A mounting table is provided. The mounting table includes an electrostatic chuck configured to mount thereon a target object and attract and hold the target object using an electrostatic force, and a gas supply line configured to supply a gas to a gap between the target object mounted on the electrostatic chuck and the electrostatic chuck via the electrostatic chuck. The mounting table further includes at least one irradiation unit configured to irradiate light having a predetermined wavelength to the gas flowing through the gas supply line or to the gas supplied to the gap between the target object and the electrostatic chuck to ionize the gas.

A film formation method includes (A) to (C) below. (A) Providing a substrate including, on a surface of the substrate, a first region in which a first material is exposed and a second region in which a second material different from the first material is exposed. (B) Supplying, to the surface of the substrate, vapor of a solution that contains a raw material of a self-assembled monolayer and a solvent by which the raw material is dissolved, and selectively forming a self-assembled monolayer in the first region. (C) Forming a desired target film in the second region by using the self-assembled monolayer formed in the first region.

A baseplate of a substrate support assembly for supporting a semiconductor substrate in a processing chamber comprises a first component made of a first material including a metal and a nonmetal. The first material has a first coefficient of thermal expansion. A layer coating the first component is made of a second material. The second material has a second coefficient of thermal expansion. The first and second coefficients of thermal expansion are different.

A film forming apparatus includes a film formation chamber capable of accommodating a substrate; a gas supplier including nozzles provided in an upper portion of the film formation chamber to supply a process gas onto a film formation face of the substrate, and a cooling part suppressing a temperature increase of the process gas; a heater heating the substrate to 1500° C. or higher; and a plate opposed to a bottom face of the gas supplier, where first opening parts of the nozzles are formed, in the film formation chamber, and arranged away from the bottom face, in which the plate includes a plurality of second opening parts having a smaller diameter than the first opening parts, and arranged substantially uniformly in a plane of the plate, and a partition protruded on an opposed face to the gas supplier and separating the plane of the plate into regions.

A substrate processing chamber includes a housing providing a process space; a spin apparatus provided in the housing; and a fluid spraying nozzle configured to spray fluid into the process space, wherein the spin apparatus includes: a spin chuck configured to support a substrate; a rotation driving part configured to rotate the spin chuck; and a weight sensor configured to measure a weight of the substrate supported on the spin chuck.

A heater controller controls power supplied to a heater capable of adjusting the temperature of a placement surface such that the heater reaches a set temperature. A temperature monitor measures the power supplied in the non-ignited state where the plasma is not ignited and in the transient state where the power supplied to the heater decreases after the plasma is ignited, while the power is controlled such that the temperature of the heater becomes constant. A parameter calculator calculates a heat input amount and the thermal resistance by using the power supplied in the non-ignited state and in the transient state to perform a fitting on a calculation model for calculating the power supplied in the transient state. A set temperature calculator calculates the set temperature of the heater at which the wafer reaches the target temperature, using the heat input amount and thermal resistance.

A film formation method includes: preparing a substrate including, on its surface, a first region in which a first material is exposed and a second region in which a second material different from the first material is exposed; selectively forming a self-assembled monolayer in the first region, among the first region and the second region; and forming a desired target film in the second region, among the first region and the second region, by using the self-assembled monolayer formed in the first region, wherein the selectively forming the self-assembled monolayer includes: selectively forming the self-assembled monolayer in the first region by using a first processing liquid including a first raw material of the self-assembled monolayer; and modifying the self-assembled monolayer, by using a second processing liquid including a second raw material of the self-assembled monolayer at a concentration different from a concentration of the first processing liquid.

Chucks for supporting semiconductor wafers during certain processing operations are disclosed. The chucks may include a recessed region near the outer perimeter of the wafer that has one or more surfaces that face towards the wafer but are recessed therefrom so as to not contact the wafer around the perimeter of the wafer. The use of such a recessed region prevents direct thermally conductive contact between the chuck and the wafer, thereby allowing the wafer to achieve a more uniform temperature distribution in certain process conditions. This has the further effect of causing certain processing operations to be more uniform with respect to edge-center deposition (or etch) layer thickness.

Provided is an apparatus for treating a substrate. The apparatus for treating a substrate may include: a liquid treating chamber configured to liquid-treat a substrate; and a controller configured to control the liquid treating chamber, and the liquid treating chamber may include a treating container having a treating space therein; a support unit configured to support and rotate the substrate in the treating space; a liquid supply unit configured to supply a liquid onto the substrate; and an elevation unit configured to adjust a relative height between the treating container and the support unit, and the controller may control the elevation unit so as to adjust the relative height between the treating container and the support unit according to a warpage state of the substrate supported on the support unit when conducting substrate treating by supplying the liquid onto the substrate while rotating the substrate.

Exemplary substrate support assemblies may include a chuck body defining a substrate support surface. The substrate support surface may define a plurality of protrusions that extend upward from the substrate support surface. The substrate support surface may define an annular groove and/or ridge. A subset of the plurality of protrusions may be disposed within the annular groove and/or ridge. The substrate support assemblies may include a support stem coupled with the chuck body.