A chuck for a laser beam wafer dicing equipment includes a wafer support plate having an upper surface for holding a wafer disposed on a dicing tape. The upper surface includes a topographically structured surface region that partly or completely overlaps an edge of the wafer when the wafer disposed on the dicing tape is placed on the upper surface. The topographically structured surface region provides for a reduction in an area of contact between the upper surface and the dicing tape.

Provided is a filter device includes: a first coil group including a plurality of coils arranged along a central axis and spirally wound with a first inner diameter; and a second coil group including a plurality of coils arranged along the central axis and spirally wound with a second inner diameter larger than the first inner diameter. A pitch between respective turns of the plurality of coils of the second coil group is larger than a pitch between respective turns of the plurality of coils of the first coil group.

Aspects generally relate to substrate support apparatus and systems having elevated surfaces for heat transfer between the elevated surfaces and a substrate, and the methods of using the same. In one aspect, the elevated surfaces are disposed between a recessed surface and a plurality of support surfaces of a plurality of support protrusions that extend from the recessed surface. In one aspect, the elevated surfaces are disposed between a base surface and a plurality of support surfaces of a plurality of support protrusions that extend from the base surface. During a substrate processing operation, heat is transferred to the substrate through a plurality of cavities disposed between the elevated surfaces and a backside surface of the substrate.

There is a substrate support comprising: a base; an electrostatic chuck disposed on the base and having a substrate supporting surface to support the substrate; and an edge ring disposed to surround the substrate on the substrate supporting surface, wherein the electrostatic chuck has a ring supporting surface to support the edge ring, and an inner edge side of the ring supporting surface is lower than an outer edge side of the ring supporting surface.

A substrate processing apparatus includes a base plate, an upper plate on the base plate, a DC power supply configured to supply power to the upper plate, and a controller interconnecting the upper plate and the DC power supply. The upper plate includes a first electrode, and a second electrode spaced apart from the first electrode. The controller includes a first controller interconnecting the first electrode and the DC power supply, and a second controller interconnecting the second electrode and the DC power supply. The DC power supply is configured to apply a first voltage to the first electrode via the first controller, and configured to apply a second voltage to the second electrode via the second controller. The first voltage and the second voltage are different.

First and second chiplets are positioned along a surface to respectively cover first and second electrodes. The first electrode is activated to cause an attraction force between the first electrode and the first chiplet. The second electrode is deactivated allowing the second chiplet to rotate on the surface. While the first electrode is activated and the second electrode is deactivated, a rotation field is applied to cause the second chiplet to be oriented at a desired orientation angle, the first chiplet being prevented from rotating by the attraction force.

An apparatus and a method for non-destructive inspection of quality of an electrostatic chuck are disclosed. The apparatus includes a measurement unit for measuring a first capacitance of a dielectric layer of the electrostatic chuck and for measuring a second capacitance of an electrode installed in the dielectric layer; and a control unit configured to evaluate quality of the electrode, based on the first capacitance and the second capacitance.

Described are electrostatic chucks that are useful to support a workpiece during a step of processing the workpiece, the electrostatic chuck including embossments that are made of multiple deposited layers, the layers including diamond-like carbon layers and layers that contain silicon-based materials such as silicon carbide layers.

A deposition apparatus, includes a chamber having at least one first gas inlet therein. A fixed chuck is installed in the chamber and an electrostatic chuck is installed on the fixed chuck. An edge ring is disposed on an edge of the electrostatic chuck. A shower head is disposed above the edge ring. A baffle is disposed above the shower head and an upper electrode is disposed above the baffle. A gas guide member is disposed above the upper electrode so that a flow path provided in the upper electrode and the first gas inlet are connected. The gas guide member has a flow path hole penetrating in upward and downward directions, and a plurality of guide holes are provided on an inner surface of the gas guide member.

The inventive concept provides a support unit for supporting a substrate. The support unit includes a heating unit for heating the substrate, and wherein the heating unit includes: a plurality of heating members; and a plurality of first power lines and a plurality of second power lines providing a supply and return pathway for a power to and from the plurality of heating members, and wherein the plurality of second power lines are connected to each of the plurality of first power lines through the plurality of heating members, and at least two heating members are connected to each first power line and at least two heating members are connected to each second power line, and at least two heating members are connected in parallel between each first power line and each second power line.