A substrate support includes a heater body, a heater element, and a heater terminal. The heater body is formed from a ceramic material and has upper and lower surfaces separated by a thickness. The heater element is arranged between the upper and lower surfaces and is embedded within the ceramic material forming the heater body. The heater terminal is arranged between the upper and lower surfaces, is electrically connected to the heater element, and has an electrode surface and a rounded surface. The electrode surface opposes the lower surface to flow an electric current to the heater element. The rounded surface opposes the upper surface and is embedded within the ceramic material to limit stress within the ceramic material during heating of a substrate seated on the upper surface of the heater body. Semiconductor processing systems and methods of making substrate supports for semiconductor processing systems are also described.

Provided is a member for a plasma processing apparatus consisting of a tungsten carbide phase. The member includes at least one type of atom selected from the group consisting of a Fe atom, a Co atom, and a Ni atom, in which the total content of the atoms is in a range of 30 to 3300 atomic ppm.

A resin coating applying apparatus includes a housing, a lid, a lid actuator for actuating the lid openably and closably with respect to the housing, a resin supply for supplying a solid resin to a workpiece, a vacuum pump for evacuating a processing space hermetically sealed by the housing and the lid, and an atmospheric vent valve for introducing atmospheric air into the processing space to cool the resin applied to the workpiece. The housing includes a holding table and a holding table actuator for moving the holding table upwardly and downwardly. The lid includes an upper table disposed opposite the holding table and movable relatively closely to the holding table to spread the resin supplied to the workpiece and coat the workpiece with the resin. When the lid is closed, it covers the opening in the housing to create the hermetically sealed processing space.

An apparatus for forming a solder bump on a substrate including a supporter configured to support the substrate to be provided thereon, a housing surrounding the supporter, a cover defining a manufacturing space in combination with the housing and including an edge heating zone along a perimeter thereof, the manufacturing space surrounding the supporter, and an oxide remover supply nozzle configured to supply an oxide remover to the manufacturing space may be provided.

A substrate processing apparatus includes a bake chamber, a chamber door that opens and closes an opening of the bake chamber, a first support plate in the bake chamber, a first partition wall, which partitions a space provided on the first support plate into first heat treatment spaces spaced apart from each other in a first horizontal direction, and extends in a second horizontal direction and a vertical direction, first heat treatment modules arranged in the first heat treatment spaces, a first exhaust duct extending in the first horizontal direction across the first heat treatment spaces, a first sealing bracket coupled to the first exhaust duct, a first horizontal packing configured to seal a gap between the first sealing bracket and the chamber door, and a first vertical packing configured to seal a gap between the first partition wall and the chamber door.

Embodiments of substrate supports are provided herein. In some embodiments, a substrate support for use in a substrate processing chamber includes a ceramic plate having a first side configured to support a substrate and a second side opposite the first side, wherein the ceramic plate includes an electrode embedded in the ceramic plate; a ceramic ring disposed about the ceramic plate and having a first side and a second side opposite the first side, wherein the ceramic ring includes a chucking electrode and a heating element embedded in the ceramic ring; and a cooling plate coupled to the second side of the ceramic plate and the second side of the ceramic ring, wherein the cooling plate includes a radially inner portion, a radially outer portion, and a thermal break disposed therebetween.

A method for controlling a temperature of a substrate support assembly is provided. A first direct current (DC) power is supplied to a heating element embedded in a zone of the substrate support assembly included in a processing chamber. A voltage is measured across the heating element. Similarly, a current is measured through the heating element. A temperature of the zone of the substrate support assembly is determined based on the voltage across the heating element and the current through the heating element. A temperature difference between the determined temperature of the zone and a target temperature for the zone is determined. A second DC power to deliver to the heating element is determined to achieve the target temperature based at least in part on the temperature difference. The second DC power is supplied to the heating element to cause the temperature of the zone to be modified to the target temperature.

A stage according to an exemplary embodiment has an electrostatic chuck. The electrostatic chuck has a base and a chuck main body. The chuck main body is provided on the base and configured to hold a substrate with electrostatic attractive force. The chuck main body has a plurality of first heaters and a plurality of second heaters. The number of second heaters is larger than the number of first heaters. The first heater controller drives the plurality of first heaters by an alternating current output or a direct current output from a first power source. The second heater controller drives the plurality of second heaters by an alternating current output or a direct current output from a second power source which has electric power lower than electric power of the output from the first power source.

A film forming apparatus comprises: a processing chamber in which a substrate is accommodated; a gas supply configured to supply a gas containing a first monomer and a gas containing a second monomer into the processing chamber; a concentration distribution controller configured to control a gas flow within the processing chamber such that a concentration of a mixed gas including the gas containing the first monomer and the gas containing the second monomer on the substrate has a predetermined distribution; and a temperature distribution controller configured to control a temperature distribution of the substrate such that a temperature of a first region of the substrate is higher than a temperature of a second region of the substrate, the concentration of the mixed gas in a region corresponding to the first region being higher than the concentration of the mixed gas in a region corresponding to the second region.

Aspects generally relate to methods, systems, and apparatus for processing substrates using one or more amorphous carbon hardmask layers. In one aspect, film stress is altered while facilitating enhanced etch selectivity. In one implementation, a method of processing a substrate includes depositing one or more amorphous carbon hardmask layers onto the substrate, and conducting a rapid thermal anneal operation on the substrate after depositing the one or more amorphous carbon hardmask layers. The rapid thermal anneal operation lasts for an anneal time that is 60 seconds or less. The rapid thermal anneal operation includes heating the substrate to an anneal temperature that is within a range of 600 degrees Celsius to 1,000 degrees Celsius. The method includes etching the substrate after conducting the rapid thermal anneal operation.