electrode disposed within the base proximate the dielectric first surface to facilitate electrostatically coupling the substrate to the dielectric first surface during use, wherein the dielectric first surface is sufficiently hydrophobic to electrostatically retain the substrate to the dielectric first surface when contacted with water. Methods of making and using the electrostatic chuck under wet conditions are also disclosed.