Exemplary semiconductor substrate supports may include a pedestal shaft. The semiconductor substrate supports may include a platen. The platen may define a fluid channel across a first surface of the platen. The semiconductor substrate supports may include a platen insulator positioned between the platen and the pedestal shaft. The semiconductor substrate supports may include a conductive puck coupled with the first surface of the platen and configured to contact a substrate supported on the semiconductor substrate support. The semiconductor substrate supports may include a conductive shield extending along a backside of the platen insulator and coupled between a portion of the platen insulator and the pedestal shaft.

A substrate fixing device includes: a base plate; and an electrostatic chuck that is fixed to the base plate to adsorb a substrate by electrostatic force. The electrostatic chuck includes: an adsorption layer that is formed of ceramic and that contacts the substrate to adsorb and hold the substrate; a first heating layer that is formed on the adsorption layer and that includes a first electrode; a second heating layer that is formed on the first heating layer and that includes a second electrode; and a via that is provided between the first electrode and the second electrode to electrically connect the first electrode and the second electrode to each other. The via includes a body portion, and an end portion that is connected to the body portion. A diameter of the end portion is larger than that of the body portion.

A wafer processing apparatus is configured to process a wafer by supplying mist to a surface of the wafer. The wafer processing apparatus includes a furnace in which the wafer is disposed, a gas supplying device configured to supply gas into the furnace, a mist supplying device configured to supply the mist into the furnace, and a controller. The controller is configured to execute a processing step by controlling the gas supplying device and the mist supplying device to supply the gas and the mist into the furnace, respectively. The controller is further configured to control the mist supplying device to stop supplying the mist into the furnace while controlling the gas supplying device to keep supplying the gas into the furnace when the processing step ends.

In one aspect, a highly scalable diffusion-couple apparatus includes a transfer chamber configured to load a wafer into a process chamber. The process chamber is configured to receive the wafer substrate from the transfer chamber. The process chamber comprises a chamber for growth of a diffusion material on the wafer. A heatable bottom substrate disk includes a first heating mechanism. The heatable bottom substrate disk is fixed and heatable to a specified temperature. The wafer is placed on the heatable bottom substrate disk. A heatable top substrate disk comprising a second heating mechanism. The heatable top substrate disk is configured to move up and down along an x axis and an x prime axis to apply a mechanical pressure to the wafer on the heatable bottom substrate disk. While the heatable top substrate disk applies the mechanical pressure a chamber pressure is maintained at a specified low value. The first heating mechanism and the second heating mechanism can be independently tuned to any value in the working range.

A method of heat-treating a silicon wafer using a lateral heat treatment furnace that can improve the product yield by restricting reduction in the lifetime value of silicon wafers placed in the vicinity of dummy blocks placed to equalize the temperature of the region where the wafers are placed. In a method of heat-treating a silicon wafer using a lateral heat treatment furnace, a boat is placed in a hollow cylindrical furnace core tube, and on the boat, at least one of a first additional block between a first dummy block and a wafer group and a second additional block between a second dummy block and the wafer group is placed.

A substrate processing apparatus includes a base with a process-side surface and a substrate support arranged on the process-side surface and designed to carry a substrate at its periphery. The periphery, more specifically the plane defined by the periphery, is spaced apart from the process-side surface. The substrate processing apparatus also includes a radiation sensor adapted to measure electromagnetic radiation arranged on a side of a back-side surface of the base. A radiation channel is arranged between the radiation sensor and the periphery of the substrate support, more specifically between the radiation sensor and the plane defined by the periphery, wherein the radiation channel is at least partially permeable to electromagnetic radiation.

An apparatus may provide a component, such as a showerhead, a pipe, a valve manifold, or a vessel, having a printed heater affixed to an outer surface of the component. In addition, a printed temperature sensor may be affixed to the outer surface of the component. The apparatus may further provide a controller to control the power to the printed heater according to data output from the printed temperature sensor.

A substrate processing apparatus includes a rotation driving device configured to rotate a rotary table holding a substrate; a processing liquid nozzle configured to supply a processing liquid onto a top surface of the substrate; an electric heater provided at a top plate and configured to heat the substrate through the top plate; an electronic component configured to perform a power feed to the electric heater and transmission/reception of a control signal for the electric heater; and a periphery cover body connected to a peripheral portion of the top plate to be rotated along with the top plate. An accommodation space in which the electronic component is accommodated is formed under the top plate. The accommodation space is surrounded by a surrounding structure including the top plate and the periphery cover body. A gap between the peripheral portion of the top plate and the periphery cover body is sealed.

A substrate processing apparatus includes a nozzle unit including a nozzle tip discharging liquid to a substrate; and a liquid supply line supplying the liquid to the nozzle unit, wherein the liquid supply line includes a liquid supply pipe connected to the nozzle tip; a supply valve installed in the liquid supply pipe; and a heater disposed between the nozzle tip and the supply valve in the liquid supply pipe.

There are provided a substrate treating apparatus and a substrate treating method. The substrate treating apparatus includes: a stage on which a substrate is seated, in a chamber; and a treatment liquid supply apparatus supplying a treatment liquid containing a solvent and a solute onto the substrate, wherein the treatment liquid supply apparatus supplies the treatment liquid onto the substrate while moving from a center of the substrate to an outer peripheral surface of the substrate.