Process chamber, high voltage measurement systems and methods for monitoring the output of a high voltage power supply are described. The output of the high voltage power supply is converted using a transducer and measured with high accuracy. A high voltage measurement system compares the converted value with a threshold criterion and actuates an interlock if readings are outside the threshold.

Process chamber, high voltage measurement systems and methods for monitoring the output of a high voltage power supply are described. The output of the high voltage power supply is converted using a transducer and measured with high accuracy. A high voltage measurement system compares the converted value with a threshold criterion and actuates an interlock if readings are outside the threshold.

An electrostatic clutch is described comprising a plurality of micron-scale thickness electrodes, adjacent electrodes being separated by a thin film of dielectric material. A power source and controller apply a voltage across two electrodes, causing an electrostatic force to develop. When engaged, a force can be transferred through the clutch. A tensioning device maintains the alignment of the clutch when the electrodes are disengaged, but permits movement in at least one direction. In some embodiments, multiple clutches are connected to an output to provide variable force control and a broad range of torque input and output values. Moreover, the clutch can be used as an energy-recycling actuator that captures mechanical energy from negative work movements, and returns energy during positive work movements.

An electrostatic clutch is described comprising a plurality of micron-scale thickness electrodes, adjacent electrodes being separated by a thin film of dielectric material. A power source and controller apply a voltage across two electrodes, causing an electrostatic force to develop. When engaged, a force can be transferred through the clutch. A tensioning device maintains the alignment of the clutch when the electrodes are disengaged, but permits movement in at least one direction. In some embodiments, multiple clutches are connected to an output to provide variable force control and a broad range of torque input and output values. Moreover, the clutch can be used as an energy-recycling actuator that captures mechanical energy from negative work movements, and returns energy during positive work movements.

In accordance with an embodiment of the invention, there is provided a soft protrusion structure for an electrostatic chuck, which offers a non-abrasive contact surface for wafers, workpieces or other substrates, while also having improved manufacturability and compatibility with grounded surface platen designs. The soft protrusion structure comprises a photo-patternable polymer.

In accordance with an embodiment of the invention, there is provided a soft protrusion structure for an electrostatic chuck, which offers a non-abrasive contact surface for wafers, workpieces or other substrates, while also having improved manufacturability and compatibility with grounded surface platen designs. The soft protrusion structure comprises a photo-patternable polymer.

An electrostatic chuck device includes: an electrostatic chuck section having one principal surface serving as a placing surface on which a plate-shaped sample is placed, and having a built-in electrostatic attracting internal electrode; a heating member bonded to a surface on the side opposite to the placing surface of the electrostatic chuck section in a pattern having gaps; a sheet material; and a base section having a function of cooling the electrostatic chuck section, in this order, in which each of the gaps of the pattern is filled with an inorganic filler composition which includes an inorganic filler and an adhesive.

An electrostatic chuck device includes: an electrostatic chuck section having one principal surface serving as a placing surface on which a plate-shaped sample is placed, and having a built-in electrostatic attracting internal electrode; a heating member bonded to a surface on the side opposite to the placing surface of the electrostatic chuck section in a pattern having gaps; a sheet material; and a base section having a function of cooling the electrostatic chuck section, in this order, in which each of the gaps of the pattern is filled with an inorganic filler composition which includes an inorganic filler and an adhesive.

A deposition apparatus is disclosed. In one aspect, the apparatus includes a metal sheet of which an edge portion is integrally combined with a sheet frame and an electrostatic chuck attached to a bottom surface of the metal sheet and configured to pull a substrate based on a static electricity force. The apparatus also includes a metal mask placed below the electrostatic chuck, wherein an edge portion of the metal mask is combined with a mask frame, and wherein the metal mask has a predetermined patterned opening where the substrate is mounted to the upper surface thereof. The apparatus further includes a magnet plate placed above the metal sheet, and configured to pull the metal mask based on a magnetic force so as to attach the substrate to the electrostatic chuck.

There are provided a method for obtaining a distance between a base portion of an electrostatic chuck and a back surface of a target object and a method for neutralizing the electrostatic chuck based on the obtained distance. The electrostatic chuck has an upper surface including the base portion and a plurality of convex portions projecting from the base portion. The target object is mounted on apexes of the convex portions of the electrostatic chuck such that the back surface is in contact with the apexes. By processing a first wavelength spectrum output from a spectroscope based on reflected light of light emitted from a light source, a distance between the back surface of the target object and the base portion of the electrostatic chuck is calculated. Based on the calculated distance, a voltage is applied to the electrostatic chuck to neutralize the electrostatic chuck.