A method for etching features in a stack below a patterned mask in an etch chamber is provided. The stack is cooled with a coolant with a coolant temperature below −20° C. An etch gas is flowed into the etch chamber. A plasma is generated from the etch gas. Features are selectively etched into the stack with respect to the patterned mask.

A method for controlling a substrate temperature in a substrate processing system includes determining a temperature difference between the substrate temperature before the substrate is loaded onto a substrate support device and a desired temperature for the substrate support device and, during a first period, controlling a thermal control element to adjust the temperature of the substrate support device to a temperature value based on the temperature difference. The temperature value is not equal to the desired temperature for the substrate support device. The method further includes loading the substrate onto the substrate support device after the first period begins and before the temperature of the substrate support device returns to the desired temperature and, during a second period that follows the first period, controlling the temperature of the substrate support device to the desired temperature for the substrate support device.

A wafer-fixing tape, having: an temporary-adhesive layer provided on a substrate film, wherein the substrate film contains an ionomer resin comprising a terpolymer crosslinked by a metal ion, and wherein an arithmetic average roughness Ra of a surface of the substrate film opposite to the temporary-adhesive layer 5b is from 0.1 to 3.0 μm; a processing method of a semiconductor wafer; and a semiconductor chip.

Exemplary semiconductor processing methods may include flowing deposition gases that may include a nitrogen-containing precursor, a silicon-containing precursor, and a carrier gas, into a substrate processing region of a substrate processing chamber. The flow rate ratio of the nitrogen-containing precursor to the silicon-containing precursor may be greater than or about 1:1. The methods may further include generating a deposition plasma from the deposition gases to form a silicon-and-nitrogen containing layer on a substrate in the substrate processing chamber. The silicon-and-nitrogen-containing layer may be treated with a treatment plasma, where the treatment plasma is formed from the carrier gas without the silicon-containing precursor. The flow rate of the carrier gas in the treatment plasma may be greater than a flow rate of the carrier gas in the deposition plasma.

In some embodiments, a method for cleaning a processing chamber is provided. The method may be performed by introducing a processing gas into a processing chamber that has a by-product disposed along sidewalls of the processing chamber. A plasma is generated from the processing gas using a radio frequency signal. A lower electrode is connected to a first electric potential. Concurrently, a bias voltage having a second electric potential is applied to a sidewall electrode to induce ion bombardment of the by-product, in which the second electric potential has a larger magnitude than the first electric potential. The processing gas is evacuated from the processing chamber.

Exemplary lithography mask processing chambers may include a substrate support that includes a plurality of lift pins that are vertically translatable relative to a top surface of the substrate support. The lithography mask processing chambers may include a cover ring positioned atop the substrate support. The cover ring may define a rectilinear substrate seat. A top surface of the rectilinear substrate seat may be elevated above the top surface of the substrate support. An outer periphery of the rectilinear substrate seat may be positioned outward of the plurality of lift pins.

A semiconductor fabricating method for a film to be processed containing a transition metal on an upper surface of a semiconductor wafer placed in a processing chamber in a container being etched with a gas for complexing the transition metal supplied into the processing chamber, including a first step of adsorbing, to the film, the complexing gas, while supplying the complexing gas, then increasing a temperature of the wafer to form an organic metal complex on a surface of the film, and volatilizing and desorbing the organic metal complex, and a second step of adsorbing, to the surface of the film, the complexing gas at a low temperature, while supplying the complexing gas, then stopping the supply of the complexing gas, and stepwise increasing the temperature of the wafer to volatilize and desorb an organic metal complex formed on the surface of the film.

An assembly provided with a coolant flow channel includes a base in which the coolant flow channel is formed; and a protrusion component that is disposed in the coolant flow channel, wherein the protrusion component is liftable or rotatable.

Embodiments of the present disclosure generally relate to substrate supports for process chambers and RF grounding configurations for use therewith. Methods of grounding RF current are also described. A chamber body at least partially defines a process volume therein. A first electrode is disposed in the process volume. A pedestal is disposed opposite the first electrode. A second electrode is disposed in the pedestal. An RF filter is coupled to the second electrode through a conductive rod. The RF filter includes a first capacitor coupled to the conductive rod and to ground. The RF filter also includes a first inductor coupled to a feedthrough box. The feedthrough box includes a second capacitor and a second inductor coupled in series. A direct current (DC) power supply for the second electrode is coupled between the second capacitor and the second inductor.

A method for manufacturing an electrostatic chuck with multiple chucking electrodes made of ceramic pieces using metallic aluminum as the joining. The aluminum may be placed between two pieces and the assembly may be heated in the range of 770 C to 1200 C. The joining atmosphere may be non-oxygenated. After joining the exclusions in the electrode pattern may be machined by also machining through one of the plate layers. The machined exclusion slots may then be filled with epoxy or other material. An electrostatic chuck or other structure manufactured according to such methods.